Your search keyword '"bioenergy"' showing total 3,369 results

1. Carbon-efficient transportation via spatially explicit modelling of large-scale bioenergy with carbon capture and storage supply chains

Author

Freer, Muir, Gough, Clair, Welfle, Andrew, and Lea-Langton, Amanda

Subjects

Bioenergy, Transportation Modelling, Net-Zero, Bioenergy with Carbon Capture and Storage, Rail, Shipping, GIS, UK, Climate Change, HGV, Carbon-Efficient, Hydrogen, Infrastructure, BECCS, Digital Twin, Supply Chains, Spatially Explicit, Macro-Energy System Analysis, Power, Waste to Energy, Carbon Capture and Storage, High Spatial Resolution

Abstract

This research focuses on the impact of a series of scenarios on the carbon performances of large-scale agricultural residue and industrial waste derived Bioenergy with Carbon Capture and Storage supply chains (BECCS) transportation emissions at a high spatial resolution in the UK. This analysis combines three novel research disciplines, high spatial resolution biomass mapping, transportation digital twin modelling and macro-energy system analysis, to simulate the carbon-optimal transportation aspects of BECCS supply chains at high spatial resolution in the UK. The three supply chains modelled in the analysis are a Municipal-Solid-Waste (MSW) derived BECCS-waste-to-energy supply chain, a Wheat Straw derived BECCS-Power supply chain and a Sawmill Residue derived BECCS-Hydrogen supply chain. The three supply chains were applied through a novel digital twin model called the Carbon Navigation System (CNS) created during the PhD, which can simulate a BECCS supply chain anywhere in the UK to determine the optimal siting locations for the facilities. The model can also carbon-efficiently switch between HGVs, rail, shipping and pipeline transportation to minimise produced emissions. The routings calculated by the CNS model also provide improved ground-truthed transportation assumptions for BECCS Life Cycle Assessments (LCAs), as the current assumptions are drastically underestimating the emissions associated with BECCS resource transportation. The three BECCS supply chains were applied through a range of scenarios to determine the impact on the carbon performance of the supply chains by changing parameters within the CNS methodology. This analysis found that the optimal siting locations for the MSW and Sawmill Residue supply chains are in Connah's Quay, while the optimal siting location for the Wheat Straw supply chain is in Barrow-Upon-Humber when capturing 1 MtCO2/yr, although the optimal siting location does change depending on how much CO2 is captured. Shifting the siting location for the supply chains away from the optimal location will increase the supply chain transportation emissions between 8.9 to 12.6% per 10km, and the improper siting may dampen the carbon balance of the project as, in the worst-case scenario, the improper siting of a project may increase supply chain transportation emissions by 1327.0%. On average for the UK, the optimal facility scale for the MSW supply chain is 0.59 MtCO2/yr, 0.88 MtCO2/yr for the Wheat Straw supply chain and 0.46 MtCO2/yr for the Sawmill Residue supply chain. The carbon performances of the three supply chains are marginally impacted by increases in biomass yield and biomass availability, with a 3 to 5% decrease in supply chain transportation emissions when biomass yield is increased by 50%, and biomass availability is increased to 100%. The carbon performances of the supply chains were only impacted when biomass yields and availabilities were extremely low, with supply chain transportation emissions increasing by 5 to 10% for a 50% decrease in biomass yield and 8 to 23% when biomass availability is reduced to their knock-out values. The decarbonisation of HGVs was the most impactful on the carbon performances of the supply chains, with the transition to high degree decarbonised fuels resulting in a 73-74% decrease in supply chain transportation emissions. The analysis was designed to help decision-making for policy-makers and industry to aid the deployment of BECCS across the UK to meet Net-Zero, and this analysis offers heuristics to aid their deployment to ensure a sustainable deployment of the technology.

Published

2023

2. The sustainability of short rotation coppice willow as riparian buffer strips on Irish dairy farms

Author

Livingstone, David, Smyth, Beatrice, Foley, Aoife, Johnston, Christopher R., and Lyons, Gary

Subjects

Src willow, bioenergy, LCA, Agriculture, sustainability, climate change, economic evaluation

Abstract

The use of renewable energy crops, planted as riparian buffer strips, is seen as one method to help increase the sustainability of agriculture. This thesis focusses on the crop short rotation coppice willow, which is fast growing, has high nutrient retention rates, requires little maintenance and can be harvested regularly without the need to replant. The aims of the system are to reduce agricultural run-off, reduce the climate impact of agriculture and provide a source of renewable energy. In this thesis the impact of implementing short rotation coppice willow riparian buffer strips into intensive dairy farm settings on the island of Ireland was considered for the first time. This was to assess the impact it would have on the food-energy-water nexus using a novel framework, the climate impact of the farm and the economic impact. On a typical Irish dairy farm, the implementation of a short rotation coppice willow riparian buffer strip could reduce total nitrogen and phosphorus leachate by 14% and 9% respectively. Total CO2eq emissions could be reduced by 16.5% if energy from the willow displaces fossil fuels, while the impact on milk production is minimal, thus relieving strain on the entire food-energy-water nexus. By implementing the willow system, the time-dependent climate impact of an Irish dairy farm could also be reduced by 9.33% with only 3.68% of the land used for willow cultivation, over a 101-year study period. Furthermore, the system was found to have an average yearly net present value of £497 ha-1 of willow buffer. Assuming 5% land usage, a drop in value of £28 ha-1 yr-1 was found when implemented in an Irish dairy setting. However, on a per litre of milk basis a farm employing willow coppice riparian buffer strips outperformed a typical dairy farm both environmentally and economically. An established short rotation coppice willow riparian buffer strip was also considered for the first time, using life cycle assessment to determine the global warming potential, energy ratio, eutrophication potential and acidification potential of the system. Key results showed emissions of 4.66 kg CO2eq GJheatout-1 and 0.01 kg SO2eq GJheatout-1, both of which are significant reductions compared to an oil heating system (95% reductions for both impact categories). The system also resulted in permanent nutrient removal of 55.36 kg PO43-eq ha-1 yr-1 and had an energy ratio of 17.4, which could rise to 64 depending on the harvest method. Finally, the impact of a region-wide uptake for Northern Ireland was assessed. Key results showed that the widespread implementation of SRC willow riparian buffer strips in the region could result in a 2.75% reduction in total greenhouse gas emissions, 8% of the region's heat demand being met or 8.7% of the region's electricity demand, and 2,452 Mg N yr-1 and 416 Mg P yr-1 permanently prevented from polluting local water bodies.

Published

2022

3. Engineering microbes for consolidated bioprocessing : new approaches in the light of synthetic biology

Author

Valenzuela Ortega, Marcos, French, Chris, and Elfick, Alistair

Subjects

synthetic biology, DNA assembly, industrial biotechnology, bioenergy, biofuels

Abstract

Mitigating climate change calls for a reduction in emissions of greenhouse gases, mainly CO2. Twenty-seven per cent of all CO2 emissions come from sources hard to eliminate, including aviation, shipping, and long-distance land transportation. To scale-up production, a transition from first-generation biofuels (edible plant biomass feedstock) to second-generation biofuels (non-edible lignocellulosic plant biomass) is required. However, lignocellulosic bioprocesses struggle to reach economic viability due to the high cost of added enzymes required to digest cellulose. A microbe that was able to generate the cellulase to digest cellulose and able to generate desired products (in what is called a consolidated bioprocess) is not known to exist in nature. Decades of research in synthetic biology have not been successful in creating it due to multiple challenges, such as generating candidate microbial strains and testing them. In this work, novel methodological approaches were developed to overcome these challenges, thus increasing the likelihood of future research finding the ideal microbe. Firstly, the generation of candidate strains was improved by a re-design of the paradigm of modular cloning, based on a vector design called JUMP (Joint Universal Modular Plasmids). Complex multi-gene plasmids can be built from standard DNA parts in a reliable and automation-friendly way using modular cloning systems, based on Golden Gate cloning (which uses type IIS restriction enzymes). However, current standards lack the flexibility to change the microbial host and to perform assemblies to optimise genes of a group. JUMP vector backbones are based on the Standard European Vector Architecture (SEVA), and also have additional modular cloning sites to modify vectors for specific purposes. The experimental results presented here showed that these features allowed use of the vector system in different organisms and reduced the number of assemblies required to optimise and test multi-gene constructs. Secondly, among different explored approaches to test strains, using fluorescent growth reporters was found to have the properties required to screen strains in a faster and more relevant way. Cellulose is insoluble in water, and consequently, previous analytical methodologies to assess the cellulolytic capacity of microorganisms used soluble analogues of cellulase substrates or depended on separation steps which are difficult to do in a fast and high-throughput way. The data presented here showed that expression of fluorescence genes, providing a direct measure of growth, could be measured without separation of cellulose. An Escherichia coli strain expressing cellulases CenA and Chu2268, previously shown to bestow cellulolytic ability on E. coli, was confirmed to be able to grow using cellulose as sole carbon source, which demonstrated the use of fluorescent growth reporters to detect cellulolytic activity. Finally, a strain benchmark was built and characterised to allow screening of expression of cellulolytic genes. A collection of modular parts encoding cellulolytic proteins and secretion signal peptides was built to allow future screening, and the effect of genetic and environmental factors in the measurement of fluorescence as a reporter of growth was investigated. It was found that volumetric conditions and medium additives critically affected the capacity of E. coli to grow at the expense of cellulose. A methodology was developed to allow growth measurement in 96-well plates. In conclusion, this study lays the foundations to establish a faster research cycle to generate and screen microbes that can utilise cellulosic biomass to produce valuable bioproducts and biofuels.

Published

2021

4. Using agricultural residues to support sustainable development : a case study of coffee stems gasification to supply energy demands in rural areas of Colombia

Author

Garcia Freites, Samira, Welfle, Andrew, Lea-Langton, Amanda, and Gilbert, Paul

Subjects

662, Process modelling, Sustainable Development Goals, Lifecycle assessment, Agriculture, Techno-economic assessment, Coffee stems, Bioenergy, Gasification, Sustainable development, Agricultural residues

Abstract

The development of sustainable bioenergy plays an active role in the decarbonisation of the energy sector. Unlike other renewables, bioenergy has the potential to expand its applications beyond climate change mitigation by providing complementary environmental and socio-economic benefits that support the Sustainable Development Goals. The deployment of bioenergy could be particularly beneficial in the rural areas of many low and middle-income countries where traditional uses of biomass still prevail. Locally available biomass in rural areas, such as agricultural residues, could be harnessed in more efficient and sustainable manners, and this could be promoted with bioenergy development. The roll-out of these technologies also arises challenges across the environmental, economic and social dimensions, especially for emergent technologies. Tackling these challenges requires a wider understanding of bioenergy technologies' impacts across these dimensions, and this could be achieved through comprehensive and integrated assessments that investigate these dimensions. This research, therefore, seeks to gain further knowledge to unfold the following questions; how bioenergy technologies using agri-residues could be sustainably and feasibly deployed?, and what are the wider co-benefits, from a sustainable development perspective to rural communities and agro-industries?. This study aimed to evaluate the feasibility of small-scale gasification systems to generate power and heat, using indigenous agricultural residues, to meet the energy demand of rural areas. Considering also that bioenergy is set within local contexts, this research was framed in a case study on the coffee sector in Colombia, using coffee stems as feedstock. The methodology in this research consisted of a combination of multidisciplinary approaches, comprising process modelling for a technical assessment, lifecycle assessment (LCA) and techno-economic analysis. The results of the technical assessment indicate that the gasification of coffee stems could generate a fuel gas suitable for power generation in engines. In addition, the heat recovery and integration to supply the demand for coffee processing could enhance the conversion efficiency of the system. The LCA results show that deploying the coffee stems gasification-CHP system could impact positively on many environmental issues, including climate change, when traditional biomass uses and energy production using fossil fuels are replaced. However, trade-offs should be considered for certain scenarios, such as those replacing grid electricity with high-hydropower generation. The evaluation of the economic feasibility indicates that costs of power generation in the gasification systems could equalise the costs of Diesel-power generation when the system reaches high capacity factors. Matching the grid-electricity tariffs is more difficult to attain even at high capacity factors. The integration of the heat vector in the coffee processing chain contributes to fuel savings and could be translated into a heat credit that reduces the power generation costs. The key findings from this research were integrated under a multidimensional framework that prompted discussions on pivotal drivers, synergies and trade-offs of this bioenergy system. The synergies relate to the importance of balancing the biomass availability and the energy demand in context-specific agricultural sectors. It also emphasises the usefulness of harnessing the biomass conversion by implementing heat recovery pathways in the system, and of maximising the utilisation of the system (increasing the capacity factor) to enhance the systems feasibility. The framework also contributes to understanding how bioenergy from agricultural residues could contribute achieving the Sustainable Development Goals. The multidimensional framework highlights potential co-benefits to rural communities, in relation to improving energy access and health, promoting sustainable agriculture and economic growth, and reducing inequalities in rural areas. In conclusion, this research supports the overarching argument that bioenergy technologies have the potential to deliver energy demands in rural areas while tapping the potential of agricultural residues. Overcoming barriers to these systems deployment is still challenging. Yet, the synergies identified across all the dimensions could help to attain the system's feasibility and sustainability. Furthermore, wider societal co-benefits to rural communities could also be realised, as suggests the strong correlation between bioenergy and the Sustainable Development Goals.

Published

2020

5. Bioremediation of waste by the bacterium Rhodopseudomonas palustris

Author

Hervey, John Romaine Delmar and Howe, Christopher

Subjects

579.3, Bioremediation, photosynthesis, waste management, Rhodopseudomonas palustris, glycerol, cyanophycin, bacterial photosynthesis, biofuel, biohydrogen, bioenergy

Abstract

Rhodopseudomonas palustris is a photosynthetic bacterium capable of metabolising a broad range of substrates. It is a highly robust microorganism with a high tolerance for toxic conditions, making it an ideal candidate for the remediation of waste materials by metabolism. Our societies produce large amounts of waste materials, which require processing and safe disposal, but could instead be used as resources to produce fuel and energy or sustainably recycled into new materials. R. palustris can be used to process waste glycerol (a byproduct of biodiesel manufacture), and naturally produces hydrogen gas (a clean-burning fuel) as a byproduct of this process. R. palustris could potentially be used to bioremediate other waste materials and could be engineered to manufacture other useful products from this process. This thesis reports discoveries regarding the growth of R. palustris on previously untested substrates and the engineering of R. palustris to improve its utilisation of substrates and add additional metabolic pathways for the sustainable production of valuable compounds. Firstly, new substrates including urea are identified as supporting growth of R. palustris, suggesting that it could be used to process nitrogen-rich agricultural wastes. Nitrogen runoff and pollution pose a significant environmental problem, and safe disposal represents a significant cost to industry. Using R. palustris to bioremediate these wastes, converting them to more valuable materials, would help to offset the costs of waste disposal as well as providing a sustainable source of desirable compounds. Secondly, a genetic manipulation system developed to allow the expression of heterologous genes in R. palustris is presented, and newly engineered strains of R. palustris are characterised that are capable of producing the industrially significant compound cyanophycin when R. palustris is grown on glycerol and urea. Finally, strategies are presented for the future development of R. palustris as a bioremediation system and cell-factory for sustainable biotechnology.

Published

2020

6. How can we engage farmers in bioenergy development? : a social innovation approach to rice straw bioenergy in the Philippines and Vietnam

Author

Minas, Angela Mae, Mclachlan, Carly, and Mander, Sarah

Subjects

333.79, rural development, agriculture, farmers, rice straw, bioenergy, social innovation

Abstract

Rice straw is one of the largest agricultural by-products globally. However, only a small portion of this is utilised and majority continues to get burnt in open field, causing local pollution with negative impacts on the environment and farmers' health. Harnessing energy from straw could offer an alternative to open field burning while also addressing energy challenges of rural communities and potentially providing wider socio-economic benefits. To understand how this potential could be met, this study explored the case of selected rice farming communities in the Philippines and Vietnam -- two of the top rice producing countries in the world, where at least 80% of rice straw continues to be burnt every year. While most research on bioenergy focuses on technical aspects, this project offers a different perspective by focusing on the role of farmers and their communities, who, to date, remain marginalised in the bioenergy development process. Furthermore, with the increasing importance of social innovation in rural development, exploring the social aspects of bioenergy allowed for an understanding of how farmers could co-design solutions that meet their development needs. This research, therefore, answers a two-fold question: first, how can bioenergy offer an alternative to rice straw burning; second, how can farmers and their communities be engaged in this process? In doing so, this research proposes a social innovation pathway in order to engage critical actors in rice straw bioenergy development. Using a qualitative network approach in social network research, a mixed-method approach that combines participant observation and in-depth interviews with social network analysis, this study mapped how farmers make decisions during rice postproduction. This allowed the development of both an understanding of the needs, preferences, and motivations of farmers, and the identification of the relevant actors and resource movers within their communities. Thus, providing insight on how actors in farmers' networks can support a bioenergy social innovation and help deliver wider sustainable development benefits in rural communities. This research also explored the potential of rice straw as feedstock by comparing rice straw management practices, energy uses, and challenges in the Philippines and Vietnam. The results also show that despite differences in rice straw management in the Philippines and Vietnam, farmers' practices are mostly driven by social factors, especially since farmers greatly value relationships within the community. Together, these results suggest that: first, potential bioenergy solutions need to be integrated in current community activities; second, resource-sharing within communities could be further developed to support farmers in adopting alternatives to burning; and third, influential actors to farmers such as lenders, traders and cooperatives could be relevant in enabling a livelihood-based rice straw management activity around bioenergy. These consequently open opportunities for government and businesses to collaborate with farmers and build capacities to transform their current practices to provide income to the local community, in addition to addressing energy security. The research provides insights into how a prospective rice straw bioenergy system could be shaped -- one that is informed by current needs and considers the preferences and livelihood characteristics of rice farmers. Furthermore, findings of this study offer insights for policy and industry actors on what could be key to deploying rice straw bioenergy; where, ideally the main stakeholders -- farmers -- are not mere recipients of technology but active participants in the process.

Published

2019

7. Biosynthesis and function of glucuronic acid substitution patterns on softwood xylan

Author

Lyczakowski, Jan Jakub and Dupree, Paul

Subjects

662, Wood, Softwood, Conifers, Plant cell walls, Xylan, Cellulose, Biomass, Biofuels, Bioenergy, Plants

Abstract

Wood from coniferous trees is an important source of renewable biomass. It can contribute to provision of carbon neutral energy, biomaterials and housing for a growing population. Softwood is mainly composed of cellulose, galactoglucomannan, xylan and lignin. This thesis focuses on the biosynthesis and function of Glucuronic acid (GlcA) decorations on softwood xylan. Results demonstrate that this GUX (GlucUronic acid substitution of Xylan)-dependent xylan branching is critical for the maintenance of biomass recalcitrance in a model vascular plant Arabidopsis thaliana. Experiments employing in vitro and in planta activity assays show that conifer transcriptomes encode at least two distinct GUX enzymes which are active glucuronosyltransferases. Interestingly, these enzymes have different specific activities, with one adding evenly spaced GlcA branches and the other one being able to add consecutive decorations. It is possible that these different patterns of xylan branching may have an impact on ability of xylan to interact with cellulose fibrils. To investigate the role for xylan binding to cellulose, Arabidopsis mutant plants in which this interaction is lost were evaluated alongside transgenic mutant lines in which the interaction may be restored. Results of this analysis indicate that the presence of cellulose-bound xylan might have an influence on plant vasculature integrity and thus it may have an effect on plant growth and biomass properties. Moreover, further results indicate that some xylan cellulose interaction is likely to occur in cell wall macrofibrils which can be detected in softwood. Taken together, this thesis provides insights into the process of conifer xylan glucuronidation and the possible role these branches may be playing in the maintenance of softwood recalcitrance and mechanical properties. In addition to identifying potential mutagenesis targets for improving softwood processing, this work is a proof of concept for the use of GUX enzymes for in vivo and in vitro biosynthesis of novel xylan structures with potential industrial application.

Published

2019

8. Performance analysis of bioanode materials and the study of the metabolic activity of Rhodopseudomonas palustris in photo-bioelectrochemical systems

Author

Pankan, Aazraa Oumayyah and Fisher, Adrian C.

Subjects

660, Bioenergy, Photo-bioelectrochemical systems, Biophotovoltaic, Photosynthetic microbial fuel cell, Bioanode materials, Nanomaterials, Synechococcus elongatus, Rhodopseudomonas palustris, Biohydrogen, Bioelectricity

Abstract

A sustainable and low-cost system, namely a photo-bioelectrochemical system (photo-BES), based on the natural blueprint of photosynthetic microorganisms was studied. The aim of this research work is to improve the efficiency of electron transfer of the microorganisms for bioelectricity generation. The first strategy adopted was the evaluation of the exoelectrogenic activity of oxygenic photosynthetic cyanobaterium, Synechococcus elongatus PCC 7942, in biophotovoltaic (BPV) platforms through a comparative performance analysis of bioanode materials. The second approach involved improving the performance of anoxygenic photosynthetic bacterium, Rhodopseudomonas palustris ATCC® 17001™, by varying the ratio of nitrogen to carbon sources (N:C) to maximise both biohydrogen production and exoelectrogenesis for conversion into bioelectricity in photosynthetic microbial fuel cells (photoMFCs). A linear correlation was obtained between average surface roughness/surface area and maximum power density of ITO-coated and graphene/ITO-coated substrates. Graphene/ITO-coated PET bioanodes produced the highest maximum power output of 29±4 μW m-2 in a single chamber BPV device due to improved biofilm formation and improved electrochemical activity. XG Leaf®, also known as graphene paper, helped to bridge the shortcomings of carbon fibres in terms of wettability. The most hydrophilic, 240 μm thick graphene paper, produced the highest maximum power output of 393±20 μW m-2 in a membrane electrode assembly (MEA)-type BPV device, mainly due to reduced electrochemical polarisation. A proof of concept study compared the performance of screen-printed graphene onto a membrane separator against 3D-printed bioanodes coated with carbon nanotubes. One mm thick 3D-printed bioanode was better performing as its structures promoted a much denser biofilm with extensive fibrous extracellular matrix. Using a ratio of N:C=0.20 resulted in higher biohydrogen production and higher exoelectrogenic activity, generating a maximum power output of 361±157 mW m-2 and 2.39±0.13 mW m-2, respectively. This study provided additional insight in improving the electron transfer efficiency, which could be used to further optimise photo-BESs as part of future research and development for sustainable technologies.

Published

2019

9. Optimizing electrogenic activity from photosynthetic bacteria in bioelectrochemical systems

Author

Call, Toby Primo and Howe, Christopher

Subjects

572, Microbial fuel cell, biophotovoltaic, cyanobacteria, purple bacteria, bioenergy, electrogenic, pili, photosynthesis, bioelectrochemical, system, graphene, Synechocystis, Rhodospeudomonas palustris

Abstract

The aims of this project were to investigate a range of limitations affecting the electrical performance of bioelectrochemical systems (BES) and their use as analytical tools. The model cyanobacterium Synechocystis sp. PCC6803 was used to characterize light-driven BESs, or biophotovoltaic (BPV) devices. The phycobilisome (PBS) antenna size was altered to modify light absorption. At low to medium light intensities the optimum PBS antenna size was found to consist of one phycocyanin (PC) disc. Incorporating pulsed amplitude fluorescence (PAM) measurements into the BPV characterization allowed simultaneous comparison of photosynthetic efficiency to EET in Synechocystis. Non-photochemical quenching (NPQ) was investigated as a limiting factor in biophotovoltaic efficiency and was found to be reduced in the PBS antenna-truncated mutants. Fluorescence and electrochemical data were combined to develop a framework for quantifying the efficiency of light to bioelectricity conversion. This approach is a first step towards a more comprehensive and detailed set of analytical tools to monitor EET in direct relation to the underlying photosynthetic biology. A set of metabolic electron sinks were deleted to remove a selection of pathways that might compete with extracellular electron transfer (EET). The combined deletion of a bi-directional hydrogenase - HoxH, nitric oxide reductase - NorB, cytochrome-c oxidase - COX, bd-quinol oxidase - cyd, and the respiratory terminal oxidase - ARTO, roughly doubled light driven electron flux to EET. Deletion of nitrate reductase - NarB, and nitrite reductase - NirA, increased EET to a similar degree, but combination with the other knockouts compromised cell viability and did not increase output further. In addition to Synechocystis, the purple non-sulphur α-proteobacterium Rhodopseudomonas palustris CGA009 was used to test the effect of storage molecule synthesis knockout in a more industrially relevant organic carbon source driven BES, or microbial fuel cell (MFC). However, the removal of glycogen and poly-ß-hydroxybutyrate (PHB) did not have a significant effect on electrical output. Finally, the importance of electrode material and design for cell to anode connections in an MFC was investigated. EET from R. palustris was greatly enhanced using custom designed graphene and poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT:PSS) aerogels. Pristine graphene is also shown for the first time to be a viable, low cost alternative to platinum as a cathodic catalyst. Together, these results present a holistic view of major limitations on electrical output from BESs that may contribute to enhancing EET for power generation from MFCs in the long term, and optimization of BPV devices as reliable analytical tools in the short term.

Published

2018

10. Strategies to enhance extracellular electron transfer rates in wild-type cyanobacterium Synechococcus elongatus PCC7942 for photo-bioelectricity generation

Author

Gonzalez Aravena, Arely Carolina and Fisher, Adrian

Subjects

572, Photo-bioelectricity, Bioenergy, Bioelectrochemistry, Cyanobacteria, Exoelectrogenesis, Microbial electrochemical cell

Abstract

The aim of this thesis is to enhance the extracellular electron transfer rates (exoelectrogenesis) in cyanobacteria, to be utilised for photo-bioelectricity generation in biophotovoltaics (electrochemical cell). An initial cross comparison of the cyanobacterium Synechococcus elongatus PCC7942 against other exoelectrogenic cultures showed a hindered exoelectrogenic capacity. Nonetheless, in mediatorless biophotovoltaics, it outperformed the microalgae Chlorella vulgaris. Furthermore, the performance of S. elongatus PCC7942 was improved by constructing a more efficient design (lower internal resistance), which was fabricated with carbon fibres and nitrocellulose membrane, both inexpensive materials. To strategically obtain higher exoelectrogenic rates, S. elongatus PCC7942 was conditioned by iron limitation and CO2 enrichment. Both strategies are novel in improving cyanobacteria exoelectrogenesis. Iron limitation induced unprecedented rates of extracellular ferricyanide reduction (24-fold), with the reaction occurring favourably around neutral pH, different to the cultural alkaline pH. Iron limited cultures grown in 5% and 20% CO2 showed increased exoelectrogenic rates in an earlier stage of growth in comparison to air grown cultures. Conveniently, the cultural pH under enriched CO2 was around neutral pH. Enhanced photo-bioelectricity generation in ferricyanide mediated biophotovoltaics was demonstrated. Power generation was six times higher with iron limited cultures at neutral pH than with iron sufficient cultures at alkaline pH. The enhanced performance was also observed in mediatorless biophotovoltaics, especially in the dark phase. Exoelectrogenesis was mainly driven by photosynthetic activity. However, rates in the dark were also improved and in the long term it appeared that the exoelectrogenic activity under illumination tended to that seen in the dark. Proteins participating in iron uptake by an alleged reductive mechanism were overexpressed (2-fold). However, oxidoreductases in the outer membrane remain to be identified. Furthermore, electroactive regions in biofilms of S. elongatus PCC7942 were established using cyclic voltammetry. Double step potential chronoamperometry was also successfully tested in the biofilms. Thus, the electrochemical characterisation of S. elongatus PCC7942 was demonstrated, implying that the strategies presented in this thesis could be used to screen for cyanobacteria and/or electrode materials to further develop systems for photo-bioelectricity generation.

Published

2018

11. Patterns and process : biodiversity and ecosystem function response to changes in the arable landscape

Author

Berkley, Nicholas Alexander James

Subjects

333.73, Bioenergy, Agriculture, Biodiversity, Biofuel, Conservation, Miscanthus, Pollination, Willow Short-rotation Coppice, Bacteria, Soil, Soil Elements, Pollinator Network, Decomposition

Abstract

Land use change is a major driver of species loss worldwide, the extent and intensity of agricultural land use poses particular pressures for biodiversity and the ecosystem services it provides. In recent years, agroecosystems have seen the introduction of 2nd generation bioenergy crops in order to tackle anthropogenic climate change, providing a renewable alternative to fossil fuels. In this thesis I study the impact of cultivating two commercial perennial energy crops (PECs), Miscanthus x giganteus and willow short-rotation coppice, when compared to the cereal crops they replace. I investigate processes relevant to the provisioning of pollination and decomposition services and explore patterns of soil element bioaccessibility alongside analyses of the similarity and diversity of soil bacterial communities. When compared to cereals, I find a consistent increase in pollinator (hoverfly, bumblebee and butterfly/moth) wildflower visitation in the margins of willow but not Miscanthus. In Miscanthus, opposing trends arose for different pollinator taxa: butterflies/moths were more frequent flower visitors in Miscanthus margins than cereal margins, while hoverfly flower visits were most frequent in cereal margins. Furthermore, the availability of margin wildflowers was enhanced in willow but not Miscanthus and the seed set of margin phytometers was similar between Miscanthus and cereals. Cultivation of willow, in particular, may therefore yield local conservation benefits for both wildflowers and pollinators. However, there was no evidence for enhancement of pollinator activity in cereals adjacent to either PEC, indicating that the strategic cultivation of these crops is unlikely to enhance pollinator service provision in the wider agri-environment. For investigated soil elements, bioaccessibility in PECs did not differ significantly to cereal controls, and denaturing gradient gel electrophoresis (DGGE) revealed no difference in the diversity of bacterial communities. Similarly, DGGE fingerprint patterns did not indicate the development of crop specific assemblages, demonstrating that the mobility of soil elements and structure of bacterial communities were principally determined by factors other than the identity of the crop cultivated. Investigation of meso-microfaunal decomposition rates in Miscanthus using litter bags demonstrated an impact on decomposition processes, with a significant increase in winter decomposition rates in the PEC when compared to cereals.

Published

2018

12. Continuous biohydrogen and volatile fatty acids production from cheese whey in a tubular biofilm reactor: Substrate flow rate variations and microbial dynamics

Author

Sarkar, Omprakash, Rova, Ulrika, Christakopoulos, Paul, Matsakas, Leonidas, Sarkar, Omprakash, Rova, Ulrika, Christakopoulos, Paul, and Matsakas, Leonidas

Abstract

Three tubular bioreactors with a varied substrate flow rate of (2 mL/min, 5 mL/min, and 8 mL/min) were examined for 75 days. At 8 mL/min flow rate, the biohydrogen evolution was higher (3.88 mL H2/h), while its conversion efficiency was lower compared to 5 and 2 mL/min flow rate. The formation of volatile fatty acids and ammonium was also influenced by substrate flow rates. The volatile fatty acids production was slightly higher at 2 mL/min (12.74 ± 2.42 gCOD/L) and 5 mL/min (18.09 ± 2.01 gCOD/L) while, decreasing at 8 mL/min (11.85 ± 0.78 gCOD/L). Substrate flow rate significantly affected the pattern and composition of volatile fatty acids showing higher acetic acid, butyric and propionic acid production of 4.72 ± 1.46 gCOD/L (2 mL/min) 10.41 ± 0.91 gCOD/L (5 mL/min) and 1.78 ± 0.13 gCOD/L (5 mL/min). Continuous substrate input maintained the pH in the reactor due to replacement with fresh substrate, thereby controlling feedback inhibition and boosting metabolite production. Hydrogen-producing Firmicutes on the biofilm confirmed the pivotal role of the microbial community's significant contribution to converting waste to bioenergy. Overall, the present results support the use of a continuous operation mode for large-scale biohydrogen production. However, to ensure the efficacy of the system using waste or wastewater, low substrate flow rates are recommended., Validerad;2024;Nivå 2;2024-04-05 (marisr);Full text license: CC BY

Published

2024

13. Bed material performance of quartz, natural K-feldspar, and olivine in bubbling fluidized bed combustion of barley straw

Author

Bozaghian Bäckman, Marjan, Rebbling, Anders, Kuba, Matthias, Larsson, Sylvia H., Skoglund, Nils, Bozaghian Bäckman, Marjan, Rebbling, Anders, Kuba, Matthias, Larsson, Sylvia H., and Skoglund, Nils

Abstract

The present study investigates how three different silicate-based bed materials behave in bubbling fluidized bed combustion of a model agricultural residue with respect to ash composition, namely barley straw. Quartz, natural K-feldspar, and olivine were all used in combustion at 700 °C, and the resulting layer formation and bed agglomeration characteristics were determined. Based on this, a general reaction model for bed ash from agricultural residues was proposed, taking into account the reactivity of the different silicates investigated towards the main ash-forming elements K, Ca, and Si. The proposed reaction model links bed material interaction with K-rich bed ash to the degree of polymerization of the silicate bed material, where addition reactions occur in systems with high polymerization, predominately in quartz, and substitution reactions dominate for depolymerized silicates such as K-feldspar and olivine., Validerad;2024;Nivå 2;2024-03-11 (hanlid);Full text license: CC BY

Published

2024

14. A robust investment decision to deploy bioenergy carbon capture and storage : exploring the case of Stockholm Exergi

Author

Stenström, Oscar, Khatiwada, Dilip, Levihn, Fabian, Usher, William, Rydén, Magnus, Stenström, Oscar, Khatiwada, Dilip, Levihn, Fabian, Usher, William, and Rydén, Magnus

Abstract

The upscaling of novel carbon dioxide removal, such as bioenergy carbon capture and storage (BECCS), to gigatonne scales is an urgent priority if global warming is to be limited to well below 2 °C. But political, economic, social, technological, environmental and regulatory uncertainty permeates BECCS projects and deters investors. To address this, we explore options to improve the robustness of BECCS deployment strategies in the face of multi-dimensional uncertainties. We apply Dynamic Adaptive Planning (DAP) through expert interviews and Robust Decision Making (RDM) through exploratory modelling, two decision making under deep uncertainty methods, to the case of Stockholm Exergi, an early mover aiming to deploy BECCS at a combined heat and power plant in the capital of Sweden. The main contributions of the research are to 1) illustrate how a quantification of robustness against uncertainty can support an investment decision to deploy BECCS 2) comprehensively cover uncertain vulnerabilities and opportunities of deploying BECCS, and 3) identify critical scenarios and adaptations to manage these uncertainties. The main conclusions are: investing in BECCS is relatively robust if assessing performance across many scenarios and if comparing the worst-cases of either investing, or not doing so. Not investing could miss out on up to € 3.8 billion in terms of net present value. The critical uncertainties of BECCS can be managed by strengthening biomass sustainability strategies and by gaining support for negative emission trading regulation on carbon markets, e.g., voluntary or Paris Agreement Article 6. Even in vulnerable scenarios of average electricity prices above 82 €/MWh, if trading regulation is implemented before 2030 and if negative emission prices exceed 151 €/CO2, investing in BECCS performs better than not doing so in 96% of cases. We suggest that facility-level parameters and cost-reductions are of little importance for BECCS investments and upscaling. It is r, QC 20240125

Published

2024

15. Co-hydrothermal carbonization of polyvinyl chloride and pyrolysis carbon black for the preparation of clean solid fuels

Author

Wang, Guangwei, Li, Desheng, Yuan, Xiang, Li, Renguo, Dan, Jiayun, Wu, Junyi, Liu, Jiawen, Ning, Xiaojun, Wang, Chuan, Wang, Guangwei, Li, Desheng, Yuan, Xiang, Li, Renguo, Dan, Jiayun, Wu, Junyi, Liu, Jiawen, Ning, Xiaojun, and Wang, Chuan

Abstract

Large quantities of polyvinyl chloride (PVC) and waste tires generated daily have the disadvantage of high content of harmful elements. They cannot be directly applied to blast furnace ironmaking. In this study, Cl in PVC and Zn in pyrolysis products of waste tires (pyrolysis carbon black, CB) were effectively removed by co-hydrothermal carbonization (co-HTC). The results indicated the dechlorination and dezincification efficiencies of co-HTC were improved by 2.78 % and 64.69 %, respectively, compared to HTC. Compositional analysis shows that the ash content of co-HTC is reduced by at least 7.67 % compared to conventional HTC. The hydrochar produced by co-HTC has an higher heating value (HHV) ranging from 30.67 to 34.13 MJ/kg. Results of physical and chemical characteristics analysis showed increasing the proportion of CB can reduce the C–H and -CHCl- functional groups and improve the carbon orderliness of the hydrochar. Combustion characteristics and kinetic analyses show that the combustibility of hydrochar increases with an increase in the proportion of PVC added to the co-HTC. The thermal stability and activation energy of the hydrochar increase with the addition of CB. Overall, this study has removed major harmful elements from PVC and CB through co-HTC, converting both into high-quality solid fuels that can be utilised in blast furnace ironmaking., QC 20240108

Published

2024

16. Tar conversion and recombination in steam gasification of biogenic residues : the influence of a countercurrent flow column in pilot- and demonstration-scale

Author

Huber, Miriam, Benedikt, Florian, Karel, Thomas, Binder, Matthias, Hochstöger, Daniel, Egger, Anna, Fürsatz, Katharina, Kuba, Matthias, Huber, Miriam, Benedikt, Florian, Karel, Thomas, Binder, Matthias, Hochstöger, Daniel, Egger, Anna, Fürsatz, Katharina, and Kuba, Matthias

Abstract

First experiments with biogenic residues and a plastic-rich rejects and woody biomass blend were conducted in an advanced 1 MW dual fluidized bed steam gasification demonstration plant at the Syngas Platform Vienna. Wood chips, bark, forest residues, and the plastic-rich rejects and woody biomass blend were tested and the tar composition was analyzed upstream and downstream of the upper gasification reactor, which is designed as a high-temperature column with countercurrent flow of catalytic material. Each feedstock was gasified with olivine as bed material in demonstration scale and is compared to the gasification of softwood pellets with olivine and limestone in pilot scale. A reduction in tar content was observed after countercurrent column for all feedstocks. However, a shift in tar species occurred. While styrene, phenol, and 1H-indene were predominant upstream, naphthalene and polycyclic aromatic hydrocarbons (PAHs) were the prevailing tar species downstream the countercurrent column. Hence, an increase of i.e. anthracene, fluoranthene, and pyrene from the upstream concentration was observed. For pyrene, up to twice the initial concentration was measured. This recombination to PAHs was observed for all feedstocks in demonstration- and pilot-scale. The only exception occurred with limestone as bed material, characterized by a higher catalytic activity in comparison to the typically used olivine. In the perspective of the integrated product gas cleaning, tar with higher temperature of condensation are separated more efficiently in the installed scrubbing unit. Hence, the recombination facilitates an overall decline of tar content after the gas cleaning.

Published

2024

17. Characterization and antifungal properties against wood decaying fungi of hydrothermal liquefaction liquids from spent mushroom substrate and tomato residues

Author

Barbero-López, A., López-Gómez, Y. M., Carrasco, J., Jokinen, N., Lappalainen, R., Akkanen, J., Mola-Yudego, B., Haapala, Antti, Barbero-López, A., López-Gómez, Y. M., Carrasco, J., Jokinen, N., Lappalainen, R., Akkanen, J., Mola-Yudego, B., and Haapala, Antti

Abstract

This study aimed to investigate the potential of converting bio-based residues from industrial production of mushrooms and tomatoes into more valuable chemicals with antifungal properties using hydrothermal liquefaction (HTL). Liquid fractions were obtained from HTL of spent substrate of Agaricus bisporus (Lange) Imbach and Pleurotus ostreatus (jacq.) P. kumm., recomposted Agaricus bisporus spent substrate, and tomato residues. The quantitative 1H NMR spectroscopy analysis revealed that the HTL liquids of all residues contained antifungal constituents like phenols and organic acids. The HTL liquids at dilutions of 10 % were able to inhibit the fungi by over 80 %. Interestingly, the fungus P. ostreatus showed tolerance to these constituents as its growth was promoted at the lowest concentration of all the HTL liquids. The HTL liquids had lower ecotoxicity than the commercial wood preservative. These results suggest that the tested residues could be a promising source of preservative chemical constituents for the wood industry.

Published

2024

18. Lost in the scenarios of negative emissions : The role of bioenergy with carbon capture and storage (BECCS)

Author

Lefvert, Adrian, Grönkvist, Stefan, Lefvert, Adrian, and Grönkvist, Stefan

Abstract

Bioenergy with carbon capture and storage (BECCS) can be a useful and cost-effective climate change mitigation tool but it is reliant on economic incentives. With this policy perspective article we question the ongoing discussion about the use of biomass for BECCS with basis in three points: (1) under the enhanced transparency framework under the Paris agreement, all parties to the agreement will use the same guidelines to estimate emissions by sources and removals by sinks, in which the emissions and removals in connection to cultivation of biomass are accounted for in the land-use, land-use change and forestry (LULUCF) sector, (2) adding carbon capture to existing processes may lead to a shift in products from that process rather than an increase in biomass use, and (3) BECCS requires substantial financial incentives. With basis in these points, we argue that a certification framework for BECCS that contradicts the guidelines of the Intergovernmental Panel on Climate Change (IPCC) risks unnecessarily hindering deployment of a potentially cost-effective climate change mitigation tool., QC 20231215

Published

2024

19. Is tree planting an effective strategy for climate change mitigation?

Author

Kirschbaum, Miko U.F., Cowie, Annette L., Peñuelas, Josep, Smith, Pete, Conant, Richard T., Sage, Rowan F., Brandão, Miguel, Cotrufo, M. Francesca, Luo, Yiqi, Way, Danielle A., Robinson, Sharon A., Kirschbaum, Miko U.F., Cowie, Annette L., Peñuelas, Josep, Smith, Pete, Conant, Richard T., Sage, Rowan F., Brandão, Miguel, Cotrufo, M. Francesca, Luo, Yiqi, Way, Danielle A., and Robinson, Sharon A.

Abstract

The world's forests store large amounts of carbon (C), and growing forests can reduce atmospheric CO2 by storing C in their biomass. This has provided the impetus for world-wide tree planting initiatives to offset fossil-fuel emissions. However, forests interact with their environment in complex and multifaceted ways that must be considered for a balanced assessment of the value of planting trees. First, one needs to consider the potential reversibility of C sequestration in trees through either harvesting or tree death from natural factors. If carbon storage is only temporary, future temperatures will actually be higher than without tree plantings, but cumulative warming will be reduced, contributing both positively and negatively to future climate-change impacts. Alternatively, forests could be used for bioenergy or wood products to replace fossil-fuel use which would obviate the need to consider the possible reversibility of any benefits. Forests also affect the Earth's energy balance through either absorbing or reflecting incoming solar radiation. As forests generally absorb more incoming radiation than bare ground or grasslands, this constitutes an important warming effect that substantially reduces the benefit of C storage, especially in snow-covered regions. Forests also affect other local ecosystem services, such as conserving biodiversity, modifying water and nutrient cycles, and preventing erosion that could be either beneficial or harmful depending on specific circumstances. Considering all these factors, tree plantings may be beneficial or detrimental for mitigating climate-change impacts, but the range of possibilities makes generalisations difficult. Their net benefit depends on many factors that differ between specific circumstances. One can, therefore, neither uncritically endorse tree planting everywhere, nor condemn it as counter-productive. Our aim is to provide key information to enable appropriate assessments to be made under specific circumstan, QC 20231204

Published

2024

20. Climate change impacts of bioenergy technologies: A comparative consequential LCA of sustainable fuels production with CCUS

Author

Krogh, Andreas, Junginger, Martin, Shen, Li, Grue, Jeppe, Pedersen, Thomas H., Krogh, Andreas, Junginger, Martin, Shen, Li, Grue, Jeppe, and Pedersen, Thomas H.

Abstract

The use of sustainable biomass can be a cost-effective way of reducing the greenhouse gas emissions in the maritime and aviation sectors. Biomass, however, is a limited resource, and therefore, it is important to use the biomass where it creates the highest value, not only economically, but also in terms of GHG reductions. This study comprehensively evaluates the GHG reduction potential of utilising forestry residue in different bioenergy technologies using a consequential LCA approach. Unlike previous studies that assess GHG impacts per unit of fuel produced, this research takes a feedstock-centric approach which enables comparisons across systems that yield diverse products and by-products. Three technologies—combined heat and power plant with carbon capture, hydrothermal liquefaction, and gasification—are assessed, while considering both carbon capture and storage (CCS) or carbon capture and utilisation (CCU). Through scenario analysis, the study addresses uncertainty, and assumptions in the LCA modelling. It explores the impact of energy systems, fuel substitution efficiency, renewable energy expansion, and the up/down stream supply chain. All technology pathways showed a potential for net emissions savings when including avoided emissions from substitution of products, with results varying from −111 to −1742 kgCO2eq per tonne residue. When combining the bioenergy technologies with CCU the dependency on the energy system in which they are operated was a significantly higher compared to CCS. The breakpoint was found to be 44 kg CO2eq/kWh electricity meaning that the marginal electricity mix has to be below this point for CCU to obtain lower GHG emissions. Furthermore, it is evident that the environmental performance of CCU technologies is highly sensitive to how it will affect the ongoing expansion of renewable electricity capacity.

Published

2024

21. Defining bioenergy system services to accelerate the integration of bioenergy into a low-carbon economy

Author

Mäki, E., Hennig, C., Thrän, Daniela, Lange, N., Schildhauer, T., Schipfer, F., Mäki, E., Hennig, C., Thrän, Daniela, Lange, N., Schildhauer, T., and Schipfer, F.

Abstract

The global energy system is in transition. It is attempting to reach net-zero greenhouse gas emissions by 2050. The systemic changes mean that the role of bioenergy will change. The potential of bioenergy to make a flexible contribution to the energy system is key for the achievement of global emission reduction ambitions and the functioning of the low-carbon energy system and economy. As the volume of sustainably available biomass resources is limited, defining the contributions from bioenergy to a low-carbon energy system and finding balances – and ideally synergies – between the different possible energy and climate system services that biomass can provide will be very important. The recognized system services include, among others, the flexible operation of bioenergy plants to integrate variable renewable energy sources and to provide negative carbon dioxide (CO2) emissions. Interest in flexible operation of bioenergy value chains, bioenergy with carbon capture and utilization as well as synergies with renewable hydrogen-based value chains has increased recently. The objective of this paper is to present a holistic definition of flexible bioenergy as a system service based on the work conducted in International Energy Agency (IEA) Bioenergy Technology Collaboration Programme's Task 44 Flexible Bioenergy and System Integration, and to provide some practical examples. The paper also presents the different bioenergy system services and considers their definitions and interactions, as this is important in energy system design. The definition of flexible bioenergy shows that the flexibility provision from bioenergy goes far beyond the traditional definition of providing short-term flexibility in the power sector. Indicators to demonstrate the value of services as well as further quantitative assessment of synergies and trade-offs are needed to valorize the different services from bioenergy and create viable business cases.

Published

2024

22. Extremophiles in a changing world

Author

Cowan, Don, Albers, Sonja Verena, Antranikian, Garabed, Atomi, Haruyuki, Averhoff, Beate, Basen, Mirko, Driessen, Arnold J.M., Jebbar, Mohamed, Kelman, Zvi, Kerou, Melina, Littlechild, Jennifer Ann, Müller, Volker Steffen, Schönheit, Peter, Siebers, Bettina, Vorgias, Konstantinos E., Cowan, Don, Albers, Sonja Verena, Antranikian, Garabed, Atomi, Haruyuki, Averhoff, Beate, Basen, Mirko, Driessen, Arnold J.M., Jebbar, Mohamed, Kelman, Zvi, Kerou, Melina, Littlechild, Jennifer Ann, Müller, Volker Steffen, Schönheit, Peter, Siebers, Bettina, and Vorgias, Konstantinos E.

Abstract

Extremophiles and their products have been a major focus of research interest for over 40 years. Through this period, studies of these organisms have contributed hugely to many aspects of the fundamental and applied sciences, and to wider and more philosophical issues such as the origins of life and astrobiology. Our understanding of the cellular adaptations to extreme conditions (such as acid, temperature, pressure and more), of the mechanisms underpinning the stability of macromolecules, and of the subtleties, complexities and limits of fundamental biochemical processes has been informed by research on extremophiles. Extremophiles have also contributed numerous products and processes to the many fields of biotechnology, from diagnostics to bioremediation. Yet, after 40 years of dedicated research, there remains much to be discovered in this field. Fortunately, extremophiles remain an active and vibrant area of research. In the third decade of the twenty-first century, with decreasing global resources and a steadily increasing human population, the world’s attention has turned with increasing urgency to issues of sustainability. These global concerns were encapsulated and formalized by the United Nations with the adoption of the 2030 Agenda for Sustainable Development and the presentation of the seventeen Sustainable Development Goals (SDGs) in 2015. In the run-up to 2030, we consider the contributions that extremophiles have made, and will in the future make, to the SDGs.

Published

2024

23. Expression in poplar of dehydroshikimate dehydratase induces transcriptional and metabolic changes in the phenylpropanoid pathway

Author

Turumtay, Emine Akyuz, Turumtay, Emine Akyuz, Turumtay, Halbay, Tian, Yang, Lin, Chien-Yuan, Chai, Yen Ning, Louie, Katherine B, Chen, Yan, Lipzen, Anna, Harwood, Thomas, Kumar, Kavitha Satish, Bowen, Benjamin P, Wang, Qian, Mansfield, Shawn D, Blow, Matthew J, Petzold, Christopher J, Northen, Trent R, Mortimer, Jenny C, Scheller, Henrik V, Eudes, Aymerick, Turumtay, Emine Akyuz, Turumtay, Emine Akyuz, Turumtay, Halbay, Tian, Yang, Lin, Chien-Yuan, Chai, Yen Ning, Louie, Katherine B, Chen, Yan, Lipzen, Anna, Harwood, Thomas, Kumar, Kavitha Satish, Bowen, Benjamin P, Wang, Qian, Mansfield, Shawn D, Blow, Matthew J, Petzold, Christopher J, Northen, Trent R, Mortimer, Jenny C, Scheller, Henrik V, and Eudes, Aymerick

Abstract

Modification of lignin in feedstocks via genetic engineering aims to reduce biomass recalcitrance to facilitate efficient conversion processes. These improvements can be achieved by expressing exogenous enzymes that interfere with native biosynthetic pathways responsible for the production of the lignin precursors. In-planta expression of a 3-dehydroshikimate dehydratase (QsuB) in poplar trees reduced lignin content and altered their monomer composition, which enabled higher yields of sugars after cell wall polysaccharide hydrolysis. Understanding how plants respond to such genetic modifications at the transcriptional and metabolic levels is needed to facilitate further improvement and field deployment. In this work, we amassed fundamental knowledge on lignin-modified QsuB poplar using RNA-seq and metabolomics. The data clearly demonstrate that changes in gene expression and metabolite abundance can occur in a strict spatiotemporal fashion, revealing tissue-specific responses in the xylem, phloem, or periderm. In the poplar line that exhibits the strongest reduction in lignin, we found that 3% of the transcripts had altered expression levels and ~19% of the detected metabolites had differential abundance in the xylem from older stems. Changes affect predominantly the shikimate and phenylpropanoid pathways as wells as secondary cell wall metabolism, and result in significant accumulation of hydroxybenzoates derived from protocatechuate and salicylate.

Published

2024

24. Optimising sewage sludge anaerobic digestion for resource recovery in wastewater treatment plants

Author

Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. GEMMA - Grup d'Enginyeria i Microbiologia del Medi Ambient, Ferrer Martí, Ivet, Passos, Fabiana Lopes del Rei, Romero Merino, Eva, Vázquez Lima, Felícitas, Font Segura, Xavier, Universitat Politècnica de Catalunya. Departament d'Enginyeria Civil i Ambiental, Universitat Politècnica de Catalunya. GEMMA - Grup d'Enginyeria i Microbiologia del Medi Ambient, Ferrer Martí, Ivet, Passos, Fabiana Lopes del Rei, Romero Merino, Eva, Vázquez Lima, Felícitas, and Font Segura, Xavier

Abstract

Recovering resources from sludge generated during wastewater treatment is both an opportunity and a challenge. Thermophilic anaerobic digestion may optimise biogas production and digested sludge properties for further valorisation, in the framework of a circular economy. Thus, this study aimed at evaluating the effect of operational conditions, i.e. temperature, solids concentration in the sludge, and solids retention time (SRT) on the methane production, volatile fatty acids (VFA) concentration, digested sludge hygienisation, and dewaterability, during long-term anaerobic digestion. This is the first time that sludge anaerobic digestion has been evaluated for over 500 days varying control parameters for assessing concomitantly biogas, VFA, and pathogen removal outcomes with focus on resource recovery. Results showed how by shifting from mesophilic (38¿°C) to thermophilic (55¿°C) conditions, with a short SRT (10 days) in the reactor, the process performance was optimised. Indeed, the methane production reached a maximum of 0.4 m3CH4/m3reactor·d, with a VFA concentration of 4.0¿g COD/L and complete pathogen removal in the digestate, for a safe agricultural reuse. Therefore, the transition from mesophilic to thermophilic anaerobic digesters seems beneficial for the valorisation of by-products and promoting the circular economy in wastewater treatment plants., Peer Reviewed, Postprint (published version)

Published

2024

25. Comparison of simultaneous saccharification and fermentation with LPMO-supported hybrid hydrolysis and fermentation

Author

Tang, Chaojun, Cavka, Adnan, Bui, Mai, Jönsson, Leif J., Tang, Chaojun, Cavka, Adnan, Bui, Mai, and Jönsson, Leif J.

Abstract

Enzymatic saccharification is used to convert polysaccharides in lignocellulosic biomass to sugars which are then converted to ethanol or other bio-based fermentation products. The efficacy of commercial cellulase preparations can potentially increase if lytic polysaccharide monooxygenase (LPMO) is included. However, as LPMO requires both a reductant and an oxidant, such as molecular oxygen, a reevaluation of process configurations and conditions is warranted. Saccharification and fermentation of pretreated softwood was investigated in demonstration-scale experiments with 10 m3 bioreactors using an LPMO-containing cellulase preparation, a xylose-utilizing yeast, and either simultaneous saccharification and fermentation (SSF) or hybrid hydrolysis and fermentation (HHF) with a 24-hour or 48-hour initial phase and with 0.15 vvm aeration before addition of the yeast. The conditions used for HHF, especially with 48 h initial phase, resulted in better glucan conversion, but in poorer ethanol productivity and in poorer initial ethanol yield on consumed sugars than the SSF. In the SSF, hexose sugars such as glucose and mannose were consumed faster than xylose, but, in the end of the fermentation >90% of the xylose had been consumed. Chemical analysis of inhibitory pretreatment by-products indicated that the concentrations of heteroaromatic aldehydes (such as furfural), aromatic aldehydes, and an aromatic ketone decreased as a consequence of the aeration. This was attributed mainly to evaporation caused by the gas flow. The results indicate that further research is needed to fully exploit the advantages of LPMO without compromising fermentation conditions.

Published

2024

26. Methane production from locally available ruminant feedstuffs in Ethiopia : an in vitro study

Author

Bekele, Wondimagegne, Huhtanen, Pekka, Zegeye, Abiy, Simachew, Addis, Siddique, Abu Bakar, Albrectsen, Benedicte Riber, Ramin, Mohammad, Bekele, Wondimagegne, Huhtanen, Pekka, Zegeye, Abiy, Simachew, Addis, Siddique, Abu Bakar, Albrectsen, Benedicte Riber, and Ramin, Mohammad

Abstract

Achieving optimal nutrient composition in locally sourced ruminant feeds is important, but can be challenging in resource-limited production systems. For example, improving the composition of available local feed resources is a key obstacle to efficiently mitigating enteric methane (CH4) emissions in ruminants. This study characterized the nutritional content and in vitro methane (CH4) yield of ruminant feedstuffs accessible in Ethiopia. A survey of 60 experienced farmers in two representative districts in Amhara region, Ethiopia, provided 33 feed samples, which were classified into four ruminant feed categories: Grasses (n=10); indigenous plants (trees, shrubs, herbaceous plants) (n=13); crop residues (n=5); and agro-industrial by-products (n=5). Nutritional composition was assessed by proximate and detergent methods. Methane yield (g CH4/kg feed dry matter (DM)) and total gas yield (L/kg DM) were evaluated using a fully automated in vitro gas production system. A colorimetric assay was conducted to measure condensed tannin content (CT, mg/g) in relevant feeds. Lower crude protein (CP) values were observed for the grass (mean 65.2 g/kg DM) and crop residues (mean 54.5 g/kg DM) categories. Agro-industrial by-products had the highest CP (mean 260 g/kg DM), while indigenous plants exhibited intermediate levels (163 g/kg DM). There was significant variation in CH4 yield (P<0.01) between grasses (12.4–24.7 g/kg DM) indigenous plants (1.8–19.3 g/kg DM), and agro-industrial by-products (8.1–26.9 g/kg DM). The indigenous plant Trifolium acaule gave the lowest in vitro CH4 yield (1.8 g/kg DM). A positive relationship was observed between in vitro dry matter digestibility (IVDMD), CH4, and total gas yield. Percentage of CH4 in total gas production varied with feed category (grasses 14.5–19.6%; indigenous plants 3.1–16.9%; crop residues 15.8–20.6%; agro-industrial by-products 12.8–18.7%), and within category, e.g., Trifolium acaule (3.1%), Acacia nilotica L. (7.1%), Ziziph

Published

2024

27. Zoektocht beste slibverwerkingstechnologie: er zijn (nog) geen betere

Author

Reedijk, P. and Reedijk, P.

Abstract

In 2022 zijn Waterschap Vallei en Veluwe en GMB BioEnergie – ondersteund door Royal HaskoningDHV – samen gaan zoeken naar oplossingen om zuiveringsslib nog duurzamer te verwerken. De projectpartners hebben mogelijke nieuwe en duurzamere technieken voor het verwerken van slib en het terugwinnen van grondstoffen onderzocht in binnen- en buitenland. Inmiddels is dit zogeheten Ontwikkeltraject Slibverwerking bijna afgerond met een verrassende uitkomst: er zijn geen betere.

Published

2024

28. Public acceptance of biomass for bioenergy : The need for feedstock differentiation and communicating a waste utilization frame

Author

van Dijk, Mathilde, Goedegebure, Robert, Nap, Jan-Peter, van Dijk, Mathilde, Goedegebure, Robert, and Nap, Jan-Peter

Abstract

Climate change calls for an energy transition utilizing all available renewable energy resources, such as bioenergy from biomass. However, the use of biomass is debated in society, and public acceptance is low or lacking. This survey-based research demonstrates for the first time that public acceptance of bioenergy hinges on (a) the type of biomass feedstock used to generate bioenergy and (b) the perceptions of the effectiveness of bioenergy in contributing to the energy transition. A survey-embedded vignette experiment (with 409 Dutch participants) shows that public acceptance of the biomass feedstocks 'wood' and 'energy crops' is significantly lower than the acceptance of 'organic waste' and 'manure' for bioenergy. These results indicate that the biomass feedstock type should be more carefully considered and specified in future research and communication on public acceptance of bioenergy. Thematic coding and bootstrapped mediation analyses identified the perceived effectivity of bioenergy in contributing to the energy transition as a prime explanatory (i.e., mediating) variable for acceptance. A subsequent message-framing communication experiment (with 414 Dutch participants) demonstrates that emphasizing biomass feedstock as a form of waste utilization is a frame that helps to increase public acceptance of bioenergy. The waste utilization frame notably improves the perceptions of the effectiveness of bioenergy as contributing to the energy transition for the two lesser accepted biomass feedstocks. The emphasis on biomass feedstock type as a form of waste treatment can improve strategic communications on bioenergy and foster wider public acceptance of bioenergy in the transition toward a more sustainable energy system.

Published

2024

29. Catabolism and interactions of syntrophic propionate- and acetate oxidizing microorganisms under mesophilic, high-ammonia conditions

Author

Weng, Nils, Singh, Abhijeet, Ohlsson, Jonas A., Dolfing, Jan, Westerholm, Maria, Weng, Nils, Singh, Abhijeet, Ohlsson, Jonas A., Dolfing, Jan, and Westerholm, Maria

Abstract

Microbial inhibition by high ammonia concentrations is a recurring problem that significantly restricts methane formation from intermediate acids, i.e., propionate and acetate, during anaerobic digestion of protein-rich waste material. Studying the syntrophic communities that perform acid conversion is challenging, due to their relatively low abundance within the microbial communities typically found in biogas processes and disruption of their cooperative behavior in pure cultures. To overcome these limitations, this study examined growth parameters and microbial community dynamics of highly enriched mesophilic and ammonia-tolerant syntrophic propionate and acetate-oxidizing communities and analyzed their metabolic activity and cooperative behavior using metagenomic and metatranscriptomic approaches. Cultivation in batch set-up demonstrated biphasic utilization of propionate, wherein acetate accumulated and underwent oxidation before complete degradation of propionate. Three key species for syntrophic acid degradation were inferred from genomic sequence information and gene expression: a syntrophic propionate-oxidizing bacterium (SPOB) "Candidatus Syntrophopropionicum ammoniitolerans", a syntrophic acetate-oxidizing bacterium (SAOB) Syntrophaceticus schinkii and a novel hydrogenotrophic methanogen, for which we propose the provisional name "Candidatus Methanoculleus ammoniitolerans". The results revealed consistent transcriptional profiles of the SAOB and the methanogen both during propionate and acetate oxidation, regardless of the presence of an active propionate oxidizer. Gene expression indicated versatile capabilities of the two syntrophic bacteria, utilizing both molecular hydrogen and formate as an outlet for reducing equivalents formed during acid oxidation, while conserving energy through build-up of sodium/proton motive force. The methanogen used hydrogen and formate as electron sources. Furthermore, results of the present study provided a framework for fu

Published

2024

30. Green heterogeneous catalysts derived from fermented kola nut pod husk for sustainable biodiesel production

Author

Asuquo, Asuquo Jackson, Zhang, Xiaolei, Lin, Leteng, Li, Jun, Asuquo, Asuquo Jackson, Zhang, Xiaolei, Lin, Leteng, and Li, Jun

Abstract

The use of green heterogeneous catalysts that are obtained from waste agricultural biomass can make the production of biodiesel more economical. In this research, three solid base heterogeneous catalysts (Catalyst A, B, and C) were synthesized from kola nut pod husks, and the synergistic effects of the elemental composition on catalytic activities for biodiesel production were studied. The results revealed a high surface area of Catalysts A, B, and C at 419.90 m2/g, 430.54 m2/g, and 432.57 m2/g, respectively. Their corresponding pore diameters are 3.53 nm, 3.48 nm, and 3.32 nm, showing that the catalysts are mesoporous in nature. The X-ray Fluorescence (XRF) results revealed the presence of a variety of alkaline earth metals and their corresponding metal oxides in substantial amounts. Catalyst A was produced with the highest concentration of calcium at 40.84 wt.% and calcium oxide at 68.02 mole%. The substantial concentration of other elements, such as potassium, magnesium, and aluminum, and their corresponding metal oxides are the proof of high catalytic activity of the produced green catalysts. The high CaO contents of all three produced catalysts and their high surface areas indicate their strong potential for good catalytic activities applied to the synthesis of biodiesel.

Published

2024

31. Dimensionering av nödkylningssystem i en fast biobränslepanna : En beräkningsmodell i Simulink

Author

Jansson, Eira and Jansson, Eira

Abstract

Samhället har ökade energibehov och krav på minskad miljöpåverkan, vilket gör biobränsle viktigt för hållbar energi. Biovärmeverks anläggningarna måste utvecklas för att bli mer miljövänliga och kunna ersätta fossila bränslen. De utsätts för höga termiska, kemiska och mekaniska påfrestningar, vilket innebär säkerhetsrisker. Således finns det lagar på trycksatta anordningar att fungera utan el genom att säkerhetsställa att överhettning undviks. Därför har biobränslepannor nödkylningssystem som förhindrar överhettning genom att hålla rörtemperaturen under den temperatur som pannan byggs för att klara, i denna studie är pannan dimensionerad för 140–150°C. Systemet, som består av stålrör med kallt vatten, aktiveras vid elavbrott eller temperaturökning, och luftflödet samt bränsletillförseln stoppas. Eftersom det är svårt att fastställa nödkylningseffekten överdimensioneras nödkylaren. Det är vanligt att nödkylaren tillverkas i diskreta storlekar och inte skräddarsys för varje panna. Vilket kan leda till onödig materialanvändning, kostnader och utsläpp. Studien, i samarbete med AKJ Energiteknik AB, syftar till att ge underlag för dimensionering av nödkylningssystemet för att minska kostnader och utsläpp. Målet är att skapa en dynamisk modell i Simulink och MATLAB och verifiera den med mätdata. Studien undersöker nödkylningssystemets funktion, kylbehov samt vatten- och materialåtgång, och utvärderar påverkan på kostnad och miljö genom CO2-ekvivalenter med förslag på åtgärder för systemets dimensioner. Den dynamiska modellen byggdes upp i Simulink och MATLAB Pannan konstruerades i zoner utifrån dimensionsförändringar i pannans rörkanaler där rökgasen flödade igenom samt förenklad beräkning för ugnens temperatur och rökgasflöde. Modellen verifierades mot mätdata från kapaciteter, temperaturer på rökgasen och vattnet samt granskades från företaget. Modellen kontrollerades utifrån känslighetsanalys, litteratur och värmeövergångstal och således skapades en trovärdig modell, Society has increasing energy demands and requirements for reduced environmental impact, making biofuel essential for sustainable energy. Facilities must be developed to become more environmentally friendly and capable of replacing fossil fuels. These facilities are subjected to high thermal, chemical, and mechanical stresses, which pose safety risks. Consequently, regulations exist for pressurized devices that operate without power by ensuring overheating is avoided. Therefore, biofuel boilers are equipped with emergency cooling systems to prevent overheating by maintaining the tube temperature below the design threshold, which in this study is 140–150°C. The system, composed of steel tubes containing cold water, activates in the event of a power outage or temperature increase, and airflow and fuel supply are halted. Since determining the emergency cooling effect is challenging, the emergency cooler is often oversized. It is common for emergency coolers to be manufactured in discrete sizes rather than customized for each boiler, which can lead to unnecessary material usage, costs, and emissions. This study, conducted in collaboration with AKJ Energiteknik AB, aims to provide insights for sizing emergency cooling systems to reduce costs and emissions. The objective is to develop a dynamic model in Simulink and MATLAB, validated with measurement data. The study investigates the emergency cooling system's function, cooling requirements, water and material consumption, and evaluates their impact on costs and the environment through CO2- equivalents, proposing dimensioning measures for the system. The dynamic model was constructed in Simulink and MATLAB. The boiler was segmented into zones based on changes in the boiler's pipe channels where flue gas flows, alongside simplified calculations for furnace temperature and flue gas flow. The model was validated against measurement data for capacities, flue gas and water temperatures, and reviewed by the company. Sensitiv

Published

2024

32. BECCS-Hub in Stockholm: Integration of biogas into the BECCS value chain

Author

Salicrú Llanos, Miquel and Salicrú Llanos, Miquel

Abstract

Bioenergi med avskiljning och lagring av koldioxid (BECCS) håller på att utvecklas till en viktig teknik för negativa utsläpp och planeras spela en avgörande roll för Sveriges mål om noll nettoutsläpp av koldioxid till 2045. Stora BECCS-anläggningar förväntas, till exempel den som planeras i Värtahamnen av Stockholm Exergi. Mindre punktkällor för koldioxidutsläpp, som avloppsreningsverket i Käppala, en biogasproducent, skulle också kunna bidra till negativa utsläpp genom BECCS, dvs. genom att fånga upp biogen koldioxid från anaerob jäsning. Ekonomiska faktorer begränsar dock implementeringen av hela BECCS-värdekedjan i mindre skala. Genom att använda en närliggande större BECCS-anläggning kan dessa kostnadsbarriärer övervinnas genom att skapa nav för BECCS och utnyttja synergier. I detta arbete undersöks de tekniska och ekonomiska utmaningarna med att integrera en CO2-ström från Käppala WWTP med Stockholm Exergis anläggning. Olika scenarier för CO2-integrering identifierades, med beaktande av flera faktorer, inklusive CO2-koncentration och renhetsbegränsningar för kondensering, kortdistanstransport och affärsmodell bakom biogasproducenten. Käppala reningsverk släpper för närvarande ut biogen CO2 i form av en CO2/luftblandning till atmosfären. Detta arbete visade att CO2 kan tas emot av Stockholm Exergi i form av en CO2/luftblandning, CO2-gas eller kondenserad CO2. Käppala reningsverk skulle antingen kunna behålla sin nuvarande vattenreningsprocess, som ger CO2/luftblandningen, eller modernisera sin biogasuppgraderingsprocess för att producera koncentrerad CO2. Vidare konstaterades att en rörledning är det mest ekonomiska alternativet för kortdistanstransport av CO2, antingen i en blandning eller i koncentrerad form, men långa ledtider kräver långsiktig planering. Om transporten istället sker med lastbilar krävs en ombyggnad och ett förvätskningssteg vid Käppalaverket. En litteraturgenomgång av tillgängliga tekniker för Käppala reningsverk identifierade en membran, Bio-energy with carbon capture and storage (BECCS) is emerging as a major negative emission technology and is scheduled to play a crucial role to Sweden’s net-zero goal by 2045. Large BECCS facilities are anticipated, such as the one planned in Värtahamnen by Stockholm Exergi. Smaller CO2 point sources like Käppala wastewater treatment plant (WWTP), a biogas producer, could also contribute to negative emissions through BECCS, i.e., by capturing the biogenic CO2 from anaerobic fermentation. However, economic constraints limit the implementation of the entire BECCS value chain on a smaller scale. Utilizing a nearby larger BECCS facility can help overcome these cost barriers by creating hubs for BECCS, leveraging synergies. This work explores the technical and economic challenges of integrating a CO2 stream from Käppala WWTP with Stockholm Exergi’s facility. Various scenarios for CO2 integration were identified, considering multiple factors, including CO2 concentration and purity constraints for liquefaction, short-distance transport, and business model behind the biogas producer. Käppala WWTP currently releases biogenic CO2 in the form of a CO2/air mixture to the atmosphere. This work found that CO2 can be received by Stockholm Exergi in the form of a CO2/air mixture, CO2 gas, or liquefied CO2. Whereas Käppala WWTP could either keep their current water scrubbing process, yielding the CO2/air mixture, or perform a revamp of their biogas upgrading process to produce concentrated CO2. Moreover, it was found that a pipeline is the most economical option for short-distance transport of CO2, either in a mixture or concentrated form, but long lead times make necessary long-term planning. If instead transport is carried out by trucks, a revamp and a liquefaction stage at Käppala WWTP are necessary. A literature review on the available technologies targeted at Käppala WWTP identified a membrane process as the most appropriate technology for a revamp of the biogas upgrading

Published

2024

33. The Value-chain of Biochar : Case developement and value validation for providers and customers from an environmental, economic and social perspective

Author

Eriksson, Markus, Engel, Samuel, Eriksson, Markus, and Engel, Samuel

Abstract

The growing need for climate mitigation solutions has contributed so thatbiochar has gained significant interest. Primary for its ability as a carbon sinkbut there is also a growing interest due to several other aspects within industriese.g. substitution effects, increased resource efficiency, an enabler forindustrial symbiosis, and its beneficial properties when put in soil that can increasegrowth. Previous studies of biochar have been dominant within the environmentalperspective of biochar, analyzing detailed characteristics of its propertiesand carbon sink potential. Some studies have a holistic perspective reflectingon countries specific energy mix and the different benefits of producingbiochar. However, previous studies are far too few to determine the value-chainof biochar. Hence previous studies have knowledge gaps within the holistic lifecycle approach from a provider or customer perspective of biochar, not reflectingon demand for quality requirements in different utilization areas and markets.The need for validation of the environmental and the economic performanceof biochar has to be established, and the economic perspective of biochar hasmajor knowledge gaps since previous studies are scarce. The study aims to establish the value-chain of biochar by evaluating theenvironmental, economic, and social perspectives through life cycle thinking.The core of the study is to distinguish value, which first has to reflect thebiochar quality requirements from providers and customers, captured throughinterviews and literature research. The quality requirements enable a goal forproducing biochar and determine what processes and biomass are needed fordifferent markets. This is evaluated through a case development which considersthe different quality requirements. Life cycle assessment (LCA) with acradle-to-grave perspective and life cycle costing (LCC) with a cradle-to-gatewere then used to distinguish biochar´s environmental and economic performance. The interviews and

Published

2024

34. Functional Assessment of Microbial Biogas Communities Acclimatized to Synthetic Feedstock with High Ammonia

Author

Tsamadou, Vasiliki and Tsamadou, Vasiliki

Published

2024

35. Biofuels and Bioenergy production in a circular bioconomy - A brief overview

Author

Govindarajan, Venkatesh, Gurunathan, Baskar, Govindarajan, Venkatesh, and Gurunathan, Baskar

Abstract

The circular bioeconomy can be visualized as a set of ‘many through many to many’ relationships, connecting different types of biomaterials from a variety of source-sectors via diverse processes and technologies in biorefineries, to end-use applications availing of the resulting valorized bio-products. One end-use sector is the energy sector; the end-use applications being as sources of heat and electricity, and as transport fuels. The focus of the chapters in this book is on bioenergy and biofuels in a circular bioeconomy, while this introductory chapter is an overview of published research in this niche area

Published

2024

36. Integrated products biorefinery options within the Swedish pulp and paper industry: Current status

Author

Agnihotri, Swarnima, Sárvári Horváth, Ilona, Agnihotri, Swarnima, and Sárvári Horváth, Ilona

Abstract

Pulp and paper manufacturing ranks as one of the most water and energy-intensive sectors globally, invariablyleading to significant environmental pollution e.g. issues related to air pollution and waste disposal. Also, asglobal competition intensifies, prices of forest products are expected to keep decreasing. To ensure their viability,traditional producers must augment their revenue streams by diversifying into the production of bioenergy andbiomaterials, alongside traditional wood, pulp, and paper products. A feasible solution is the integrated productsbiorefineries which provide a distinctive chance to pulp and paper industry to enhance revenues as well asreduce their environmental impact. Since pulp and paper stands as the predominant industry in Sweden, thisreview article explores the emerging biorefinery process options and main technological pathways beingdeveloped within Swedish pulp and paper mills. It also delves into the significant challenges that are beingencountered in this evolving landscape and what possibilities lie ahead for responsible and sustainable pulp andpaper operations.

Published

2024

37. Biogas potential of organosolv pretreated wheat straw as mono and co-substrate: substrate synergy and microbial dynamics

Author

Sarkar, Omprakash, Rova, Ulrika, Christakopoulos, Paul, Matsakas, Leonidas, Sarkar, Omprakash, Rova, Ulrika, Christakopoulos, Paul, and Matsakas, Leonidas

Abstract

Anaerobic digestion (AD) technology can potentially address the gap between energy demand and supply playing a crucial role in the production of sustainable energy from utilization of biogenic waste materials as feedstock. The biogas production from anaerobic digestion is primarily influenced by the chemical compositions and biodegradability of the feedstock. Organosolv-steam explosion offers a constructive approach as a promising pretreatment method for the fractionation of lignocellulosic biomasses delivering high cellulose content.This study showed how synergetic co-digestion serves to overcome the challenges of mono-digestion's low efficiency. Particularly, the study evaluated the digestibility of organosolv-steam pretreated wheat straw (WSOSOL) in mono as well as co-digesting substrate with cheese whey (CW) and brewery spent grains (BSG). The highest methane yield was attained with co-digestion of WSOSOL + CW (338 mL/gVS) representing an enhanced biogas output of 1–1.15 times greater than its mono digestion. An ammonium production was favored under co-digestion strategy accounting for 921 mg/L from WSOSOL + BSG. Metagenomic study was conducted to determine the predominant bacteria and archaea, as well as its variations in their populations and their functional contributions during the AD process. The Firmicutes have been identified as playing a significant role in the hydrolysis process and the initial stages of AD. An enrichment of the most prevalent archaea genera enriched were Methanobacterium, Methanothrix, and Methanosarsina. Reactors digesting simpler substrate CW followed the acetoclastic, while digesting more complex substrates like BSG and WSOSOL followed the hydrogenotrophic pathway for biomethane production. To regulate the process for an enhanced AD process to maximize CH4, a comprehensive understanding of microbial communities is beneficial., Full text license: CC BY 4.0

Published

2024

38. Enhancement of Biogas (Methane) Production from Cow Dung Using a Microbial Electrochemical Cell and Molecular Characterization of Isolated Methanogenic Bacteria

Author

Bhatt, Puja, Poudyal, Pranita, Dhungana, Pradip, Prajapati, Bikram, Bajracharya, Suman, Yadav, Amar Prasad, Bhattarai, Tribikram, Sreerama, Lakshmaiah, Joshi, Jarina, Bhatt, Puja, Poudyal, Pranita, Dhungana, Pradip, Prajapati, Bikram, Bajracharya, Suman, Yadav, Amar Prasad, Bhattarai, Tribikram, Sreerama, Lakshmaiah, and Joshi, Jarina

Abstract

Biogas has long been used as a household cooking fuel in many tropical counties, and it has the potential to be a significant energy source beyond household cooking fuel. In this study, we describe the use of low electrical energy input in an anaerobic digestion process using a microbial electrochemical cell (MEC) to promote methane content in biogas at 18, 28, and 37 °C. Although the maximum amount of biogas production was at 37 °C (25 cm3), biogas could be effectively produced at lower temperatures, i.e., 18 (13 cm3) and 28 °C (19 cm3), with an external 2 V power input. The biogas production of 13 cm3 obtained at 18 °C was ~65-fold higher than the biogas produced without an external power supply (0.2 cm3). This was further enhanced by 23% using carbon-nanotubes-treated (CNT) graphite electrodes. This suggests that the MEC can be operated at as low as 18 °C and still produce significant amounts of biogas. The share of CH4 in biogas produced in the controls was 30%, whereas the biogas produced in an MEC had 80% CH4. The MEC effectively reduced COD to 42%, whereas it consumed 98% of reducing sugars. Accordingly, it is a suitable method for waste/manure treatment. Molecular characterization using 16s rRNA sequencing confirmed the presence of methanogenic bacteria, viz., Serratia liquefaciens and Zoballella taiwanensis, in the inoculum used for the fermentation. Consistent with recent studies, we believe that electromethanogenesis will play a significant role in the production of value-added products and improve the management of waste by converting it to energy., Godkänd;2024;Nivå 0;2024-06-14 (joosat);Funder: Tribhuvan University under National Priority Area Research Project (TU-NPAR-077/78-ERG-07);Full text license: CC BY

Published

2024

39. Climate performance of liquefied biomethane with carbon dioxide utilization or storage

Author

Gustafsson, Marcus, Cordova, Stephanie, Svensson, Niclas, Eklund, Mats, Gustafsson, Marcus, Cordova, Stephanie, Svensson, Niclas, and Eklund, Mats

Abstract

In the process of upgrading biogas to biomethane for gas grid injection or use as a vehicle fuel, biogenic carbon dioxide (CO₂) is separated and normally emitted to the atmosphere. Meanwhile, there are a number of ways of utilizing CO₂ to reduce the dependency on fossil carbon sources. This article assesses the climate performance of liquefied biomethane for road transport with different options for utilization or storage of CO₂. The analysis is done from a life cycle perspective, covering the required and avoided processes from biogas production to the end use of biomethane and CO₂. The results show that all of the studied options for CO₂ utilization can improve the climate performance of biomethane, in some cases contributing to negative CO₂ emissions. One of the best options, from a climate impact perspective, is to use the CO₂ internally to produce more methane, although continuous supply of hydrogen from renewable sources can be a challenge. Another option that stands out is concrete curing, where CO₂ can both replace conventional steam curing and be stored for a long time in mineral form. Storing CO₂ in geological formations can also lead to negative CO₂ emissions. However, with such long-term storage solutions, opportunities to recycle biogenic CO₂ are lost, together with the possibility of de-fossilizing processes that require carbon, such as chemical production and horticulture., Funding: Kamprad Family Foundation [20200041], Värdeskapande av koldioxid från biogasproduktion

Published

2024

40. Production of biomethane, biohydrogen, and volatile fatty acids from Nordic phytoplankton biomass grown in blended wastewater

Author

Wicker, Rebecca J., Daneshvar, Ehsan, Patel, Alok, Dhar, Bipro Ranjan, Bhatnagar, Amit, Wicker, Rebecca J., Daneshvar, Ehsan, Patel, Alok, Dhar, Bipro Ranjan, and Bhatnagar, Amit

Abstract

Upgrading carbon-negative microalgal biomass to biofuels and value-added products presents a three-pronged solution for waste treatment, carbon capture, and economically viable bioenergy production. Acidogenesis and methanogenesis are versatile processes at the core of anaerobic digestion systems, facilitating the conversion of diverse biogenic substrates into energy and a wide range of biobased products. The present study was conducted to integrate acidogenesis and methanogenesis for coproduction of biohydrogen, biomethane, and volatile fatty acids from Nordic phytoplankton consortia. For this purpose, microalgal consortia was cultivated in a raceway pond equipped with high surface area structures. Harvested microalgal biomass was subjected to thermoalkaline (2% NaOH solution at 121 °C) and enzymatic (cellulase) pretreatments. The hydrolysates of the pretreated biomass were inoculated with thermally treated sludge for acidogenic fermentation and with mixture of untreated sludge and cow dung (1:1 v/v ratio) for anerobic digestion. The acidogenic process produced a significant amount of biohydrogen (maximum 164.8 mL bioH2/VSload) along with volatile fatty acids (maximum 7.9 g COD/L), while methanogenesis resulted in biomethane production of maximum 210.7 mL bioCH4/VSload, accompanied by an ammonium recovery of 1278 mg NH4+/L. These maximum yields were all achieved by enzymatic pretreatment of the biomass fraction harvested from high surface area brush head structures inserted in the raceway pond. These results have important implications for designing phytoplankton cultivation systems and upstream pathways to optimize energy production from carbon-negative phytoplankton biomass., Validerad;2024;Nivå 2;2024-03-28 (hanlid);Funder: Tekniikan Edistämissäätiö (8883);Full text license: CC BY

Published

2024

41. Assessing the bioenergy potential in South America : Projections for 2050

Author

Magne, Angelica, Khatiwada, Dilip, Cardozo, Evelyn, Magne, Angelica, Khatiwada, Dilip, and Cardozo, Evelyn

Abstract

Biomass has enormous potential globally, but it requires sustainable management and conversion into modern bioenergy that aligns with the Sustainable Development Goals (SDGs). This study assesses sustainable biomass potential for energy generation in South America, considering forestry, agriculture, agro-industrial, and municipal solid waste biomass. The Autoregressive Integrated Moving Average (ARIMA) time series forecasting model with data from the Food and Agriculture Organization Corporate Statistical Database (FAOSTAT) and the World Bank up to 2050 is used. In 2021, the total biomass theoretical potential amounts to 1214 million tonnes (Mt), projected to increase to 1371 Mt by 2050. The available technical potential for energy purposes ranges from 796 Mt in 2021 to 916 Mt by 2050, with approximately 66 % attributed to agricultural biomass, 10 % to agro-industrial biomass, 17 % to forestry biomass, and 7 % to municipal waste biomass. Notably, not all countries experience growth in bioenergy potential from 2021 to 2050. Increasing forestry biomass recoverability from 25 % to 75 % enhances the total technical potential by 7 % for 2050. Primary bioenergy potential, utilizing available biomass, ranges from 13,831–15,892 PJ between 2021 and 2050, equivalent to 1278 to 1444 Terawatt hour (TWhe) when considering biomass conversion to electric energy. The share of bioelectricity could be 24 % of the total electricity generation in 2021. Additionally, modern bioenergy could help achieve sustainable development goals and decarbonize the energy sector in the region. This assessment of modern bioenergy potential in South America is relevant for subsequent techno-economic and environmental evaluations towards global energy decarbonization by 2050., QC 20240830

Published

2024

42. A bottom-up regional potential assessment of bioenergy with carbon capture and storage in Germany

Author

Sadr, Mohammad, Esmaeili Aliabadi, Danial, Jordan, Matthias, Thrän, Daniela, Sadr, Mohammad, Esmaeili Aliabadi, Danial, Jordan, Matthias, and Thrän, Daniela

Abstract

Bioenergy with Carbon Capture and Storage (BECCS) is a bio-based Carbon Dioxide Removal Technology (CDR) undergoing detailed and comprehensive screening in many countries. The latest scientific reports emphasized that net-zero targets can not be achieved globally or nationally without deploying such technologies. Germany aims to achieve carbon neutrality by 2045, and negative emissions thereafter, which means a higher demand for CDRs. Despite BECCS being the building block of net-zero policies, its implementation on a national and regional scale presents serious challenges. Therefore, in this study, we analyze the role of BECCS in the German bioenergy system with a spatially detailed bottom-up optimization model that accounts for techno-economics and political aspects of BECCS (e.g., availability of biomass and investment costs). Our analysis demonstrates that BECCS can remove almost 61 Mt CO2 in 2050; however, the outcomes demonstrate sensitivity toward CO2 credit and CO2 prices, which can raise the removal as high as 69 Mt CO2. Additionally, results suggest that removing enough CO2 to achieve carbon neutrality in Germany by 2045 solely through BECCS seems extremely challenging; thus, a portfolio of negative emission technologies will be necessary to contribute. Our findings provide a better understanding of BECCS feasibility and its potential to assist us in achieving climate targets in Germany. Although we apply our model to Germany, the developed tool and insights are generic and can be applied to other countries.

Published

2024

43. WANO policy brief

Author

Hjertø Lind, Anders Torgeir, Flick, Helge, Teräs, Jukka, Heleniak, Timothy, Hjertø Lind, Anders Torgeir, Flick, Helge, Teräs, Jukka, and Heleniak, Timothy

Abstract

Waste management in the northern latitudes is often more challenging than in the more central regions. Under the Arctic climate conditions with large distances between settlements and to the recycling facilities, and relatively smaller markets and volume of produced waste, there are special needs for developing new innovative solutions for waste management. WANO focuses on cross-border business and innovation cooperation in the field of waste management, including municipal and industrial waste, in the regions of Troms, Finnmark and Nordland (Norway), Lapland and North Ostrobothnia (Finland) and Norrbotten (Sweden). The project identifies key actors, technologies, innovation trends, and cross-border collaboration possibilities in the Arctic waste sector. Among the lessons learned so far which are highlighted in this policy brief are that waste management in Norway has already taken important steps to promote innovation and cooperation but that there is a demand for additional knowledge-based expertise among the waste management actors in north Norway. Cross-border initiatives are welcomed in north Norway by the actors. The big hindrance seems to be “know-who”: the Norwegian actors need more information about the actors across the border in north Finland and north Sweden.

Published

2024

44. Structural and thermal investigation of lignocellulosic biomass conversion for enhancing sustainable imperative in progressive organic refinery paradigm for waste-to-energy applications

Author

Qureshi, Tayyab, Farooq, Muhammad, Imran, Shahid, Munir, Muhammad Adeel, Javed, Muhammad Asad, Sohoo, Ihsanullah, Sultan, Muhammad, Rehman, Ateekh Ur, Farhan, Muhammad, Asim, Muhammad, Andresen, John M., Qureshi, Tayyab, Farooq, Muhammad, Imran, Shahid, Munir, Muhammad Adeel, Javed, Muhammad Asad, Sohoo, Ihsanullah, Sultan, Muhammad, Rehman, Ateekh Ur, Farhan, Muhammad, Asim, Muhammad, and Andresen, John M.

Abstract

The depletion of finite fossil fuel reserves and the severe environmental degradation resulting from human activities have compelled the expeditious development and application of sustainable waste to energy technologies. To encapsulate energy and environment in sustainability paradigm, bio waste based energy production is need to be forged in organic bio refinery setup. According to world bioenergy association, biomass can cover 50 % of the primary energy demand of the world. Therefore, the present study focuses on reforming the energy mix for a clean energy generation, where, sample composition of cotton stalk was acidified in dilute (5% wt.) hydrochloric acid (HCL) for analyzing material burnout patterns in biomass conversion systems utilized in organic bio refinery sector. Advanced thermochemical burning technique, which includes pyrolysis and combustion was applied at four different leaching times from 0 to 180 min under nitrogen environment from 0 degrees C to 500 degrees C and air from 500 degrees C to 900 degrees C, respectively. Different analyses including proximate, ultimate, gross calorific value (GCV), thermos-gravimetric, kinetic, XRD, FTIR, SEM-EDS were used for analyzing the degradation of demineralized cotton stalk at different treatment rates. Proximate study demonstrated that cotton stalk leaching for 180 min has efficiently infused HCL, leading in a significant increase in fixed carbon and higher heating value of 20.23 % and 12.48%, respectively, as well as a reduction in carbon footprint of around 54.80%. The findings of proximate was validated by GCV analysis and CHNS analysis as value of carbon and hydrogen has shown increasing behavior with the time delay in demineralization Thermo-gravimetric and derivative thermo-gravimetric data analyses shows an increasing trend of conversion efficiency, with the maximum increase of 98 % reported for sample 3H. TT.DEM. XRD characterization has reported 23 degrees to 25 degrees angle for all the observed p

Published

2024

45. Biomass performance and stability of 5-year outdoor microalgal cultivation for CO2 removal from cement flue gas

Author

Lindehoff, Elin, Mattsson, Lina, Olofsson, Martin, Svensson, Fredrik, Farnelid, Hanna, Legrand, Catherine, Lindehoff, Elin, Mattsson, Lina, Olofsson, Martin, Svensson, Fredrik, Farnelid, Hanna, and Legrand, Catherine

Abstract

The study evaluated removal of industrial CO2 from cement flue gas using algal cultivation. Local polycultures were grown in an up-scaled outdoor photobioreactor over 5 years in northern Europe. Algal biomass was harvested 2–3 times per week and the closed panel system was re-filled with seawater amended with nutrients. Flue gas was fed to the photobioreactor circulatory system in one direction or re-circulated. Removal efficiency of CO2 averaged 9 % in non-recirculation and 17 % in re-circulation modes and reached 20–60 % under best cultivation conditions. Recovery of carbon into algal biomass reached up to 10 g m2d−1 in non-recirculation mode. Biomass performance was explained by circulation mode and shift of polyculture traits. Stability of biomass quality was shown over seasons, with higher relative content of protein in autumn. Toxic elements in biomass were below legal thresholds for upcycling. The study shows feasibility of algal solutions for conversion of waste, applied in temperate climate. © 2023 The Authors

Published

2024

46. Cellulosic biomass fermentation for biofuel production : Review of artificial intelligence approaches

Author

Naveed, Muhammad Hamza, Khan, Muhammad Nouman Aslam, Mukarram, Muhammad, Naqvi, Salman Raza, Abdullah, Abdullah, Haq, Zeeshan Ul, Ullah, Hafeez, Mohamadi, Hamad Al, Naveed, Muhammad Hamza, Khan, Muhammad Nouman Aslam, Mukarram, Muhammad, Naqvi, Salman Raza, Abdullah, Abdullah, Haq, Zeeshan Ul, Ullah, Hafeez, and Mohamadi, Hamad Al

Abstract

Scarcity in fossil fuel reserves and their environmental impacts has forced the world towards the production of clean and environment-friendly fuels called biofuels. This review focuses on the importance of different machine learning models and optimization techniques to simulate and optimize process conditions, yield and parameters in the fermentation of cellulosic biomass from fifty recent studies. The superiority of ML models, especially ANN dominance in 70 % of studies with highest coefficient of regression over conventional techniques in the production of bioethanol and biohydrogen is comprehensively reviewed. Research gaps and studies directed toward the usage of most optimum ML models in future are directed after the sensitivity analysis with 5 % variation that suggest the stability of ML models. It is intended to spur further investigation into the development and use of ML models combined with optimization methods and CFD in the fermentation process to produce bioethanol and biohydrogen.

Published

2024

47. Assessing the impact of seasonality on bioenergy production from energy crops in Germany, considering just-in-time philosophy

Author

Sadr, Mohammad, Esmaeili Aliabadi, Danial, Avşar, B., Thrän, Daniela, Sadr, Mohammad, Esmaeili Aliabadi, Danial, Avşar, B., and Thrän, Daniela

Abstract

The availability of biomass is strongly influenced by seasonality, which can affect the production of biofuels, biogas, and bio-based products in the downstream bioenergy supply chain. Rapeseed, maize silage, sugar beet, wheat, and grass from grassland are the most popular energy crops; they play a significant role in the German bioenergy strategy and are being discussed extensively in the current gas shortage context. Most models in the literature assume yearly temporal resolution for these energy crops, which can negatively impact the accuracy of results. This problem is increasingly relevant under weather conditions that are varying increasingly due to climate change; in this study we therefore employ the extended bioenergy optimization model (BENOPTex) to explore the impact of seasonality on the optimal deployment of biomass from energy crops in bioenergy production in the German heat, power, and transport sectors, which typically show high dependency on fossil fuels. First, we increased the model's temporal resolution using available datasets and documents. Next, the varying availability factors were embedded in the optimization model, considering the no-storage policy for energy crops in accordance with the just-in-time philosophy. Finally, the outcomes of the BENOPTex with annual resolution were contrasted with the results including the effects of seasonality, while considering various objective functions. We demonstrated a shift toward the consumption of woody biomass until 2045 due to its longer shelf life and improved storability. The energy demand stemming from summer leisure travel was also anticipated to exceed the bioenergy system's capacity. The insights provided here might be interesting for policymakers who design roadmaps for bioenergy development with a more resilient energy supply.

Published

2024

48. Advanced SQL-Database for bioenergy technologies - A catalogue for bio-resources, conversion technologies, energy carriers, and supply applications

Author

Dotzauer, M., Radtke, K.S., Jordan, Matthias, Thrän, Daniela, Dotzauer, M., Radtke, K.S., Jordan, Matthias, and Thrän, Daniela

Abstract

Bioenergy is a crucial element of the future energy system with wide range of applications in electricity, heat and transport. A major challenge for the analysis and optimisation of the bioenergy system is the degree of diversity and complexity compared to wind or solar energy. A coherent database for studying the role of bioenergy in the energy system needs to cover the different entities such as bio-resources, conversion procedures and process chains. Since there is no comprehensive data collection for bioenergy so far, we develop a SQLite database by merging several existing datasets and additional information. The resulting Bio-Energy Technology Database (BET.db) provides a consistent set of 141 feedstocks as well as energy carriers, 259 conversion technologies, and 134 energy supply concepts. The proof of concept within a bioenergy system modelling a wide range of technologies for the electricity, heat and transport sectors using the BENOPT model has been successful. By providing a one-stop-shop solution for techno-economic information about on the bioenergy nexus, this blind spot can be avoided for further investigations. The current stage of development is an intermediate prototype that will be developed into a more versatile and interactive web application later on.

Published

2024

49. Perennializing Marginal Croplands: Going Back to the Future to Mitigate Climate Change with Resilient Biobased Feedstocks

Author

Ramirez, Salvador, II, Schmer, Marty R., Jin, Virginia L., Mitchell, Robert B., Stewart, Catherine E., Parsons, Jay, Redfearn, Daren D., Quinn, John J., Varvel, Gary E., Vogel, Kenneth P., Follett, Ronald F., Ramirez, Salvador, II, Schmer, Marty R., Jin, Virginia L., Mitchell, Robert B., Stewart, Catherine E., Parsons, Jay, Redfearn, Daren D., Quinn, John J., Varvel, Gary E., Vogel, Kenneth P., and Follett, Ronald F.

Abstract

Managing annual row crops on marginally productive croplands can be environmentally unsustainable and result in variable economic returns. Incorporating perennial bioenergy feedstocks into marginally productive cropland can engender ecosystem services and enhance climate resiliency while also diversifying farm incomes. We use one of the oldest bioenergy-specific field experiments in North America to evaluate economically and environmentally sustainable management practices for growing perennial grasses on marginal cropland. This long-term field trial called 9804 was established in 1998 in eastern Nebraska and compared the productivity and sustainability of corn (Zea mays L.)—both corn grain and corn stover—and switchgrass (Panicum virgatum L.) bioenergy systems under different harvest strategies and nitrogen (N) fertilizer rates. This experiment demonstrated that switchgrass, compared to corn, is a reliable and sustainable bioenergy feedstock. This experiment has been a catalyst for other bioenergy projects which have also expanded our understanding of growing and managing bioenergy feedstocks on marginal cropland. We (1) synthesize research from this long-term experiment and (2) provide perspective concerning both the knowledge gained from this experiment and knowledge gaps and how to fill them as well as the role switchgrass will play in the future of bioenergy.

Published

2024

50. Methane yield response to pretreatment is dependent on substrate chemical composition: a meta-analysis on anaerobic digestion systems

Author

Anacleto, Thuane Mendes, Kozlowsky-Suzuki, Betina, Björn (Fredriksson), Annika, Shakeri Yekta, Sepehr, Masuda, Laura Shizue Moriga, de Oliveira, Vinicius Peruzzi, Enrich Prast, Alex, Anacleto, Thuane Mendes, Kozlowsky-Suzuki, Betina, Björn (Fredriksson), Annika, Shakeri Yekta, Sepehr, Masuda, Laura Shizue Moriga, de Oliveira, Vinicius Peruzzi, and Enrich Prast, Alex

Abstract

Proper pretreatment of organic residues prior to anaerobic digestion (AD) can maximize global biogas production from varying sources without increasing the amount of digestate, contributing to global decarbonization goals. However, the efficiency of pretreatments applied on varying organic streams is poorly assessed. Thus, we performed a meta-analysis on AD studies to evaluate the efficiencies of pretreatments with respect to biogas production measured as methane yield. Based on 1374 observations our analysis shows that pretreatment efficiency is dependent on substrate chemical dominance. Grouping substrates by chemical composition e.g., lignocellulosic-, protein- and lipid-rich dominance helps to highlight the appropriate choice of pretreatment that supports maximum substrate degradation and more efficient conversion to biogas. Methane yield can undergo an impactful increase compared to untreated controls if proper pretreatment of substrates of a given chemical dominance is applied. Non-significant or even adverse effects on AD are, however, observed when the substrate chemical dominance is disregarded., Funding Agencies|Linkoeping University

Published

2024