Your search keyword '"corn stover"' showing total 9,118 results

1. Enhanced enzymatic hydrolysis of corn stover by γ-valerolactone pretreatment and the characteristics of enzymatic residues.

Author

Zhou, Tairan, Wang, Jiabin, Gui, Zheng, Wang, Shijie, Xie, Fang, and Luo, Hongzhen

Subjects

*CORN stover, *THERMOGRAVIMETRY, *THERMAL analysis, *DEPOLYMERIZATION, *SUGARS

Abstract

Efficient pretreatment methods are crucial for the generation of fermentable sugars from the renewable lignocellulose. In this study, γ-valerolactone (GVL), a biomass-derived green solvent, was used to fractionate corn stover (CS). The impact of different additives on the enzymatic hydrolysis and pretreatment of CS within the GVL/water system was carefully investigated. The results demonstrate that the use of H 2 SO 4 -assisted GVL/H 2 O (80:20, w/w) pretreatment at mild conditions successfully facilitates the depolymerization of CS, thereby improving the cellulase accessibility. Furthermore, by increasing the GVL pretreatment temperature to 160 °C with 100 mM H 2 SO 4 addition, the pretreated CS led to nearly 100 % of hydrolysis yield at 2 % (w/v) solid load. Finally, the thermogravimetric analysis (TGA) was performed to evaluate the thermal decomposition characteristics of untreated CS and enzymatic residues based on the H 2 SO 4 -assisted GVL/H 2 O pretreatment. The results indicate that the enzymatic residues had two depolymerization stages from 200 °C to 500 °C with a final residual mass of 22.73 %, which was higher than that of untreated CS (20.56 %). Overall, this study provides an efficient lignocellulose pretreatment for fermentable sugars production and valorization of enzymatic residues. [Display omitted] • Using H 2 SO 4 as γ-valerolactone (GVL) pretreatment additive enhanced xylan removal. • Glucose yield of GVL-pretreated corn stover (CS) was 3–5 folds higher than raw CS. • Sugars production reached 32.4 g/100 g CS by 50 mM H 2 SO 4 -assisted GVL pretreatment. • Enzymatic residues had two decomposition stages in 200–500 °C by thermal analysis. [ABSTRACT FROM AUTHOR]

Published

2024

2. Corn biomass as a feedstock for biorefinery: a bibliometric analysis of research on bioenergy, biofuel and value‐added products.

Author

Rosa, Rafael Gabriel, Ferreira, Vanessa Cosme, Barroso, Tiago Linhares Cruz Tabosa, Castro, Luiz Eduardo Nochi, and Forster‐Carneiro, Tânia

Subjects

*ALKALINE hydrolysis, *BIBLIOMETRICS, *CIRCULAR economy, *SOIL absorption & adsorption, *SOIL remediation, *CORN stover, *BIOMASS conversion

Abstract

Limited research has been dedicated to exploring the potential reuse and creation of value‐added products from corn stover. Existing gaps in current research underscore the need for waste biorefineries that adhere to the principles of a circular bioeconomy to maximize the value of corn stover. This review uses bibliometric analysis from the past decade to examine the potential and pathways for converting corn stover into energy and value‐added products within the biorefinery framework. The data were processed using the Web of Science® database and analyzed with the VosViewer® bibliometric software's, Bibliometrix package in R and Gephi, generating keyword‐based maps. A total of 2557 experimental articles and 30 reviews on corn stover research were analyzed. The bibliometric study revealed that the primary research focuses on pretreatment technologies for converting corn stover into value‐added products, bioenergy and biofuels. The main technologies employed include acid, alkaline and enzymatic hydrolysis, as well as torrefaction anaerobic digestion and steam explosion. The pretreatment processes yield sugars, xylooligosaccharides and organic acids. Additionally, the studies explored the use of corn stover biochar for soil remediation and adsorption processes. This review aims to enhance the understanding of technological pathways explored in previous research, contributing to the evaluation of sustainable processes for utilizing corn stover byproducts. Ultimately, it promotes environmentally conscious agroindustry practices that align with circular economy principles and sustainable development. [ABSTRACT FROM AUTHOR]

Published

2024

3. Scale sensitivity of ethanol production via consolidated bioprocessing with consideration of feedstock cost.

Author

Hoey, Madeline, Clark, Robin, Webb, Erin, and Lynd, Lee

Subjects

*CELLULOSIC ethanol, *CAPITAL costs, *PAYBACK periods, *PRICES, *CELLULASE, *CORN stover

Abstract

We examine feedstock cost and minimum selling price for ethanol production from corn stover as a function of scale, stover yield, participation rate, and price incentives for two conversion technologies: a conventional base case featuring thermochemical pretreatment with added cellulase, and an advanced case featuring consolidated bioprocessing with cotreatment (C‐CBP). Delivered feedstock cost ranged from $85 Mg−1 at small (10 million gallons year−1 or ~38 million L year−1) scale with high yield and participation rates to $124 Mg−1 at large scale (60 million gallons year−1 or 227 million L year−1) and low yield and participation rates. The minimum ethanol selling price (MESP) was approximately twofold lower for the advanced case compared with the base case. The payback period was several times lower for the advanced case compared with the base case, with increasing disparity at smaller scales, and was highly sensitive to ethanol price supports. For both C‐CBP and the conventional processing paradigm, MESP decreased with increasing scale, indicating that the cost penalty due to higher feedstock transport distances was more than outweighed by lower capital costs. However, the cost penalty for operation at small scale, expressed in $ gallon−1 ethanol, is lower for C‐CBP than for the conventional paradigm by roughly twofold. Particularly for initial applications of C‐CBP, we speculate that this cost penalty will likely be modest compared with the anticipated benefits of small‐scale operation such as increased opportunity to use existing infrastructure, easier plant siting and supply chain establishment, and lower total investment required. [ABSTRACT FROM AUTHOR]

Published

2024

4. Corn Stover Lignin as a Solid Acid Catalyst for the Esterification of Oleic Acid.

Author

Hamilton, Aisha, Pains Duarte, Michelle, and Naccache, Rafik

Subjects

*RENEWABLE energy sources, *HETEROGENEOUS catalysts, *EDIBLE fats & oils, *ACID catalysts, *ALTERNATIVE fuels, *CORN stover, *LIGNIN structure, *LIGNANS

Abstract

The catastrophic ramifications of fossil fuels on the environment have prompted the search for renewable energy sources. Over the recent decades, biodiesel has garnered attention as a promising direct alternative to diesel fuel; however, reliance on homogeneous catalysts and the requirement for refined vegetable oil feedstocks present financial and sustainability concerns. Thus, there exists a need for the development of sustainable and cost‐effective catalytic solutions. Herein, the application of lignin, an abundant and renewable biomass, as an effective heterogeneous catalyst is reported for biodiesel production via the esterification of oleic acid. Lignin is extracted from corn straw using sulfuric acid, which endows sulfonic acid groups (0.85 mmol g−1) to its structure allowing it to act as an acid catalyst without additional post‐treatments. Conversion of oleic oil to biodiesel is achieved at 97% using a 1:3 oleic acid to methanol molar ratio with a 5 wt.% catalyst loading at 90 °C after only 30 min. Moreover, the catalyst exhibits a remarkable turnover frequency of 2.61 min−1 proving its efficiency. These findings demonstrate that heterogeneous catalysts can be prepared from biomass waste offering a significantly cheaper and less intensive synthesis process and allowing for a paradigm shift to non‐edible and waste cooking oils. [ABSTRACT FROM AUTHOR]

Published

2024

5. The effects of applying cellulase and laccase on fermentation quality and microbial community in mixed silage containing corn stover and wet brewer’s grains.

Author

Li Li, Xiangxue Xie, Guoqiang Zhao, Jiajun He, and Yongliang Zhang

Subjects

FEED analysis, LACTIC acid bacteria, LACCASE, CELLULASE, MICROBIAL communities, MICROORGANISM populations, CORN stover, MICROBIAL inoculants

Abstract

Objective: The purpose of this experiment was to explore the effect of adding cellulase and laccase on fermentation quality and microbial community in mixed silage of corn stover and wet brewer’s grains. Try to a new approach for the proper preservation and utilization of the agro-industrial by-products (corn stover and wet brewer’s grains). Methods: The experiment was divided into four groups: CK (control), C (cellulase, 120 U/g fresh matter [FM]), L (laccase, 50 U/g FM), CL (cellulase 120 U/g FW and laccase 50 U/g FM), and the chemical composition, fermentation quality, microbial population and microbial community in mixed silage of corn stover and wet brewer’s grains after 30 day’s fermentation were determined. Results: Compared to control, the addition of cellulase significantly increased crude protein (CP), water-soluble carbohydrate (WSC), lactic acid bacteria (LAB) counts, while significantly decreased the neutral detergent fiber (NDF), acid detergent fiber (ADF) content (P < 0.05). Adding laccase significantly decreased the acid detergent lignin (ADL) content (P < 0.05). Combined application of cellulase and laccase significantly increased the CP, WSC content and LAB counts, while significantly decreased pH value, NDF, ADF and ADL content (P < 0.05), thereby improving fermentation quality. In addition, the application of cellulase and laccase increased the abundance of Firmicutes and LAB genera, and decreased microbial diversity level of the sample. Conclusion: The combined application of cellulase and laccase further improved fermentation quality and microbial community in mixed silage of corn stover and wet brewer’s grains. [ABSTRACT FROM AUTHOR]

Published

2024

6. Moulding Test and Process Parameter Optimization of Biomass Seedling Pots for Cow Dung and Corn Stover.

Author

Chen, Jiaqi, Ma, Yongcai, Wang, Hanyang, Teng, Da, Qi, Yan, and Liu, Dan

Abstract

In order to determine the optimal moulding process parameters of biomass seedling pots prepared from fermented cow dung mixed with corn stover, the moulding pressure, baking time, and baking temperature of biomass seedling pots were taken as the influencing factors, and the expansion rate, durability rate, wet swelling rate (48 h), and resistance to damage were taken as the evaluation indexes, and the Box–Behnken design of the response surface method was used to analyze the significance of interactions among the different influencing factors in the moulding process of biomass seedling pots and to optimize the moulding process. The experiment was conducted in the Biomass Laboratory of Heilongjiang Bayi Agricultural University. The response surface method Box–Behnken design was used to analyze the significance of the interaction between different influencing factors in the biomass seedling pots moulding process and optimize the moulding process. The results showed that the optimum moulding process conditions obtained using the Box–Behnken design were the following: a moulding pressure of 520.393 kN, baking temperature of 202.870 °C, and baking time of 8.573 min. The model was validated by testing and a response value of 10.522% was obtained for expansion, 99.598% for durability rate, 11.145% for wet swelling (48 h), and 4503.545 N for resistance to damage. The experimental verification showed that the deviation of the actual value obtained under this condition from the predicted value is less than 5%, indicating that the model reproduces well and meets the experimental requirements. Based on the optimal moulding process conditions determined in this experiment, the total porosity, EC, and pH of the Biomass seedling pots were determined to be 67.32%, 1.63 mS/cm, and 6.7, respectively, which met the seedling requirements. [ABSTRACT FROM AUTHOR]

Published

2024

7. Mechanical Properties and Tribological Study of Bottom Pouring Stir-Cast A356 Alloy Reinforced with Graphite Solid Lubricant Extracted from Corn Stover.

Author

Venkatesh, Vavilada Satya Swamy and Vundavilli, Pandu Ranga

Abstract

The present work epitomises extracting the graphite (Gr) solid lubricant from the corn stover. The extracted Gr was incorporated as reinforcement in the A356 alloy (Al-7Si), and the effect of the Gr particles on the mechanical and tribological properties was investigated. In spite of this, the input process parameters for the dry sliding wear test at room temperature against the EN31 steel disc were optimised through ANOVA analysis. The fabricated A359—X wt% (X = 0, 2.5, 5, 7.5) composite through bottom pouring stir casting techniques was analysed microstructurally by using XRD and FESEM analysis. The micro Brinell hardness and tensile strength were investigated per ASTME10 and ASTME8M standards. A wear test was performed for the composite pins against the EN31 steel disc according to ASTM G99 specifications. The XRD analysis results depict the presence of carbon (C), aluminium (Al), and silicon (Si) in all the wt% of the Gr reinforcement. However, along with the elements, the Al2Mg peak was confirmed for the A356—7.5 wt% Gr composite and the corresponding cluster element was confirmed in FESEM analysis. The maximum micro Brinell hardness of 92 BHN and U.T.S of 123 MPa and % elongation of 7.11 was attained at 5 wt% Gr reinforcement due to uniform Gr dispersion in the A356 alloy. Based on the ANOVA analysis, the optimal process parameters were obtained at 20 N applied load, 1 m/s sliding velocity, and 1000 m sliding distance for the optimal wear rate of 0.0052386 g/km and 0.364 COF. [ABSTRACT FROM AUTHOR]

Published

2024

8. Monitoring corn stover processing by the fungus Ustilago maydis.

Author

Robertz, Stefan, Philipp, Magnus, Schipper, Kerstin, Richter, Paul, Miebach, Katharina, Magnus, Jorgen, Pauly, Markus, and Ramírez, Vicente

Subjects

SUSTAINABILITY, CORN stover, BIOTECHNOLOGY, USTILAGO maydis, PLANT biomass, CORN

Abstract

A key aspect of sustainable bioeconomy is the recirculation of renewable, agricultural waste streams as substrates for microbial production of high-value compounds. One approach is the bioconversion of corn stover, an abundant maize crop byproduct, using the fungal maize pathogen Ustilago maydis. U. maydis is already used as a unicellular biocatalyst in the production of several industrially-relevant compounds using plant biomass hydrolysates. In this study, we demonstrate that U. maydis can grow using untreated corn stover as its sole carbon source. We developed a small-scale bioreactor platform to investigate U. maydis processing of corn stover, combining online monitoring of fungal growth and metabolic activity profiles with biochemical analyses of the pre- and post-fermentation residues. Our results reveal that U. maydis primarily utilizes soluble sugars i.e., glucose, sucrose and fructose present in corn stover, with only limited exploitation of the abundant lignocellulosic carbohydrates. Thus, we further explored the biotechnological potential of enhancing U. maydis´ lignocellulosic utilization. Additive performance improvements of up to 120 % were achieved when using a maize mutant with increased biomass digestibility, co-fermentation with a commercial cellulolytic enzyme cocktail, and exploiting engineered fungal strains expressing diverse lignocellulose-degrading enzymes. This work represents a key step towards scaling up the production of sustainable compounds from corn stover using U. maydis and provides a tool for the detailed monitoring of the fungal processing of plant biomass substrates. [ABSTRACT FROM AUTHOR]

Published

2024

9. Effects of whole-plant quinoa and corn stover mixed silage on nutrient composition, silage quality, and mycotoxin content.

Author

DING Li-qi, CUI Jian-xiao, QIU Miao, ZHANG Kai-wen, GAO Biao, LIU Jia-bin, and ZHU Feng-hua

Abstract

The experiment aimed to explore the impact of different ensiling times and methods on the nutritional components, silage quality, and mycotoxin content of whole-plant quinoa mixed with corn stover. The raw materials were 'Jinli 1' and corn stover harvested 20 cm above the ground at the milk stage, which were cut into 2~3 cm lengths. Two treatment groups was designed, including the control group (CK group), fed with whole-plant quinoa, and the test group (CS group) fed with a mixture of whole-plant quinoa to corn stover (fresh weight:dry weight ratio of 6:4). There were 12 replicates per group, and the silage for 60 days. Samples were taken at 15, 30, 45, and 60 days of ensiling to analyze fermentation parameters and nutritional components, and mycotoxin content was analyzed at 60 days. The results showed that in terms of ensiling time, compared with the 15th day of ensiling, the content of dry matter (DM), crude fat (EE), crude fiber (CF), acid detergent fiber (ADF), and pH value of the CK group and CS group on the 60th day of ensiling were all significantly reduced (P<0.05), while the content of crude protein (CP), crude ash (Ash), calcium (Ca), phosphorus (P), lactic acid (LA), acetic acid (AA), propionic acid (PA), butyric acid (BA), and the ratio of ammonia nitrogen to total nitrogen (NH3-N/TN) all significantly increased (P<0.05), the content of acid detergent lignin (ADL) in the CK group was significantly reduced (P<0.05). In terms of treatment methods, compared with the CK group, the content of DM, CF, NDF, ADL, LA, AA, and NH3-N/TN in the CS group were all significantly increased (P<0.05), while the content of CP, EE, Ash, P, PA, and pH value were all significantly reduced (P<0.05). Compared with the CK group, the content of BA in the CS group on the 30th and 45th days of ensiling was significantly increased (P<0.05), and the content of BA on the 60th day of ensiling was significantly reduced (P<0.05). On the 60th day of ensiling, compared with the CK group, the content of aflatoxin (AFB1) in the CS group was reduced, while the content of zearalenone (ZEA) and deoxynivalenol (DON) was increased, and both groups were below the feed hygiene standards. The study indicates that whole-plant quinoa alone during the milky stage and mixed with corn straw (6:4) both meet the standards for high-quality silage, but whole-plant quinoa alone during the milky stage is better than mixed with corn straw (6:4), and both can obtain high-quality silage between 45 to 60 days. [ABSTRACT FROM AUTHOR]

Published

2024

10. Effects of sunflower straw replacement of corn stover on digestive performance, lactation performance, rumen fermentation indexes, and serum biochemical indexes of dairy cows.

Author

TIAN Ying-qiao, ZHANG Xin-yu, ZHAO Yan, and ZHANG Hao

Abstract

The paper was to investigate the effects of sunflower straw replacing corn stover on the digestive performance, lactation performance, rumen fermentation indexes, and serum biochemical indexes of dairy cows. Eighty Chinese Holstein cows with no significant differences in parity, body weight, and milk yield were selected and randomly divided into four groups of 20 replicates each, with each head as a replicate. The control group was fed a basal diet, and unflower straw in the experimental groups was replaced with 20% (Group I), 50% (Group II), and 100% (Group III) corn stover in the basal diet, respectively. The experiment lasted for 100 days, including 10 days of pre-test and 90 days of formal experiment. The results showed that compared with the control group, the dry matter intake of the three experimental groups was significantly increased (P<0.05), the apparent digestibility of dry matter was significantly increased (P<0.05), the apparent digestibility of crude protein in all experimental groups was extremely increased (P<0.01). The somatic cell count in the milk of Group II was significantly reduced (P<0.05), the microbial protein content in Group III was significantly decreased (P<0.05). GroupsII and III showed a significant increase in the levels of total protein and albumin in serum at 60 and 90 days (P<0.05). The production efficiency of Group I increased by 4.51 yuan/head per day. The study shows that replacing corn stover with 20% sunflower stalks can increase dairy cows' feed intake, improve digestion and absorption of nutrients, and improve milk production and quality, with no adverse effects on the rumen environment and liver and kidney function, and with better economic benefits. [ABSTRACT FROM AUTHOR]

Published

2024

11. Investigation of the Composting Process of Mongolian Horse Manure Utilizing Intelligent Composting Equipment.

Author

Wang, Jian, Ren, Kailin, Zhang, Yong, Zhang, Longfei, and Li, Zhe

Subjects

*SUSTAINABILITY, *ORGANIC fertilizers, *ENVIRONMENTAL management, *POLLUTION, *MUNG bean, *CORN stover

Abstract

The Inner Mongolia Autonomous Region, known for its famous Mongolian horses, faces significant environmental challenges due to the large-scale rearing of these animals, which produces a substantial amount of manure. If not managed effectively, this manure can lead to severe environmental pollution. The aim of this study was to investigate whether a small-scale intelligent aeration and heating composting system is effective in treating Mongolian horse manure, with the objective of enhancing composting efficiency and resource utilization to support sustainable agricultural development in the region. The equipment was utilized to treat a compost mixture of Mongolian horse manure and corn stover, allowing for an analysis of the changes in key indicators throughout the composting process. The results demonstrated that the equipment maintained high temperatures for up to eight days during the composting process, effectively inactivating pathogens and promoting the efficient decomposition of organic matter. The system also successfully controlled humidity to 12.7% and maintained oxygen concentration within the optimal range. Post-composting analysis revealed that the final compost contained 2.3% nitrogen, 1.3% phosphorus, and 1.2% potassium, with a pH of 6.4 and conductivity of approximately 5.2 mS/cm. Additionally, the carbon-to-nitrogen ratio decreased significantly from 27.3 to 15.9, indicating substantial organic matter degradation. Seed germination tests showed germination rates of 80%, 86%, and 75% for corn, mung bean, and wheat, respectively, with a final seed germination index of 104%. This study concluded that the small aeration and heating composting equipment is highly effective in treating Mongolian horse manure, producing high-quality organic fertilizers that significantly enhance soil fertility and demonstrate considerable potential for supporting sustainable agricultural practices and improving environmental management in the Inner Mongolia Autonomous Region. [ABSTRACT FROM AUTHOR]

Published

2024

12. Feedstock variability impacts the bioconversion of sugar and lignin streams derived from corn stover by Clostridium tyrobutyricum and engineered Pseudomonas putida.

Author

Ruhl, Ilona A., Nelson, Robert S., Katahira, Rui, Kruger, Jacob S., Chen, Xiaowen, Haugen, Stefan J., Ingraham, Morgan A., Woodworth, Sean P., Alt, Hannah, Ramirez, Kelsey J., Peterson, Darren J., Ding, Ling, Laible, Philip D., Linger, Jeffrey G., and Salvachúa, Davinia

Subjects

*CORN stover, *BIOLOGICAL products, *BIOCONVERSION, *FEEDSTOCK, *CLOSTRIDIUM, *LIGNOCELLULOSE

Abstract

Feedstock variability represents a challenge in lignocellulosic biorefineries, as it can influence both lignocellulose deconstruction and microbial conversion processes for biofuels and biochemicals production. The impact of feedstock variability on microbial performance remains underexplored, and predictive tools for microbial behaviour are needed to mitigate risks in biorefinery scale‐up. Here, twelve batches of corn stover were deconstructed via deacetylation, mechanical refining, and enzymatic hydrolysis to generate lignin‐rich and sugar streams. These batches and their derived streams were characterised to identify their chemical components, and the streams were used as substrates for producing muconate and butyrate by engineered Pseudomonas putida and wildtype Clostridium tyrobutyricum, respectively. Bacterial performance (growth, product titers, yields, and productivities) differed among the batches, but no strong correlations were identified between feedstock composition and performance. To provide metabolic insights into the origin of these differences, we evaluated the effect of twenty‐three isolated chemical components on these microbes, including three components in relevant bioprocess settings in bioreactors, and we found that growth‐inhibitory concentrations were outside the ranges observed in the streams. Overall, this study generates a foundational dataset on P. putida and C. tyrobutyricum performance to enable future predictive models and underscores their resilience in effectively converting fluctuating lignocellulose‐derived streams into bioproducts. [ABSTRACT FROM AUTHOR]

Published

2024

13. Assessing the Application of Near-Infrared Spectroscopy to Determine Saccharification Efficiency of Corn Biomass.

Author

Pereira-Crespo, Sonia, Gesteiro, Noemi, López-Malvar, Ana, Gómez, Leonardo, and Santiago, Rogelio

Subjects

*NEAR infrared spectroscopy, *REGRESSION analysis, *LEAST squares, *MANUFACTURING processes, *ETHANOL as fuel, *CORN stover

Abstract

Nowadays, in the bioethanol production process, improving the simplicity and yield of cell wall saccharification procedure represent the main technical hurdles to overcome. This work evaluated the application of a rapid and cost-effective technology such as near -infrared spectroscopy (NIRS) for easily predict saccharification efficiency from corn stover biomass. Calibration process focussing on the number of samples and the genetic background of the maize inbred lines were tested; while Modified Partial Least Squares Regression (MPLS) and Multiple Linear Regression (MLR) were assessed in predictions. The predictive capacity of the NIRS models was mainly determined by the coefficient of determination (r2ev) and the index of prediction to deviation (RPDev) in external validation. Overall, we could check a better efficiency of the NIRS calibration process for saccharification using larger number of observations (1500 sample set) and genetic backgrounds; while MPLS regression provided better prediction statistics (r2ev = 0.80; RPDev = 2.21) compared to MLR (r2ev = 0.68; RPDev = 1.75). These results indicate that NIRS could be successfully implemented as a large-phenotyping tool in order to test the saccharification potential of corn biomass. Highlights: • NIRS could be successfully implemented as a large-phenotyping tool in order to test the saccharification potential of corn biomass. • NIRS wavelengths noted provide information about associated chemical components interfering in the saccharification potential. • The best efficiency in the NIRS calibration process was obtained using larger number of observations (1500 samples) and genetic backgrounds. • MPLS regression model is the most reliable for NIRS prediction of corn saccharification. [ABSTRACT FROM AUTHOR]

Published

2024

14. Evaluating the Environmental Impacts of Pretreatment and Nanoparticles in Solid-State Anaerobic Digestion Using Life Cycle Assessment.

Author

Ajayi-Banji, Ademola, Pourhashem, Ghasideh, Rahman, Shafiqur, and Feng, Xiaoyu

Subjects

*PRODUCT life cycle assessment, *CLEAN energy, *NANOPARTICLES, *ORGANIC wastes, *FOSSIL fuels, *ANAEROBIC digestion, *CORN stover, *CALCIUM hydroxide

Abstract

The yield of green energy from solid-state anaerobic co-digestion (SSAD) has recently been enhanced by incorporating innovative pretreatment methods and nanoparticles. However, the environmental consequences of employing new processes have not been fully examined. In this study, the environmental impacts of three high-methane-yielding scenarios including SSAD of corn stover blended with dairy manure (DM) denoted as (SYM1), calcium hydroxide-pretreated corn stover (CpCS) blended with DM (SYM2), and the CpCS blended with DM and nanoparticles (SYM3) were assessed and compared the baselines of solid-state and semi-solid-state anaerobic digestion using a life cycle assessment (LCA) approach. The approach investigated the best management practices that would result in high methane yield and low environmental impact. Results of the life cycle assessment indicate the inclusion of calcium hydroxide and nanoparticle has minimal negative environmental impact. There was an environmental gain in GWP when corn stover was co-digestion with DM (SYM1) relative to DM mono-digestions (baselines) and the carbon footprint of SYM1 was less by more than 85% compared to SYM2 and SYM3. However, the large volume of untreated corn stover harnessed for SYM1 scenario resulted in over 75% fossil fuel depletion compared to the other scenarios. The surplus methane from the SYM3 (at least twofold of other scenarios and baselines) in conjunction with being the least with the environmental implication makes the scenario the most attractive option for on-farm practice capable of harnessing the growing organic waste volume. These outcomes can guide trade-off between pretreatment and nanoparticle application to reduce solid-state anaerobic digestion's negative environmental impact. [ABSTRACT FROM AUTHOR]

Published

2024

15. Effect of Hemicelluloses Fractionated by Graded Ethanol Precipitation from Corn Stover on the Enzymatic Hydrolysis of Lignocellulosic Biomass.

Author

Yan, Zhanqiang, Alam, Md Asraful, Li, Jinfeng, Xiong, Wenlong, Zhang, Shen, Zhan, Zili, and Xu, Jingliang

Subjects

*CORN stover, *FOURIER transform infrared spectroscopy, *LIGNOCELLULOSE, *NUCLEAR magnetic resonance, *ION exchange chromatography, *HEMICELLULOSE

Abstract

The presence of hemicellulose inhibits the enzymatic hydrolysis of lignocellulosic biomass. The purpose of this study is to investigate the effect of different hemicellulose fractions on the enzymatic hydrolysis and the way to eliminate the inhibiting effect caused by hemicellulose. Four kinds of hemicelluloses, namely, HXF, H15, H30, and H60, were first extracted from corn stover by ethanol fractional precipitation. The structures of hemicellulose samples were analyzed using Fourier transform infrared spectroscopy, 1H and 13C nuclear magnetic resonance, and high-performance ion chromatography. The results show that H30 has the strongest inhibition on the enzymatic hydrolysis of Avicel and corn stover, presenting inhibition ratio of 13.35% and 9.98%, respectively. The inhibition ratios of other hemicelluloses in Avicel and corn stover are 8–12% and 5–9%, respectively. However, the inhibiting effect caused by H30 is removed by adding hemicellulase, which even presents a 4.99% increase in the efficiency of enzymatic hydrolysis of corn stover. The corresponding glucose concentration reached 68.11 g/L. This research could help design effective processes to promote the enzymatic hydrolysis of lignocellulosic biomass. [ABSTRACT FROM AUTHOR]

Published

2024

16. Self-Buffering Effect of Solids During High-Solid Enzymatic Hydrolysis of Lignocellulose.

Author

Shi, Xin, Wang, Lan, and Chen, Hongzhang

Subjects

*CORN stover, *DEIONIZATION of water, *BIOCHEMICAL substrates, *BIOLOGICAL products, *SURFACE area, *LIGNINS, *BETA-glucans, *LIGNOCELLULOSE

Abstract

The role of buffer in modulating the enzymatic hydrolysis environment of lignocellulose is crucial. However, studies on the impact of buffer on high-solid enzymatic hydrolysis remain limited. This study discovered that utilizing deionized water as a reaction medium, rather than the conventional buffer, did not influence the enzymatic hydrolysis of steam-exploded corn stover when the solid loading ranged between 15 and 25%. At 15% solid loading, the glucan conversion in the group treated with buffer was recorded at 89.8%, with a corresponding glucose concentration of 51.1 g/L. In contrast, the group without buffer exhibited a conversion of 88.9% and a glucose concentration of 50.5 g/L. The increase of acid groups in lignin was attributed to the formation of phenolic hydroxyls during steam explosion, which provided the substrate with the necessary conditions for buffering effects. Sequentially, during the high-solid enzymatic hydrolysis process, the substrate's increased pore volume and specific surface area could potentially offset the buffering capacity, which led to the buffering effect becoming ineffective. Leveraging the self-buffering effect of the substrate, a fed-batch strategy was developed. This strategy replaced the water supplementation with buffers, augmenting the solid loading from 20 to 33% across six distinct feeding sessions over a span of 72 h. This not only reduced costs but also laid the foundation for the industrial viability of lignocellulosic high-concentration sugar production, thereby advancing the biofuels and bioproducts sector. These findings provide valuable insights for the exploration of solid reaction processes. [ABSTRACT FROM AUTHOR]

Published

2024

17. Bioethanol Production from Alkali-Treated Corn Stover via Acidic Adjustment by Furfural Residue.

Author

Zhang, Mengxuan, Liu, Yunyun, Li, Wentao, Wang, Wen, Liang, Cuiyi, Zhang, Yu, Jia, Bao, and Qi, Wei

Subjects

*CORN stover, *SOLID waste, *ETHANOL as fuel, *INDUSTRIAL costs, *BIOCONVERSION

Abstract

The unwashed alkali-treated lignocellulose can be directly enzymatically hydrolyzed and fermented via pH adjustment with acids. The use of acids would give a burden on production cost. Furfural residue (FR) which is the acidic solid waste from lignocellulose-derived furfural production process was employed in this study as a pH regulator. The corn cob-derived FR was used to adjust the pH value of alkali-treated corn stover (PCS) to 4.8 for enzymatic hydrolysis and ethanol fermentation. The unwashed PCS adjusted by FR got higher enzymatic hydrolysis efficiency (EHE) than the washed PCS samples. Meanwhile, the mixing of PCS and FR had a synergistic effect on the EHE of PCS. The fermentation of enzymatic hydrolysate from unwashed PCS-FR mixture at 20% solid concentration could attain ethanol production of 26.54 ± 0.02 mg/mL with a yield of 89.53 ± 0.08%. This work created a novel recycling way of FR as a pH regulator for improving the bioconversion of alkali-treated lignocellulose. It also provided a novel clue for the valuable valorization of wastes from corn production. [ABSTRACT FROM AUTHOR]

Published

2024

18. Influence of Cellulose and Lignin-Rich Biomass on Catalyst Performance: A Study with Walnut Shell and Corn Stover Gasification.

Author

Soomro, Ahsanullah, Chen, Shiyi, Mallah, Mahdi Hassan, Samo, Imran Ahmed, Siyal, Asif Ali, Ali, Babar, Samo, Kamran Ahmed, Ma, Shiwei, Mukwana, Kishan Chand, and Xiang, Wenguo

Subjects

*BIOMASS chemicals, *BIOMASS gasification, *COKE (Coal product), *X-ray diffraction, *SYNTHESIS gas, *CORN stover

Abstract

This study investigates the gasification of cellulose, lignin, corn stover (rich in cellulose) and walnut shells (rich in lignin) using CaO as a catalyst. The objective was to understand the effect of the different biomass components on the gasification products and the performance of the CaO catalyst. Notable results indicate distinctive product distribution: cellulose yields higher liquid (58%) and CO (95.36%) products, while lignin produces increased H2 (47.88%), CH4 (34.34%), and CO2 (29.58%). Gasification of biomass feedstocks, corn stover (cellulose-rich) and walnut shell (lignin-rich), aligns with pure cellulose and lignin trends. Catalyst characterization highlights that cellulose exhibits a greater tendency for coke formation, leading to elevated tar compounds and coke deposition on the catalyst surface. The solid residue from cellulose gasification displays a smaller pore volume (5.70 m2/g) and specific surface area, indicating undesirable catalyst rearrangement. XRD analysis indicates a higher carbonation rate of CaO in lignin-rich gasification, leading to increased CaCO3 formation. Further results show a higher CO2 concentration (3.35 mol/kg) and lower CO production (0.54 mol/kg) in corn stover gasification, contrasting with walnut shell (CO2: 14.24 mol/kg, CO: 1.24 mol/kg). The study underscores the quantitative assessment of biomass composition for optimizing gasification processes, vital for catalyst selection and ensuring efficient CO2 capture in industrial applications. [ABSTRACT FROM AUTHOR]

Published

2024

19. Innovative Pavement Materials: Utilizing Corn Stover and Fly Ash in Geopolymers.

Author

Paneru, Anu, Sagar, Viral, Tarikuzzaman, Mohammad, Lynam, Joan G., Gordon II, Stephen T., and Alam, Shaurav

Subjects

CORN stover, FLY ash, ASPHALT concrete, ROAD construction, COMPRESSIVE strength, POLYMER-impregnated concrete

Abstract

The development of each nation is evaluated by its infrastructure, and each nation is competing with the others in infrastructure advancement, especially in the construction of roadways, since they play a vital role in the economic and social development of the nation. The conventional materials used for road construction are concrete and asphalt, which pose significant environmental challenges. This research gives insight into the potential of fly ash (FA) and corn stover (CS) in synthesizing geopolymer, as an alternative material for the construction of roads. This study examines the impact of three FA and CS mixture percentages and the particle size of CS on the compressive strength and porosity of geopolymer. The results indicate that incorporating larger amounts of CS in fly ash-based geopolymer may decrease the compressive strength of the geopolymer. Smaller CS particle sizes also tend to lead to lower compressive strength. Porosity of the geopolymer tended to increase with the incorporation of higher percentages of CS, particularly for smaller corn stover sizes. As a fine aggregate replacement for geopolymer, CS incorporation has the potential to reduce mined aggregate obtained from a process that harms the environment. [ABSTRACT FROM AUTHOR]

Published

2024

20. Monitoring corn stover processing by the fungus Ustilago maydis

Author

Stefan Robertz, Magnus Philipp, Kerstin Schipper, Paul Richter, Katharina Miebach, Jorgen Magnus, Markus Pauly, and Vicente Ramírez

Subjects

Lignocellulose utilization, Corn stover, Ustilago maydis, Bioconversion, Online monitoring, Technology, Chemical technology, TP1-1185, Biotechnology, TP248.13-248.65

Abstract

Abstract A key aspect of sustainable bioeconomy is the recirculation of renewable, agricultural waste streams as substrates for microbial production of high-value compounds. One approach is the bioconversion of corn stover, an abundant maize crop byproduct, using the fungal maize pathogen Ustilago maydis. U. maydis is already used as a unicellular biocatalyst in the production of several industrially-relevant compounds using plant biomass hydrolysates. In this study, we demonstrate that U. maydis can grow using untreated corn stover as its sole carbon source. We developed a small-scale bioreactor platform to investigate U. maydis processing of corn stover, combining online monitoring of fungal growth and metabolic activity profiles with biochemical analyses of the pre- and post-fermentation residues. Our results reveal that U. maydis primarily utilizes soluble sugars i.e., glucose, sucrose and fructose present in corn stover, with only limited exploitation of the abundant lignocellulosic carbohydrates. Thus, we further explored the biotechnological potential of enhancing U. maydis´ lignocellulosic utilization. Additive performance improvements of up to 120 % were achieved when using a maize mutant with increased biomass digestibility, co-fermentation with a commercial cellulolytic enzyme cocktail, and exploiting engineered fungal strains expressing diverse lignocellulose-degrading enzymes. This work represents a key step towards scaling up the production of sustainable compounds from corn stover using U. maydis and provides a tool for the detailed monitoring of the fungal processing of plant biomass substrates. Graphical abstract

Published

2024

21. Simulation of a 1MWth biomass chemical looping gasification process based on kinetic and pyrolysis models.

Author

Dai, Mingyang, Guo, Tuo, Hu, Xiude, Ma, Jingjing, and Guo, Qingjie

Subjects

*BURNUP (Nuclear chemistry), *ENERGY consumption, *NUCLEAR fuels, *BIOMASS chemicals, *COLD gases, *CORN stover, *BIOMASS conversion

Abstract

In this research, based on kinetic and pyrolysis modelling, a model of 1-MW th biomass chemical looping gasification (BCLG) was prepared using the Aspen Plus process simulation software; the involved biomass feedstock was corn stover. The model reliability was verified using experimental data, and the energy and exergy performances of the modeled BCLG were analyzed in detail. Further, thermodynamic modelling was compared with kinetic modelling to determine the fuel utilization efficiency. In addition, the effects of operating conditions such as the gasification temperature, oxygen/carbon (O/C) ratio, and water/carbon (H 2 O/C) ratio on the modeled BCLG were investigated under steady-state conditions. Results revealed that the involved H 2 /CO ratio, syngas yield, and cold-gas efficiency were optimal at a gasification temperature of 850 °C, an O/C ratio of 0.45, and an H 2 O/C ratio of 0.6. Moreover, the heat output power and heat efficiency were 15.42% and 60.99%, respectively. In addition, the involved exergy destruction was found to primarily result from the fuel reactor (50.29%), with the total exergy destruction being 54.59%. The product exergy efficiency and total exergy efficiency of the model were 91.40% and 41.64%, respectively. Overall, this research aims to guide the stable operation of the demonstration plant as well as offer theoretical support and data accumulation for industrialized BCLG application. [Display omitted] • Biomass chemical looping gasification was modeled using kinetic and pyrolysis modelling. • Identified optimal operational conditions for maximizing syngas yield and cold gas efficiency. • The system heat efficiency of the kinetic model is increased by 22.27%. • Kinetic modelling has higher product exergy efficiency and total exergy efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

22. Characterization of a novel cellobiose phosphorylase with broad optimal pH range from a tailings pond macrogenomic library.

Author

Gao, Yushan, Ran, Xiaoqin, Chen, Tingting, Wang, Zancheng, Fan, Junping, Liu, Lulu, and Li, Yonghao

Subjects

*AMINO acid residues, *CORN stover, *INDUSTRIAL capacity, *CELLOBIOSE, *THERMAL stability, *CELLULASE

Abstract

AbstractGlucose-1-phosphate, a crucial pharmaceutical intermediate, can be generated through the synergistic transformation of lignocellulose using cellulase and cellobiose phosphorylase (CBP), thus holding promise for a profitable biorefinery process. However, the reported optimal pH range of CBPs (6.0–7.5) does not align with that of cellulase (4.8), resulting in suboptimal efficiency in the one-pot conversion of cellulose to glucose-1-phosphate. In this study, we identified a novel cellobiose phosphorylase, CBP1942, comprising 811 amino acid residues (92.5 kDa), in tailing pond macrogenomes, exhibiting identity of 60% to 75% with reported CBPs. CBP1942 was efficiently expressed in E. coli BL21 and purified with His tagging. It maintains over 90% enzyme activity across pH 4–9. Compared to the benchmark CtCBP (GenBank ID: AAL67138.1), CBP1942 displays a 1.2-fold increase in specific enzyme activity at the optimal cellulase temperature (50 °C), indicating its superior suitability for cellulase compounding. CBP1942 exhibits Km and kcat values of 6.69 mM and 8.83 s−1, respectively, with a kcat/Km ratio 6.6 times higher than CtCBP, suggesting superior catalytic efficiency. Notably, CBP1942 shows remarkable thermal stability, retaining 94.67% enzyme activity after 3 h at 50 °C, while CtCBP retains only 78.33%. Additionally, CBP1942 complexed with cellulase enhances the conversion of corn stover, resulting in a 6.2-fold increase in glucose-1-phosphate yield compared to CtCBP. These findings indicate CBP1942’s potential as an industrial enzyme for corn stover conversion to glucose-1-phosphate. [ABSTRACT FROM AUTHOR]

Published

2024

23. Microwave-assisted catalytic gasification of mixed plastics and corn stover for low tar, hydrogen-rich syngas production.

Author

Abedin, Ashraf, Bai, Xinwei, and Muley, Pranjali

Subjects

*BIOMASS gasification, *SYNTHESIS gas, *TAR, *CORN stover, *MICROWAVE heating, *REACTIVE oxygen species, *PLASTICS, *CORN harvesting

Abstract

The challenge for efficient management of post-consumer plastic and biomass waste has grown over the past few decades due to their dramatic increases. In comparison to conventional gasification, microwave-assisted co-gasification of plastics and corn stover offers many benefits, including increased H 2 yield and gas components compared to unfavorable char/tar. Nonetheless, for future commercialization of the process and ease of product separation, further reduction of the undesirable tar is necessary, which can be achieved over the catalytic route. In this work, we studied the catalytic effect of magnetite for microwave-assisted co-gasification of corn stover and plastic to make syngas with higher H 2 and lower tar selectivity over non-catalytic conditions. A 1:1:1 ratio of plastic-corn stover-magnetite was used to evaluate the reaction parameters such as temperature, space velocity, heating media, and catalytic cycles under gasification conditions. In comparison with the microwave non-catalytic route, a 100% increase in the total H 2 yield with 76% higher H 2 production efficiency (mmol/kWh) was achieved in the presence of the magnetite catalyst, while reducing the overall tar formation from 9% to 2%. When magnetite was reduced in situ during the reaction, it coupled with microwave and delivered oxygen radicals that cracked down plastic and corn stover intermediates generated from the synergistic effect under microwave heating. Soon after the oxygen transfer process initiated, magnetite reached its final oxidation state consisting of microwave-active Fe and Fe 3 C phases that continued coupling with microwaves along with the generated graphitic carbon to maintain the heat necessary to further reduce the generated tar and make additional gaseous products, as confirmed by XRD, Raman, and TGA analyses. [Display omitted] • Catalytic co-gasification of waste feedstock was demonstrated using microwave energy for production of clean hydrogen • Catalyst and microwave synergy doubled the H 2 production compared to non-catalytic reaction with 76% higher H 2 production efficiency (mmol/kWh) • Catalytic gasification reduced the tar yields from 9% from non-catalytic reactions to 2% • Magnetite delivered oxygen radicals that cracked down plastic and corn Stover intermediates • Synergy between microwaves and catalyst + feedstock resulted in H 2 -rich syngas with reduced tars [ABSTRACT FROM AUTHOR]

Published

2024

24. Synthesis of carbon dots from corn stover and their application in quercetin detection.

Author

Wang, Jing, Han, Dan, and Yan, Zihong

Subjects

*FLUORESCENCE yield, *CORN stover, *QUERCETIN, *FLUORESCENCE quenching, *SMALL molecules, *FLUORESCENT probes, *CARBON

Abstract

In this work, carbon dots with green fluorescence were prepared by one-step hydrothermal reaction using corn stover as a carbon source. The carbon dots prepared under the optimal synthesis conditions had a spherical morphology with an average particle size of 2.07 ± 0.48 nm, and their fluorescence quantum yield reached 37.4%. The effects of various metal ions and organic small molecules on the fluorescence intensity of carbon dots were tested. The results showed that only quercetin caused a strong fluorescence quench of carbon dots, which were constructed as highly selective quercetin fluorescent probes based on the inner filter effect and the static quenching effect. The carbon dots quenched by quercetin exhibited high sensitivity for a fluorescence quench process, the quercetin concentration and the difference in fluorescence intensity of carbon dots (F0/F) showed linear relationship between two variables. For low the quercetin concentration was 10 ∼ 100 µmol·L−1, the standard curve was F0/F = 0.0078X + 1.08 (R2=0.9943); while the quercetin concentration was 100 ∼ 200 µmol·L−1, the standard curve was F0/F = 0.015X + 0.341 (R2=0.9937), and its limit of detection was 6.41 µmol·L−1. [ABSTRACT FROM AUTHOR]

Published

2024

25. Impacts of Various Calcium Concentrations on the Biochemical Characteristics of Corn (Zea mays L.) Seedlings in Drought Conditions.

Author

Kabay, Turgay, Oral, Erol, Eryiğit, Tamer, and Altuner, Fevzi

Subjects

*DROUGHTS, *CORN quality, *CORN seedlings, *SUPEROXIDE dismutase, *CALCIUM, *CORN, *CORN stover

Abstract

In recent years, there has been a significant decrease in corn production and quality due to drought. Ca applications are thought to be effective in eliminating this negative effect of drought. The research was conducted in a climatic chamber using a completely randomized experimental design. Four Ca doses were used in this study as research factors. In the study, increases in malondialdehyde, catalase activity, and superoxide dismutase levels, as well as leaf proportional water content, membrane damage index, Ca, and potassium contents, were examined. As a result of the research; leaf proportional water content was 55.633–72.103%, membrane damage index 44.540–71.643%, K content 1.967–2.733%, Ca content 0.243–0.497%, malondialdehyde activity 0.090–0.114 nmol g−1 FW, catalase activity 0.015–0.043 nmol g−1 FW and superoxide dismutase varied between 0.011 and 0.027 unit g−1 FW. Drought stress has negative effects on yield and quality properties in crop production. It has been determined that these negative impacts vary depending on the genetic structure of the plants as well as the presence of regulatory elements such as Ca. In this research, it was determined that Ca fertilization under drought stress caused a decrease in K content and some enzymatic activities such as MDI, MDA, CAT, and SOD, and an increase in LWC and Ca contents in corn seedlings. As a result, it is concluded that the applied Ca doses reduced the negative effects of drought. In conclusion, the 400 mg L−1 Ca application is recommended for reducing the negative effects of drought stress. [ABSTRACT FROM AUTHOR]

Published

2024

26. Effect of enzymatic hydrolysis of arabinoxylan on the quality of frozen dough during the subfreezing process.

Author

Zhu, Nannan, Liu, Yufen, Zhang, Xing, Gao, Haiyan, Zeng, Jie, Yang, Junjie, Song, Jianguo, Li, Xinjian, and Zhao, Tianxiang

Subjects

*THAWING, *DOUGH, *WHEAT bran, *CORN stover, *HYDROLYSIS, *XYLANASES, *QUALITY control

Abstract

BACKGROUND: The objective of this investigation was to examine the impact of enzymatic hydrolysis of arabinoxylan (AX) on frozen dough quality under subfreezing conditions. The dough was subjected to freezing at −40 °C for 2 h and then stored at −9, −12, and −18 °C for 15 days. The water loss, freezable water content, water migration, and microstructure of the dough were measured. RESULTS: The dough containing 0.8% cellulase enzymatically hydrolyzed AX (CAX) required the shortest duration when traversing the maximum ice‐crystal formation zone (6.5 min). The dough with xylanase enzymatically hydrolyzed AX (XAX) demonstrated a faster freezing rate than the dough with CAX. The inclusion of both XAX and CAX in the dough resulted in the lowest freezable water loss and reduced freezable water content and free‐water content levels, whereas the inclusion of xylanase‐cellulase combined with enzymatically hydrolyzed AX resulted in higher free‐water content levels. The textural properties of the subfreezing temperature dough were not significantly different from the dough stored at −18 °C and sometimes even approached or surpassed the quality observed in the control group rather than the dough stored at −18 °C. In addition, the gluten network structure remains well preserved in XAX‐ and CAX‐containing doughs with minimal starch damage. CONCLUSION: The enzymatic hydrolysis of AX from wheat bran can be used as a useful additive to improve the quality of frozen dough. © 2024 Society of Chemical Industry. [ABSTRACT FROM AUTHOR]

Published

2024

27. Low-Temperature Plasma Modification of Lignin-Derived Carbon Solid Acid Catalyst for Catalytic Production of 5-HMF.

Author

Lv, Shijun, Deng, Xiaoya, Zhu, Peiwen, Ruan, Lingyu, Tao, Yuheng, Wang, Liqun, Zhu, Jie, and Qing, Qing

Subjects

*ACID catalysts, *NON-thermal plasmas, *SULFUR acids, *DIMETHYL sulfoxide, *SULFUR dioxide, *CORN stover

Abstract

Sulfonated carbon catalysts exhibit superior catalytic performance for production of biobased chemicals, but the catalyst preparation approaches are still suffered from high corrosion and possible pollution risks. In this paper, lignin extracted from corn stover was used to prepare lignin-based activated carbon, which was then subjected to grafting modification by sulfur dioxide nonthermal plasma method to construct a novel lignin-derived solid acid catalyst (LP-LDSA). The catalytic performances of LP-LDSA were further determined by dehydration of fructose to produce 5-HMF in a biphasic solvent system composed by dimethyl sulfoxide (DMSO) and water. Under the optimal conditions, the 5-HMF yield and reaction selectivity were 88.9% and 89.4%, respectively. This LP-LDSA catalyst also exhibited excellent stability and reusability in five sequential reaction batches. This method has advantages of shorter solid acid preparation duration, lower energy consumption, and higher catalytic stability, presenting an innovative and green method for sulfonation production of solid acid catalyst. [ABSTRACT FROM AUTHOR]

Published

2024

28. Conversion of Corn Stover for Microbial Enzymes Production by Phanerochaete chrysosporium.

Author

Kukreti, Neha, Kumar, Pravir, and Kataria, Rashmi

Abstract

Phanerochaete chrysosporium, a white rot fungus, exhibits remarkable capabilities in producing various extracellular enzymes. These microbial enzymes find extensive applications in disrupting the intricate structure of plant cell walls, decolorizing synthetic dyes, and facilitating pulp extraction, among other functions. The process of solid-state fermentation stands out as an economical and sustainable approach, ideal for achieving high yields in enzyme production using lignocellulosic biomass as a substrate. In this research paper, both untreated and alkali pretreated corn stover materials served as substrates for enzyme production, leveraging the fungal strain's capacity to generate enzymes like cellulases and manganese peroxidase. The maximum production of endoglucanase was notably observed, reaching 121.21 ± 0.90 U/gds on the 9th day for untreated biomass and 79.75 ± 0.57 U/gds on the 6th day for treated biomass. Similarly, the peak exoglucanase production was recorded at 2.46 ± 0.008 FPU/ml on the 3rd day for untreated biomass and 0.92 ± 0.002 FPU/ml on the 6th day for treated biomass. Furthermore, the highest production of manganese peroxidase was achieved, with values of 5076.81 U/l on the 6th day for untreated biomass and 1127.58 ± 0.23 U/l on the 3rd day for treated biomass. These results collectively emphasize the potential of corn stover as a renewable and promising substrate for the production of essential enzymes. [ABSTRACT FROM AUTHOR]

Published

2024

29. Studying microbial triglyceride production from corn stover saccharides unveils insights into the galactose metabolism of Ustilago maydis.

Author

Richter, Paul, Panchalingam, Jathurshan, Miebach, Katharina, Schipper, Kerstin, Feldbrügge, Michael, and Mann, Marcel

Subjects

*CORN stover, *USTILAGO maydis, *SACCHARIDES, *GALACTOSE, *SUSTAINABILITY, *TRIGLYCERIDES

Abstract

The global demand for plant oil has reached unprecedented levels and is relevant in all industrial sectors. Driven by the growing awareness for environmental issues of traditional plant oils and the need for eco-friendly alternatives, microbial oil emerges as a promising product with significant potential. Harnessing the capabilities of oleaginous microorganisms is an innovative approach for achieving sustainable oil production. To increase economic feasibility, it is crucial to explore feedstocks such as agricultural waste streams as renewable resource for microbial bioprocesses. The fungal model Ustilago maydis is one promising organism in the field of microbial triglyceride production. It has the ability to metabolize a wide variety of carbon sources for cell growth and accumulates high amounts of triglycerides intracellularly. In this study we asked whether this large variety of usable carbon sources can also be utilized for triglyceride production, using corn stover saccharides as a showcase. Our experiments revealed metabolization of the major saccharide building blocks present in corn stover, demonstrating the remarkable potential of U. maydis. The microorganism exhibited the capacity to synthesize triglycerides using the saccharides glucose, fructose, sucrose, xylose, arabinose, and galactose as carbon source. Notably, while galactose has been formerly considered as toxic to U. maydis, we found that the fungus can metabolize this saccharide, albeit with an extended lag phase of around 100 hours. We identified two distinct methods to significantly reduce or even prevent this lag phase, challenging previous assumptions and expanding the understanding of U. maydis metabolism. Our findings suggest that the two tested methods can prevent long lag phases on feedstocks with high galactose content and that U. maydis can produce microbial triglycerides very efficiently on many different carbon sources. Looking forward, exploring the metabolic capabilities of U. maydis on additional polymeric components of corn stover and beyond holds promise for innovative applications, marking a significant step toward environmentally sustainable bioprocessing technologies. [ABSTRACT FROM AUTHOR]

Published

2024

30. Study on the Effect of Magnesium Chloride-Modified Straw Waste Biochar on Acidic Soil Properties.

Author

Liu, Zhigao, Dai, Yuhang, Wen, Tianyi, Wei, Penglian, Fu, Yunlin, and Qiao, Mengji

Subjects

*GREENHOUSE gas mitigation, *CORN straw, *TILLAGE, *ACID soils, *BIOCHAR, *CORN stover

Abstract

Soil biochar is a kind of organic matter rich in carbon, which is of great significance in soil fertility improvement, fertilizer type innovation and greenhouse gas emission reduction. In this paper, Mg-modified biochar was prepared by thermal cracking using rice straw and corn straw as raw materials. The Mg-modified biochar and unmodified biochar were fully mixed with prepared soil samples at the addition amounts of 0.5% (w/w), 1% (w/w) and 2% (w/w), respectively, and then simulated indoor soil cultivation experiments were carried out. The effects of magnesium ion-modified biochar and non-modified biochar on soil chemical properties and the effects of different amounts of biochar on soil properties were studied. The results showed that the yield of Mg-modified biochar from rice straw and corn straw, prepared by pyrolysis, was 65%, and the ash content was large. The pH of MG-modified corn stalk biochar (MCBC) is weakly basic (8.55), while the pH of MG-modified rice stalk biochar (MRBC) is basic (10.1), and their internal structures are slightly different. After the application of biochar prepared from rice straw and maize stover, soil indicators were determined. Compared to the control, the chemical properties of the treated soil samples were significantly improved, with an increase in soil pH, an increase in the content of effective nutrients, such as fast-acting potassium, fast-acting phosphorus and alkaline dissolved nitrogen, and an increase in the content of the total phosphorus and total nitrogen, as well as an increase in the content of organic matter. The Mg-modified biochar was generally superior to the unmodified biochar in improving soil fertility, at the same addition level. It was also found that the rice-straw biochar performed better than the corn-stover biochar and had a more obvious effect on soil improvement in terms of fast-acting potassium, ammonium nitrogen, nitrate nitrogen, total phosphorus and total nitrogen contents. [ABSTRACT FROM AUTHOR]

Published

2024

31. Iron Active Center Coordination Reconstruction in Iron Carbide Modified on Porous Carbon for Superior Overall Water Splitting.

Author

Guo, Wenxin, Li, Jinlong, Chai, Dong‐Feng, Guo, Dongxuan, Sui, Guozhe, Li, Yue, Luo, Dan, and Tan, Lichao

Subjects

*CEMENTITE, *LIQUID nitrogen, *IRON, *HYDROGEN evolution reactions, *OXYGEN evolution reactions, *CLEAN energy, *DENSITY functional theory, *CORN stover, *DEIONIZATION of water

Abstract

In this work, a novel liquid nitrogen quenching strategy is engineered to fulfill iron active center coordination reconstruction within iron carbide (Fe3C) modified on biomass‐derived nitrogen‐doped porous carbon (NC) for initiating rapid hydrogen and oxygen evolution, where the chrysanthemum tea (elm seeds, corn leaves, and shaddock peel, etc.) is treated as biomass carbon source within Fe3C and NC. Moreover, the original thermodynamic stability is changed through the corresponding force generated by liquid nitrogen quenching and the phase transformation is induced with rich carbon vacancies with the increasing instantaneous temperature drop amplitude. Noteworthy, the optimizing intermediate absorption/desorption is achieved by new phases, Fe coordination, and carbon vacancies. The Fe3C/NC‐550 (550 refers to quenching temperature) demonstrates outstanding overpotential for hydrogen evolution reaction (26.3 mV at −10 mA cm−2) and oxygen evolution reaction (281.4 mV at 10 mA cm−2), favorable overall water splitting activity (1.57 V at 10 mA cm−2). Density functional theory (DFT) calculations further confirm that liquid nitrogen quenching treatment can enhance the intrinsic electrocatalytic activity efficiently by optimizing the adsorption free energy of reaction intermediates. Overall, the above results authenticate that liquid nitrogen quenching strategy open up new possibilities for obtaining highly active electrocatalysts for the new generation of green energy conversion systems. [ABSTRACT FROM AUTHOR]

Published

2024

32. Optimization of Mixed Microbes Pretreatment on Corn Straw for Enhancing Methane Production.

Author

Shilin Yang, Yixiang Qin, Panpan Li, Chao He, Pengfei Li, Tingting Hou, Gang Li, Guizhuan Xu, and Youzhou Jiao

Subjects

*CORN straw, *STRAW, *METHANE, *MICROORGANISMS, *FERMENTATION, *CORN stover, *ANAEROBIC digestion

Abstract

In order to efficiently utilize straw biomass resources, the mixed microbes were used to pretreat corn straw and anaerobic fermentation was carried out. The effects of the straw particle size, the solid-liquid ratio, and the initial pH value on both the pretreatment process and the anaerobic digestion were investigated. On the basis of single factor experiments, the pretreatment conditions were optimized using the response surface method. The pretreatment was conducted at a temperature of 30 ℃ for a duration of 15 days. The results indicated that the optimal parameters in pretreatment process were as follows: a straw particle size of 20 mesh, a solid-liquid ratio of 1:17, and an initial pH value of 6.5. The predicted cumulative methane production under these conditions was 3740 mL, while the experimental result obtained was (3805 ± 67) mL. With a relative deviation of 1.68% between the predicted and experimental values, the model optimized the pretreatment conditions and improved the prediction of cumulative methane production. The methane yield of corn straw achieved 243 mL/(g-VSadded). [ABSTRACT FROM AUTHOR]

Published

2024

33. Residual Effect of Wheat Varieties and Integrated Nutrient Management on Productivity and Profitability of Green Gram under North Gujarat Agro-climatic Condition.

Author

Kantwa, C. R., Vyas, K. G., Patel, Sweta A., and Patel, B. J.

Subjects

*WHEAT, *AGRICULTURAL colleges, *SUSTAINABLE development, *SEED yield, *NUTRIENT uptake, *CORN stover

Abstract

Background: A field experiment was conducted during two consecutive summer seasons of 2016-17 and 2017-18 at Sardarkrushinagar Dantiwada Agricultural University, Sardarkrushinagar, Gujarat to assess the residual effect of wheat varieties and integrated nutrient management on growth, yield, economics and quality of green gram (Vigna radiata L.). The soil of the experimental plot was loamy sand in texture, low in organic carbon (0.24%), available nitrogen (159 kg/ha) and Zn (0.41 mg/kg), medium in available phosphorus (38.90 kg/ha) and high in available potash (287 kg/ha). Methods: During the period 2016-17 to 2017-18 the experiment was laid out in a Factorial RBD with three replications, consisted of four varieties GW 273 (V1 ), GW 322 (V2 ), GW 451 (V3 ) and GW 496 (V4 ) and six integrated nutrient management control (N1 ), 100% RDF (N2 ), 100% RDF + Azotobacter + PSB (N3 ), 75% RDF + Azotobacter + PSB (N4 ), 75% RDF + Azotobacter + PSB + ZnSO4 (N5 ) and 50% RDF + 25% N through FYM + Azotobacter + PSB + ZnSO4 (N6 ). Result: The pooled results indicated that among the residual effect of nutrient management practices, application of 50% RDF (RDF; 120:60:00 kg NPK/ha) + 25% N through FYM + Azotobacter + PSB + ZnSO4 significantly improved growth parameters, yield attributes, seed yield (669 kg/ha) and stover yield (1406 kg/ha) over control and gained the highest net return (`18538/ha) and benefit: cost ratio of 0.88. [ABSTRACT FROM AUTHOR]

Published

2024

34. Effects of Defatting Pretreatment on Polysaccharide Extraction from Rambutan Seeds Using Subcritical Water: Optimization Using the Desirability Approach.

Author

Nilmat, Kamonthip, Hunsub, Panusorn, Ngamprasertsith, Somkiat, Sakdasri, Winatta, Karnchanatat, Aphichart, and Sawangkeaw, Ruengwit

Subjects

CORN stover, WATER use, SEEDS, SUPERCRITICAL fluid extraction, GALACTOMANNANS, POLYSACCHARIDES

Abstract

Rambutan seeds are by-products generated from fruit-processing factories; the leftover seeds are buried in landfills, generating methane emissions. This work aimed to extract polysaccharides (POLS) from rambutan seeds by using subcritical water extraction (SWE). The effects of defatting pretreatment and operating parameters in SWE were investigated using a Box–Behnken design. The results show that defatting pretreatment significantly enriched the POLS yield, while it had no significant effect on the total sugar content. Using the desirability approach, the suitable feedstock for SWE was defatted rambutan seeds. The maximum desirability of 0.86 was found at a temperature range of 145–150 °C, an extraction time of 15 min, and a liquid–solid ratio of 10:1. The POLS yield and total sugar content were in the range of 52.33–55.63 g/100 g feedstock and 83.37–87.45 g/100 g POLS, respectively. The extracted POLS had an equivalent molecular weight of 413.70 kDa that could be used as an extender in plant-based products. In conclusion, the defatting pretreatment of rambutan seeds not only improved the POLS yield obtained via SWE but also generated additional lipids that could be utilized as an unconventional source of specialty fat. [ABSTRACT FROM AUTHOR]

Published

2024

35. The Adsorption Characteristics of Phosphorus-Modified Corn Stover Biochar on Lead and Cadmium.

Author

Zhou, Lina, Chen, Lin, Zhang, Yuqing, Zhang, Yu, Li, Zhifan, Yang, Kun, and Chen, Limei

Subjects

ADSORPTION (Chemistry), LEAD, CORN stover, METALLIC composites, POTASSIUM phosphates

Abstract

In order to achieve the purpose of efficiently removing lead and cadmium as the main heavy metals from wastewater, this paper explores the adsorption properties of cadmium ions and lead ions on biochar under different modified conditions prepared from corn stalks as raw materials and potassium phosphate as surface modifiers. Before preparing biochar (BC), the mass ratios of 1:1 and 1:2 (corn stalks to potassium phosphate) were used for pre-modification, and the oxygen-restricted pyrolysis processes of 350 °C, 550 °C and 750 °C were used for treatment. The study discussed the individual and composite adsorption effects of biochar on Pb2+ and Cd2+ under different conditions. The experimental results show that phosphorus modification has changed the physical and chemical properties of the original biochar. Among them, the biochar (2PBC550) with an impregnation ratio of 1:2 and a pyrolysis temperature of 550 °C (2PBC550) exhibits excellent adsorption properties. When the pH of the simulated wastewater is 5 and the amount of adsorbent is 30 mg·L−1, the maximum adsorption capacity of Pb2+ and Cd2+ is 145.48 mg·g−1 and 14.533 mg·g−1, respectively, which are 6.46 times and 3.67 times of the original biochar. The Pb2+ and Cd2+ adsorption data of 2PBC550 fit well with the quasi-secondary dynamics and Langmuir isothermal models, indicating that the adsorption process is controlled by single-layer chemical adsorption. In the composite metal system of Pb2+ and Cd2+, 2PBC550 exhibits a stronger affinity for Pb2+ than Cd2+. Through the analysis of characterization methods such as SEM, FTIR, XRD and XPS, it is proved that the adsorption of Pb2+ and Cd2+ by 2PBC550 is due to precipitation, complexation and π electron interaction. Therefore, 2PBC550 shows great application potential in the repair of wastewater containing Pb2+ or Cd2+. [ABSTRACT FROM AUTHOR]

Published

2024

36. On-farm corn stover and cover crop residue recycling with biostimulant Re-Gen increases corn yields and resultant milk yields in multi-year dairy cattle farm trials.

Author

Gibson, William S., Ziobron, Amy S., Olson, Noah E., Neher, Deborah A., Smith II, Charles F., and Holden, Victoria I.

Subjects

CORN stover, MICROBIAL inoculants, CROP residues, MILK yield, COVER crops, ORGANIC farming, DAIRY cattle

Abstract

Introduction: There is a need to rebuild soil health by implementing regenerative agricultural practices across cropping systems dependent on agrochemicals, such as in United States corn production. One increasingly utilized regenerative practice is the application of biostimulants, or microbial inoculants that can rebuild soil health and productivity. In this study, we describe results from a multi-year corn trial conducted to quantify the impact of Re-Gen, a biostimulant invented to recycle plant biomass and increase nutrient bioavailability in the soil. Methods: Re-Gen was applied across four fields (VA01, BH01, VA04, and LA05) at a dairy cattle farm in Ferrisburgh, VT. Results: Over the two consecutive years (2022-2023) of the trial, Re-Gen application on corn stover and cover crop residues increased ear corn yield by 24% and corn silage yield by 12.5-30%, depending on the field. Analysis of soil nutrients and plant tissues showed increased nutrients, particularly in field LA-05. Multi-year Re-Gen application increased yield and generated additional economic value, indicating that the effects of Re-Gen do not diminish with multiple applications. The increased corn silage yield correlated to increased potential milk yield from cows fed silage grown in Re-Gen-treated fields. Further investigation into the mechanism suggests that increased phosphatase production Re-Gen could contribute to increased phosphorus bioavailability in the soil and uptake in the tissue, potentially increasing yields. Discussion: These results highlight the potential for Re-Gen to foster regenerative agriculture processes on cropland and livestock farms while also increasing corn and milk yield and, therefore, revenue for corn farmers in the United States and for similar cropping systems worldwide. [ABSTRACT FROM AUTHOR]

Published

2024

37. Biocalorimetry-aided monitoring of fungal pretreatment of lignocellulosic agricultural residues.

Author

Duong, Hieu Linh, Paufler, Sven, Harms, Hauke, Maskow, Thomas, and Schlosser, Dietmar

Subjects

*WHEAT straw, *AGRICULTURAL wastes, *LIGNOCELLULOSE, *CORN stover, *HEAT flux measurement, *SOLID-state fermentation, *FILAMENTOUS fungi

Abstract

The present study aimed to investigate whether and how non-invasive biocalorimetric measurements could serve for process monitoring of fungal pretreatment during solid-state fermentation (SSF) of lignocellulosic agricultural residues such as wheat straw. Seven filamentous fungi representing different lignocellulose decay types were employed. Water-soluble sugars being immediately available after fungal pretreatment and those becoming water-extractable after enzymatic digestion of pretreated wheat straw with hydrolysing (hemi)cellulases were considered to constitute the total bioaccessible sugar fraction. The latter was used to indicate the success of pretreatments and linked to corresponding species-specific metabolic heat yield coefficients (YQ/X) derived from metabolic heat flux measurements during fungal wheat straw colonisation. An YQ/X range of about 120 to 140 kJ/g was seemingly optimal for pretreatment upon consideration of all investigated fungi and application of a non-linear Gaussian fitting model. Upon exclusion from analysis of the brown-rot basidiomycete Gloeophyllum trabeum, which differs from all other here investigated fungi in employing extracellular Fenton chemistry for lignocellulose decomposition, a linear relationship where amounts of total bioaccessible sugars were suggested to increase with increasing YQ/X values was obtained. It remains to be elucidated whether an YQ/X range being optimal for fungal pretreatment could firmly be established, or if the sugar accessibility for post-treatment generally increases with increasing YQ/X values as long as "conventional" enzymatic, i.e. (hemi)cellulase-based, lignocellulose decomposition mechanisms are operative. In any case, metabolic heat measurement–derived parameters such as YQ/X values may become very valuable tools supporting the assessment of the suitability of different fungal species for pretreatment of lignocellulosic substrates. Key points: • Biocalorimetry was used to monitor wheat straw pretreatment with seven filamentous fungi. • Metabolic heat yield coefficients (YQ/X) seem to indicate pretreatment success. • YQ/X values may support the selection of suitable fungal strains for pretreatment. [ABSTRACT FROM AUTHOR]

Published

2024

38. Enhanced Biological Nitrate Removal from Groundwater in Humid Tropical Regions Using Corn Cob-Based Permeable Reactive Barriers: A Case Study from Panama.

Author

Sánchez Hidalgo, Graciela Cecilia, Ortega, Maria De Los Ángeles, and Deago, Euclides

Subjects

PERMEABLE reactive barriers, CORN stover, FOURIER transform infrared spectroscopy, CORNCOBS, GROUNDWATER, NITRATES

Abstract

Nitrate contamination in groundwater is a global concern due to its widespread presence and consequential social, environmental, and economic ramifications. This study investigates the efficacy of biological denitrification in a humid tropical setting, utilizing corn cob in batch and column tests to assess nitrate removal under varying conditions. Batch tests demonstrated the nitrate removal efficiencies of 93.14%, 91.58%, 90.77%, and 98.74% for initial concentrations of 22.18 ± 2.82 mg/L, 27.3 mg/L, 69.1 ± 1.2 mg/L and 115.08 ± 1.88 mg/L, respectively. In the column test, the removal efficiency was 99.86%, 87.13%, and 74%, and the denitrification rate was 32.82, 53.43, and 83.53 mg NO3−-N/L d, for a hydraulic retention time (HRT) of 24 h, 16 h, and 7 h, respectively. Predominantly, nitrate removal occurred via biological denitrification, particularly favoring a 24 h HRT. The corn cob effectively removed high nitrate concentrations of up to 115 mg NO3−-N/L. Scanning electron microscopy and Fourier transform infrared spectroscopy revealed surface characteristic changes of the carbon source pre- and post-denitrification. This research sheds light on the potential of biological denitrification using corn cob in humid tropical environments, offering a promising avenue for addressing nitrate contamination challenges in groundwater systems. [ABSTRACT FROM AUTHOR]

Published

2024

39. Physical Properties of Moist, Fermented Corn Grain after Processing by Grinding or Milling.

Author

Blazer, Keagan J., Shinners, Kevin J., Kluge, Zachary A., Tekeste, Mehari Z., and Digman, Matthew F.

Subjects

*ENZYMES, *CORN, *BIOMASS production, *CORN storage, *CORN stover, *GRAIN drying, *GRAIN

Abstract

A novel biomass production system, integrating the co-harvesting and co-storage of moist corn grain and stover, promises a reduction in delivered feedstock costs. In this innovative method, the dry grain traditionally utilized for feed or biofuel production will now be processed at a considerably greater moisture content. The adoption of this approach may necessitate a substantial redesign of existing material handling infrastructure to effectively accommodate the handling and storage of moist grain after processing by milling or grinding. A comprehensive study was conducted to quantify the physical properties of this grain after processing with a knife processor or a hammermill. The geometric mean particle size, bulk and tapped density, sliding angle, material coefficient of friction, and discharged angle of repose were quantified. Five grain treatments, either fermented or unfermented, and having different moisture contents, were used. After processing, the moist, fermented ground grain exhibited a significantly smaller particle size compared to the dry grain. Additionally, both moist processed grains resulted in a decreased bulk density and increased material sliding angle, friction coefficient, and angle of repose. The examined metrics collectively suggest that handling, mixing, and storing moist ground grain will pose significant challenges compared to conventional dry ground grain. This increased difficulty may lead to substantially higher costs, a crucial factor that must be carefully considered when evaluating the overall economics of implementing this new biomass production system using combined harvesting and storage of corn grain and stover. [ABSTRACT FROM AUTHOR]

Published

2024

40. Composition Analysis and Environmental Factors Influencing Biomass Quality: a Comparative Study of Montana-Grown Biomasses.

Author

Scheffel, Aidan J., Johnsrude, Lauren M., Allen, Brett L., and Wettstein, Stephanie G.

Subjects

*SUSTAINABILITY, *FACTOR analysis, *BIOMASS, *CORN stover, *ARABINOSE, *ENERGY crops, *CHEMICAL yield, *SWITCHGRASS

Abstract

In order to obtain high yields of chemicals and fuels from biomass, feedstocks need to be selected that contain high amounts of glucose, xylose, or lignin, depending on the end product. The first objective of this study was to evaluate the biomass composition of 20 samples from 11 broadleaf and grass crop species grown at two distinct sites in Montana. Another objective was to investigate the influence of growing location and seed type to determine which cultivars may be best for renewable chemical production in the northern Great Plains. There was a significant effect due to the growing location as the biomass samples from the site that had higher precipitation exhibited a significantly higher acid-insoluble lignin (23.8%) content compared to the biomass samples from the lower precipitation site (20.0%). Additionally, the 357 napus had a significantly higher amount of glucose (1.8% more) and acid-soluble lignin (0.2% more) than compared to the 940 napus both grown at the Froid site that may be attributed to genetic modifications. In terms of sugar content for potential upgrading, the grasses had significantly more glucose (36.1% total), xylose (24.3%), and arabinose (2.3%) than the Brassicaceae biomasses, but the lignin content was not significantly different. Switchgrass, in particular, had the highest total sugar content of close to 70 wt%. Understanding the impact of growing location on biomass composition is an important consideration for optimizing biomass utilization strategies and developing sustainable bioenergy production systems. [ABSTRACT FROM AUTHOR]

Published

2024

41. Cost effective and efficient technique for removing per- and polyfluoroalkyl substances in water.

Author

Mai, Steven

Subjects

FLUOROALKYL compounds, BIOCHAR, CORN stover, CHEMICAL bonds, RENAL cancer, MANUFACTURED products, TESTICULAR cancer, FREE radicals

Abstract

Per- and polyfluoroalkyl substances (PFAS) are synthetic chemicals, which can leak into the surrounding environment, such as water and soil, from water-resistant manufactured products where they remain highly persistent due to their strong chemical bonds. PFAS have been found in human blood and can cause thyroid disease, increased cholesterol levels, liver damage, kidney cancer, and testicular cancer in humans. The goal of this study is to test the effectiveness of sorption and degradation removal methods on PFAS. The sorption method involves the use of biochar. Biochar can hold the PFAS in a concentrated area through electrostatic and hydrophobic properties. The degradation method involves using powerful ultraviolet (UV) light, in which free radicals will be produced and help break down PFAS molecules into simpler ones such as carbon and fluorine. The sorption experiment tested various modified corn biochar and the effect on perfluorobutanesulfonic acid (PFBS). It was found that biochar did have a positive removal effect on PFBS, and the biochar with the most modifications had the highest removal rate. The degradation experiment tested the effect of UV light and other modifications on PFBS. It was found that UV light did have a positive removal effect on PFBS, and the UV light combined with other modifications had a higher removal effect. [ABSTRACT FROM AUTHOR]

Published

2024

42. 水滑石基Ni/Al2O3催化剂催化玉米秸秆加氢裂解制二元醇和 芳香族单体性能研究.

Author

马泽暐 and 温 哲

Subjects

CORN stover, TEMPERATURE-programmed reduction, ALTERNATIVE fuels, CATALYST testing, FOSSIL fuels, GLYCOLS

Abstract

Copyright of Low-Carbon Chemistry & Chemical Engineering is the property of Low-Carbon Chemistry & Chemical Engineering Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

43. Performance and ruminal fermentation of second-trimester pregnant beef cows fed short-season high-moisture corn stover or barley greenfeed during winter in western Canada.

Author

Carey, R.E., Lardner, H.A., McAllister, T.A., and Penner, G.B.

Subjects

CORN stover, DISTILLERY by-products, COWS, BARLEY, FERMENTATION of feeds, FERMENTATION

Abstract

This study evaluated performance and ruminal fermentation for cows fed short-season high-moisture shelled corn stover with corn dried distillers' grains with solubles (COR) or barley greenfeed (BAR) that was either swathed (S-COR; S-BAR; Experiment 1) or baled (B-COR; B-BAR; Experiment 2) as winter-feeding systems. In Experiment 1, cows were randomly assigned to S-COR or S-BAR and fed for 52 days in the fields where crops were grown. Body weight (BW), subcutaneous rib and rump fat, and body condition score (BCS) were measured, with no differences detected between treatments (P > 0.05). However, S-COR had a lower estimated dry matter intake (DMI) than S-BAR (P ≤ 0.03). In Experiment 2, cows were assigned to B-COR or B-BAR for 42 days and fed in field paddocks. Cows fed B-COR had less (P ≤ 0.01) DMI, final BW, rib fat, rump fat, and BCS than B-BAR, with no differences (P > 0.05) for ruminal pH. Total SCFA concentration was greater (P ≤ 0.05) on day 21 for B-BAR than B-COR, but not on day 42. Under western Canadian conditions, COR may reduce DMI and the performance of pregnant cows, suggesting that additional preservation and supplementation strategies should be investigated. [ABSTRACT FROM AUTHOR]

Published

2024

44. Production of Hydrogen with Ruminal Microbiota: Finding Culture Conditions for High Yields.

Author

Gándara-Arteaga, Vianca Maribel, Guatemala-Morales, Guadalupe María, Martínez-Gómez, Álvaro de Jesús, Toriz, Guillermo, Pelayo-Ortiz, Carlos, and Corona-González, Rosa Isela

Subjects

HYDROGEN production, FOSSIL fuels, CORN stover, HEAT treatment, LIGNOCELLULOSE

Abstract

Hydrogen is ideal for replacing fossil fuels because upon combustion it generates only water. Dark fermentation (DF) from lignocellulose might be a competitive process for hydrogen production at the industrial scale. However, lignocellulose must be pretreated to obtain fermentable sugars, which is costly and creates pollution. Microorganisms from bovine rumen efficiently degrade lignocellulose. Unfortunately, they have scarcely been explored for the production of hydrogen. Therefore, deeper studies on the culture conditions have to be undertaken to understand the behavior of microbial consortia from the rumen of bovines (MCRB) during hydrogen production. In this work, we evaluated the production of hydrogen by DF with MCRB by varying the incubation time, two culture media (MB and Rhodospirillaceae), headspace (40 and 80 mL), and thermal treatment. It was found that the production of hydrogen was maximum at 16 h MCRB incubation in MB. An amount of 80 mL headspace resulted in a threefold production of hydrogen as compared to 40 mL; the MCRB without heat treatment had a higher H2 yield. The production of hydrogen with 32 MCRB was highly variable, ranging between 21 and 696 mL. Our findings show a different perspective on the treatment of MCRB for the production of hydrogen and give insights on the impact of the culture conditions for increasing hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2024

45. Moisture relationships among conventional and brown‐midrib corn hybrids for silage.

Author

Cherney, J. H., Cherney, D. J. R., and Digman, M. F.

Subjects

HYBRID corn, MOISTURE, CORN harvesting, SILAGE, CITRUS greening disease, PLANT collecting, CORN stover

Abstract

Much of the corn acreage in New York state is harvested as corn silage and moisture assessment in the field is necessary for predicting harvest timing, but moisture estimation visually is very problematic, particularly for brown‐midrib (BMR) hybrids. Our goal was to assess plant moisture relationships between BMR and conventional (CONV) corn hybrids, and to identify metadata that may assist in the prediction of whole plant moisture based on ear moisture estimations. In 2023, 202 corn fields were sampled in central New York from August 18 to September 27. A total of 41 different corn hybrids were sampled, with relative maturity (RM) ranging from 84 to 112 days, and 29% of the fields sampled were planted to BMR hybrids. Five representative plants per field were evaluated for plant height, ear length and width, and ear, stover, and whole plant moisture. Estimation of dry ear:stover ratio would be helpful in estimating whole plant moisture based on ear moisture. Ear length was not related to ear:stover ratio, while plant height and ear width were weakly but significantly correlated with ear:stover ratio. Ear moisture was highly correlated with ear:stover ratio (BMR, r = −0.95; CONV, r = −0.90), and highly correlated with whole plant moisture (BMR, r = 0.97; CONV, r = 0.98). Ear moisture averaged 1 to 2% units lower throughout the sampling season for BMR compared to CONV hybrids, while stover moisture averaged 1 to 2% units higher for BMR compared to CONV hybrids prior to optimum harvest moisture. Whole plant moisture declined about 0.6%units/day and was relatively similar across RM groups. Plain Language Summary: The primary key to making good corn silage is harvesting at the proper moisture content. It is extremely difficult to visually evaluate standing corn for moisture content. In particular, brown‐midrib hybrids often are diseased and lose their green color but maintain much of their moisture content. It is possible to scan corn ears with a handheld near infrared reflectance (NIR) spectrometer and predict ear moisture, as well as whole plant moisture, from only an ear scan. Although ear moisture is well related to ear:stover ratio and to whole plant moisture, it would be helpful if other data could be used to provide more information on the ear:stover ratio. We collected five corn plants per field from 202 fields in central New York in 2023, and we measured plant height, ear length, ear width, as well as ear, stover and whole plant moisture. Twenty‐nine percent of the plants collected were brown‐midrib hybrids. Ear width and plant height were weakly but significantly correlated with ear:stover. [ABSTRACT FROM AUTHOR]

Published

2024

46. Identifying uncertainty in the global warming impacts of biomaterials: an analysis of biosuccinic acid.

Author

Dunlap, Josh, Schramski, John R., Li, Gengyang, and Li, Ke

Subjects

GLOBAL warming, ENERGY crops, ACID analysis, CORN stover, PRODUCT life cycle assessment, SUGARCANE, CORNSTARCH

Abstract

Purpose: Life cycle assessments of biosuccinic acid (bioSA) report a range of emissions compared to their fossil-based counterparts. Such uncertainty results from multiple factors including different processing options and modeling choices, making it difficult to interpret results and ensure emission reductions. Identifying uncertainty is thus crucial to ensuring the environmental benefits of biomaterials and is a crucial step toward a future bioeconomy. Methods: Comparing 15 life cycle assessments of bioSA production, factors such as feedstocks, downstream processing technologies, study scopes, coproduct handling, coproduct types, and study locations were assessed to identify the impact of different modeling choices and processing options on the global warming impacts of bioSA. Emissions were referenced to a fossil-derived equivalent product and selected case studies were developed for a more in-depth analysis of the impact of individual factors, such as enzymes, coproducts, and grid location on overall emissions. Results: Global warming impacts varied across differing processing and modeling factors. BioSA from sugar cane and energy crops consistently showed emission reductions while from corn starch, corn stover, and food waste, bioSA displayed impacts above and below fossil-based production depending on processing and modeling options. Uncertainty in individual factors such as enzyme production was significant, potentially resulting in impacts exceeding conventional fossil-based production. However, coproduct inclusion and handling methods were necessary for several feedstocks to ensure emissions remained lower than the fossil-based route. Conclusions: This study highlights the importance of identifying and quantifying uncertainties in the global warming impacts of biobased products. Doing so serves not only to ensure emission reduction benefits, but also strengthens trust in LCA studies and encourages more accurate and trustworthy results for policy makers, industrial partners, and LCA practitioners. [ABSTRACT FROM AUTHOR]

Published

2024

47. Psychrophilic co-digestion of carbohydrate waste and chicken manure for biogas production.

Author

Flayyih, Radhwan A., Faraj, Johain J., and Hussien, Fawziea M.

Subjects

*BIOGAS production, *POULTRY manure, *CARBOHYDRATES, *ENERGY development, *ANAEROBIC digestion, *WASTE products as fuel, *CORN stover

Abstract

Waste-to-energy technology is becoming increasingly popular around the world as one of the most effective ways to accomplish long-term energy development. Anaerobic digestion is the most widely used method for converting organic-rich material into clean, sustainable products. As a result, anaerobic digestion is the ideal alternative for safely disposing of the trash while also producing biogas for cooking and heating, as this process creates high-quality fertilizer for soil replenishment with nutrients as well. In this work, the production of biogas from different types of carbohydrates under psychrophilic conditions is investigated. Four identical digesters were prepared for this purpose, loaded with corn, potatoes, sugar, and rice. The digester with the potato showed a significantly higher rate of production and methane production. The delay time was identical for all reactors, which is about 56 days. The recorded temperature was below 25°C during the production period, which is within the psychrophilic range. Sugar, as expected, had the lowest PH due to its rapid hydrolysis, followed by rice, while corn and potato had moderate and favorable values. [ABSTRACT FROM AUTHOR]

Published

2024

48. Corn stover-derived biochar supporting dual functional catalyst for direct sorbitol production from cellulosic materials

Author

Romtira Soda, Wanwitoo Wanmolee, Bunyarit Panyapinyopol, Pawan Boonyoung, Wasawat Kraithong, Nawin Viriya-empikul, Navadol Laosiripojana, and Kamonwat Nakason

Subjects

Cellulose conversion, Agricultural wastes, Hydrolysis hydrogenation, Corn stover, Platform chemicals, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Sorbitol is one of the top twelve platform chemicals and is industrially produced via glucose hydrogenation reaction. Direct sorbitol production from cellulosic material using a low-cost catalyst is a current challenge. In this study, corn stover-derived biochar supporting dual functional catalyst (Ru/S-CCS) was prepared and extensively characterized. The Ru/S-CCS catalyst was used for direct sorbitol production from microcrystalline cellulose at various reaction temperatures (180–220 °C), times (3–18 h), H2 pressures (1–5 MPa), and Ru contents (1–5 %). The maximum sorbitol yield (66.3 wt%) and selectivity (66.1 %) were achieved at 220 °C for 6 h under 5 MPa H2 with 5 % Ru. Various catalyst characterization techniques revealed that the acidic characteristics and metal hydrogenation sites of the Ru/S-CCS played a vital role in direct sorbitol production from cellulose. The sorbitol yield and selectivity could be enhanced by the vigorous interactive effect of sulfonic groups and Ru metal sites. The recycling performance of the Ru/S-CCS catalyst was explored under the optimal reaction conditions. Moreover, sorbitol production from glucose, raw CS, and pretreated CS was further investigated. Overall, the results of this study show that the CS biochar used in Ru/S-CCS preparation can be a competitive material for the catalyst preparation in sorbitol production, which may subsequently be used for designing large-scale sugar alcohol production.

Published

2024

49. Knockout of ZmNST2 promotes bioethanol production from corn stover.

Author

Wang, Ying, Xing, Ye, Yang, Xinyu, Yu, Yanwen, Li, Jiankun, Zhao, Chenyang, Yuan, Mengyu, Huang, Weili, Yin, Yue, Liu, Guohui, Sun, Yuqing, Li, Haochuan, Tang, Jihua, Zhang, Qin, and Gou, Mingyue

Subjects

*CHEMICAL reagents, *LIQUID fuels, *LIGNOCELLULOSE, *ALTERNATIVE fuels, *FOSSIL fuels, *CORN stover

Published

2024

50. Use of a Lignin-Based Admixture for Tailoring the Rheological Properties of Mortars for 3D Printing

Author

Rodriguez, Fabian B., Foster, Kyle E. O., Fross, Xavier, Schmidt, Rory, Aday, Anastasia N., Odukomaiya, Adewale, Himmel, Michael, Griffin, Michael, Lowke, Dirk, editor, Freund, Niklas, editor, Böhler, David, editor, and Herding, Friedrich, editor

Published

2024