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2. Carbon Analysis of Wood Composite Panels

Author

Puettmann, Maureen Elaine

Subjects
Environment -- Research, Forest products industry -- Research -- Environmental aspects, Carbon dioxide -- Control, Emissions (Pollution) -- Control, Fibrous composites -- Research -- Environmental aspects, Business, Forest products industry
Abstract

Wood composite panels (WCP) are well known for their environmentally friendly attributes of being sustainable, renewable, biodegradable, and predominantly made from wood residues generated during lumber and plywood production. This paper focuses on the ability of WCPs to store carbon for long periods of time in nonstructural applications such as cabinets, furniture, and flooring. WCPs, include particleboard, medium density fiberboard (MDF), and hardboard--engineered wood siding and trim (EWST). These panels are anticipated to have an average service life of 25--30 years. In 2019, there was an estimated 291 million cubic meters ([m.sup.3]) of WCPs in use in North America that corresponds to a carbon pool of 354 million metric tons of carbon dioxide equivalents. This WCP carbon pool is enough to offset 24 years of cradle-to-gate cumulative carbon emissions (fossil and biogenic sources) emitted during production of these panels. In other words, producing and using WCPs stores carbon for long periods because the amount of carbon emitted during the production of the panels is far less than what the panels themselves are capable of storing over their lifetime of product use., Demand for sustainable 'green' products, desired for their favorable environmental performance, is increasing in the marketplace. Recent life cycle assessment (LCA) studies document the environmental performance of composite panels (Puettmann [...]

Published
2022
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5. A Life-Cycle Assessment of Forest Resources of the Pacific Northwest, USA

Author

Oneil, Elaine and Puettmann, Maureen E.

Subjects
United States. Environmental Protection Agency -- Powers and duties, Sustainable forestry -- Reports, Business, Forest products industry, United Nations. Environment Programme -- Reports
Abstract

Life-cycle inventory (LCI) and life-cycle assessment (LCA) were used to provide quantitative assessments of the environmental impacts of forest management activities that are required to produce feedstock for wood products such as lumber, engineered panels, and pulp. Primary and secondary data were gathered for the Pacific Northwest Douglas-fir region of the United States to produce an attributional LCA that includes planting, growing, and harvesting trees that are destined for use in wood manufacturing. Using the Tool for the Reduction and Assessment of Chemical and other environmental Impacts (TRACI) method, under average management conditions, forest operations can expect to generate from 10 to 18 kg C[O.sub.2] equivalent (C[O.sub.2] eq) per cubic meter ([m.sup.3]) of logs ready to leave the landing for the manufacturing facility, depending on the amount of forest residues that are piled and burned. This same cubic meter of log plus bark will have sequestered 960 kg C[O.sub.2] eq during its growth cycle, for a net greenhouse gas sink of 942 to 950 kg C[O.sub.2] eq per [m.sup.3]. Forest management impacts are from 1 to 13 percent of the total impacts from the cradle to gate for global warming potential and the potential to increase smog, eutrophication, and acidification. Upstream impacts associated with the production of herbicides are reflected in the ozone potential impact category. These LCA results can be used as upstream processes for wood manufacturers interested in developing Environmental Product Declarations for products that use these resources as inputs., The Consortium for Research on Renewable Industrial Material (CORRIM) has developed research protocols (CORRIM 1998) and methodologies that have been used to conduct a wide range of attributional life-cycle inventory [...]

Published
2017
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6. Cradle-to-Gate Life-Cycle Impact Analysis of Glued-Laminated (Glulam) Timber: Environmental Impacts from Glulam Produced in the US Pacific Northwest and Southeast

Author

Bowers, Tait, Puettmann, Maureen E., Ganguly, Indroneil, and Eastin, Ivan

Subjects
Ecological footprint -- Environmental aspects, Timber -- Production management, Business, Forest products industry, International Organization for Standardization -- Reports
Abstract

This study was an update on the 2000 life-cycle inventory data on material and energy inputs associated with the production of 1 [m.sup.3] of glued-laminated (glulam) timbers produced in the Pacific Northwest (PNW) and the Southeast (SE) regions of the United States. This article looks at the cradle to gate for the entire glulam production processes, which include forest harvest, lamstock production, and glulam beam production. Data collected from glulam beam manufacturers in 2013 allowed for the development of a life-cycle assessment utilizing the product category rules for North American Structural and Architectural Wood Products so that the results from these analyses can be used for the development of environmental product declarations of glulam beams produced in the United States. Comparing the results of this study with the life-cycle assessment based on the 2000 survey data shows 30 percent reductions in global warming potential of glulam beams produced in both the PNW and the SE and reductions in the use of energy derived from fossil fuels by 40 percent in the PNW and SE. The overall net carbon sequestered in 1 [m.sup.3] of PNW glulam is equivalent to 938 kg of C[O.sub.2] and 1,038 kg of C[O.sub.2] in the SE. Utilizing techniques that reduced the use of electricity and minimizing the transportation distances of the raw materials and resins to the mill could help to further reduce the carbon footprint of the glulam beam manufacturing process., The environmental impacts of wood products manufactured in the United States is directly related to the specific product under consideration, the exact process and raw materials utilized to manufacture the [...]

Published
2017
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7. CORRIM: Forest Products Life-Cycle Analysis Update Overview

Author

Oneil, Elaine, Bergman, Richard D., and Puettmann, Maureen E.

Subjects
Forest products industry -- Product introduction -- Reports, Business, Forest products industry, International Organization for Standardization -- Reports
Abstract

Since its inception in 1996, the nonprofit Consortium for Research on Renewable Industrial Materials (CORRIM; www.corrim.org) has developed comprehensive environmental performance information on wood building materials consistent with International Organization [...]

Published
2017
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8. Life-Cycle Assessment for Wood-Fired Boilers Used in the Wood Products Industry

Author

Puettmann, Maureen E. and Milota, Michael

Subjects
United States. Environmental Protection Agency -- Powers and duties, Wood products -- Production management, Business, Forest products industry
Abstract

Many wood production facilities use wood-based fuels for steam generation for drying wood or pressing boards or panels. This process contributes to the life-cycle impacts of the products produced downstream. Past life-cycle assessment studies of wood products have relied on wood boiler data sets that represent both the paper and the wood products industries as well as on secondary data from the US Environmental Protection Agency primarily based on the potential to emit or collect from an uncontrolled source. Primary data were collected by survey for the material and energy inputs and outputs of wood-fired boilers at lumber and plywood wood production facilities in the Pacific Northwest and Southeast regions of the United States. The results were averaged to create a life-cycle inventory model to represent wood-fired boilers at wood production facilities. Results indicated that regional differences, as well as type of wood waste burned, did not warrant separate boiler data sets for each industry and region. The model is useful for including the effects of steam production in the life-cycle assessment of wood products. The primary data used in the model should better represent wood-fired boilers used in US wood production facilities than existing data sets do., Most wood products production facilities generate residues, such as bark, chips, sawdust, hog fuel, trimmings, shavings, mill rejects, and sander dust. These can be green (typically around 50% moisture content [...]

Published
2017
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9. Impacts of the Allocation Assumption in Life-Cycle Assessments of Wood-Based Panels

Author

Taylor, Adam M., Bergman, Richard D., Puettmann, Maureen E., and Alanya-Rosenbaum, Sevda

Subjects
United States. Department of Agriculture -- Reports, Wood products -- Production management, Business, Forest products industry, International Organization for Standardization -- Reports
Abstract

Wood processing often involves an array of products and coproducts and a cascade of primary and secondary uses. Prior life-cycle assessment (LCA) reporting allocated environmental burdens to products and coproducts based on mass for multiproduct systems to develop environmental product declarations, which are developed from LCAs following the procedures detailed in product category rules (PCRs). A recent PCR for North American structural and architectural wood products requires allocation by economic value when the main products exceed the value of coproducts by greater than 10 percent. Using recent LCAs of wood-based panels, this article describes the differences in LCA results when using mass and economic allocation methods. For wood panel products that do not use wood residues from primary wood manufacturers (e.g., plywood), an increase in environmental impacts results from an economic allocation approach. For wood panel products made from wood residues (e.g., cellulosic fiberboard), there is a slight decrease in most environmental impact metrics with economic allocation. Sensitivity and variability in LCA results are discussed for the mass and economic allocation approaches., Wood processing often involves an array of products and coproducts. Life-cycle assessment (LCA) of wood products therefore must divide--or allocate--the environmental impacts of the whole process to these various products [...]

Published
2017
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10. Life-Cycle Assessment for the Cradle-to-Gate Production of Softwood Lumber in the Pacific Northwest and Southeast Regions

Author

Milota, Michael and Puettmann, Maureen E.

Subjects
Raw materials -- Environmental aspects, Business, Forest products industry, Western Wood Products Association -- Reports
Abstract

A cradle-to-gate life-cycle inventory was done for 2 by 4 to 2 by 12 dimension lumber produced from logs in the Pacific Northwest (PNW) and Southeast (SE) regions of the United States. Seven mills in the PNW and 11 mills in the SE provided data for 2012 lumber and coproduct production, raw material and fuel use, electricity consumption, and on-site emissions. The mills represented 17 and 11 percent of the production volumes in the regions, respectively. Five processes existed within the mill, log yard, sawing, drying, planing, and energy generation. Data for the first four processes came exclusively from the survey. The functional unit was 1 [m.sup.3] of planed dry wood. Data for energy generation were based on a nationwide wood boiler survey that included PNW lumber mills. The cradle-to-gate processing energy in the PNW region was 3,434 MJ/[m.sup.3] of planed, dry lumber, 96 percent of which is owing to log transport and wood processing. The value was higher, 5,151 MJ/[m.sup.3], for the SE region in part owing to a higher initial wood moisture content. In each region, more than 70 percent of the energy is from bio-based residuals with less than 30 percent from fossil sources. The global warming impact indicator is 58.7 kg C[O.sub.2] eq per [m.sup.3] in the PNW and 81.4 kg CC_ eq per [m.sup.3] in the SE, of which 85 percent is a result of log transport and processing. Planed, dry lumber from the PNW region stores 856 kg C[O.sub.2] eq per [m.sup.3] compared with 935 kg C[O.sub.2] eq per [m.sup.3] for lumber from the SE region. The coproducts, emissions, and material and energy inputs are further discussed in this article., The environmental consequences of extracting raw materials and producing a product, such as lumber, are carried forward into the life cycle of products, such as wooden structures. These consequences arise [...]

Published
2017
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12. Life Cycle Assessment of Bioethanol Production: A Case Study from Poplar Biomass Growth in the U.S. Pacific Northwest.

Author

Morales-Vera, Rodrigo, Vásquez-Ibarra, Leonardo, Scott, Felipe, Puettmann, Maureen, and Gustafson, Richard

Subjects
ETHANOL as fuel, PRODUCT life cycle assessment, RENEWABLE natural resources, BIOMASS, FOSSIL fuels, POPLARS
Abstract

Biomass appears to be one of the most prominent renewable resources for biofuels such as bioethanol, mainly due to its better environmental performance compared with fossil fuels. This study addresses a comprehensive environmental performance of bioethanol production, employing empirical data from hybrid poplar grown in the U.S. The study considers 1 MJ as a functional unit and employs a cradle-to-grave approach, which entails the feedstock and harvesting production of poplar, transport to a biorefinery, bioconversion of the biomass process, and fuel use. On average, bioconversion is the main contributor to environmental degradation in all the categories evaluated (77%). The second main contributor is either the feedstock and harvesting production of poplar (17%) or fuel use (6%), depending on the environmental category. Thus, focusing on only one category may induce a misinterpretation of the environmental performance of bioethanol production. Finally, environmental credits in the global warming potential (GWP) category were obtained from the carbon sequestered in the biomass during the growing period and from avoided fossil fuel emissions due to electricity production from a renewable source. This means that the net GWP of the life cycle of bioethanol from poplar biomass is slightly negative (−1.05 × 10−3 kg CO2-eq·MJ−1). [ABSTRACT FROM AUTHOR]

Published
2022
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13. The carbon impacts of wood products

Author

Bergman, Richard, Puettmann, Maureen, Taylor, Adam, and Skog, Kenneth E.

Subjects
Carbon sequestration -- Analysis, Forest products -- Usage -- Environmental aspects -- Analysis, Business, Forest products industry
Abstract

Abstract Wood products have many environmental advantages over nonwood alternatives. Documenting and publicizing these merits helps the future competitiveness of wood when climate change impacts are being considered. The manufacture [...]

Published
2014
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14. Life-cycle carbon from waste wood used in district heating and other alternatives

Author

Lippke, Bruce and Puettmann, Maureen E.

Subjects
Wood waste -- Waste management -- Environmental aspects, Boilers -- Usage, Business, Forest products industry
Abstract

Abstract Using wood wastes provides an opportunity to avoid fossil carbon emissions from the combustion of natural gas or other fossil fuels. Using a life-cycle assessment, a new biomass boiler [...]

Published
2013
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15. Using life-cycle assessments to demonstrate the impact of using wood waste as a renewable fuel in urban settings for district heating

Author

Puettmann, Maureen E. and Lippke, Bruce

Subjects
Energy minerals -- Analysis -- Environmental aspects, Fossil fuels -- Analysis -- Environmental aspects, Emissions (Pollution) -- Influence -- Environmental aspects, Boilers -- Usage, Business, Forest products industry
Abstract

Abstract The use of wood waste for heating in urban settings provides an opportunity for communities to reduce annual fossil emissions by directly reducing the amount of fossil fuel used. [...]

Published
2013
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16. Life-cycle assessment for the production of bioethanol from willow biomass crops via biochemical conversion

Author

Budsberg, Erik, Rastogi, Mohit, Puettmann, Maureen E., Caputo, Jesse, Balogh, Stephen, Volk, Timothy A., Gustafson, Richard, and Johnson, Leonard

Subjects
Life cycle assessment -- Analysis, Energy crops -- Analysis, Market trend/market analysis, Business, Forest products industry
Abstract

We conducted a life-cycle assessment (LCA) of ethanol production via bioconversion of willow biomass crop feedstock. Willow crop data were used to assess feedstock production impacts. The bioconversion process was modeled with an Aspen simulation that predicts an overall conversion yield of 310 liters of ethanol per tonne of feedstock (74 gal per US short ton). Vehicle combustion impacts were assessed using Greenhouse Gases, Regulated Emissions, and Energy Use in Transportation (GREET) models. We compared the impacts of bioconversion-produced ethanol with those of gasoline on an equivalent energy basis. We found that the life-cycle global warming potential of ethanol was slightly negative. Carbon emissions from ethanol production and use were balanced by carbon absorption in the growing willow feedstock and the displacement of fossil fuel-produced electricity with renewable electricity produced in the bioconversion process. The fossil fuel input required for producing 1 MJ of energy from ethanol was 141 percent less than that from gasoline. More water was needed to produce 1 MJ of ethanol fuel than 1 MJ of gasoline. The life-cycle water use for ethanol was 169 percent greater than for gasoline. The largest contributors to water use were the conversion process itself and the production of chemicals and materials used in the process, such as enzymes and sulfuric acid., ********** The Energy Independence and Security Act (EISA) mandates that at least 16 billion gallons (61 billion liters) per y of cellulosic fuel be in production by the year 2022 [...]

Published
2012

17. Life-cycle assessment of bioethanol from pine residues via indirect biomass gasification to mixed alcohols

Author

Daystar, Jesse, Reeb, Carter, Venditti, Richard, Gonzalez, Ronalds, and Puettmann, Maureen E.

Subjects
Biomass energy -- Analysis, Feedstock -- Economic aspects -- Analysis, Life cycle assessment -- Analysis, Energy industry -- Economic aspects, Business, Forest products industry
Abstract

The goal of this study was to estimate the greenhouse gas (GHG) emissions and fossil energy requirements from the production and use (cradle-to-grave) of bioethanol produced from the indirect gasification thermochemical conversion of loblolly pine (Pinus taeda) residues. Additional impact categories (acidification and eutrophication) were also analyzed. Of the life-cycle stages, the thermochemical fuel production and biomass growth stages resulted in the greatest environmental impact for the bioethanol product life cycle. The GHG emissions from fuel transportation and process chemicals used in the thermochemical conversion process were minor (less than 1 percent of conversion emissions). The net GHG emissions over the bioethanol life cycle, cradle-to-grave, was 74 percent less than gasoline of an equal energy content, meeting the 60 percent minimum reduction requirement of the Renewable Fuels Standard to qualify as an advanced (second generation) biofuel. Also, bioethanol had a 72 percent lower acidification impact and a 59 percent lower eutrophication impact relative to gasoline. The fossil fuel usage for bioethanol was 96 percent less than gasoline, mainly because crude oil is used as the primary feedstock for gasoline production. The total GHG emissions for the bioethanol life cycle analyzed in this study were determined to be similar to the comparable scenario from the Greenhouse Gases, Regulated Emissions, and Energy Use in Transportation model. A sensitivity analysis determined that mass allocation of forest establishment burdens to the residues was not significant for GHG emissions but had significant effects on the acidification and eutrophication impact categories., ********** The United States is the largest bioethanol producing country, with 49.2 billion liters as of 2010 (Renewable Fuels Association [RFA] 2010). Controversy around conventional biofuels, which are usually produced [...]

Published
2012

18. Carbon emission reduction impacts from alternative biofuels

Author

Lippke, Bruce, Puettmann, Maureen E., Johnson, Leonard, Venditti, Richard, Gustafson, Richard, Steele, Philip, Katers, John F., Taylor, Adam, Volk, Timothy A., Oneil, Elaine, Skog, Kenneth, Budsberg, Erik, Daystar, Jesse, and Caputo, Jesse

Subjects
Biomass energy -- Analysis, Forest products -- Usage -- Analysis, Emissions (Pollution) -- Environmental aspects, Business, Forest products industry
Abstract

The heightened interest in biofuels addresses the national objectives of reducing carbon emissions as well as reducing dependence on foreign fossil fuels. Using life-cycle analysis to evaluate alternative uses of wood including both products and fuels reveals a hierarchy of carbon and energy impacts characterized by their efficiency in reducing carbon emissions and/or in displacing fossil energy imports. Life-cycle comparisons are developed for biofuel feedstocks (mill and forest residuals, thinnings, and short rotation woody crops) with bioprocessing (pyrolysis, gasification, and fermentation) to produce liquid fuels and for using the feedstock for pellets and heat for drying solid wood products, all of which displace fossil fuels and fossil fuel-intensive products. Fossil carbon emissions from lignocellulosic biofuels are substantially lower than emissions from conventional gasoline. While using wood to displace fossil fuel-intensive materials (such as for steel floor joists) is much more effective in reducing carbon emissions than using biofuels to directly displace fossil fuels, displacing transportation fuels with ethanol provides the opportunity to also reduce dependence on imported energy. The complex nature of wood uses and how wood fuels and products interact in their environments, as well as the methods needed to understand these impacts and summarize the relative benefits of different alternatives, are discussed herein. Policies designed to increase biofuel use by subsidies or mandates may increase prices enough to divert biomass feedstock away from producing products, such as for composite panels, resulting in increased emissions from fossil fuel-intensive substitutes. Policies that fail to consider life-cycle implications are discussed, identifying their unintended consequences., The life-cycle inventory (LCI) data for the many different uses of wood reveal a hierarchy of different opportunities to reduce carbon emissions or increase energy independence, both being current national [...]

Published
2012

19. Life-cycle assessment of pyrolysis bio-oil production

Author

Steele, Philip, Puettmann, Maureen E., Penmetsa, Venkata Kanthi, and Cooper, Jerome E.

Subjects
Life cycle assessment -- Analysis, Atmospheric carbon dioxide -- Environmental aspects, Pyrolysis -- Analysis, Fuelwood -- Economic aspects -- Analysis, Business, Forest products industry
Abstract

As part of the Consortium for Research on Renewable Industrial Materials' Phase I life-cycle assessments of biofuels, lifecycle inventory burdens from the production of bio-oil were developed and compared with measures for residual fuel oil. Bio-oil feedstock was produced using whole southern pine (Pinus taeda) trees, chipped, and converted into bio-oil by fast pyrolysis. Input parameters and mass and energy balances were derived with Aspen. Mass and energy balances were input to SimaPro to determine the environmental performance of bio-oil compared with residual fuel oil as a heating fuel. Equivalent functional units of 1 MJ were used for demonstrating environmental preference in impact categories, such as fossil fuel use and global warming potential. Results showed near carbon neutrality of the bio-oil. Substituting bio-oil for residual fuel oil, based on the relative carbon emissions of the two fuels, estimated a reduction in [CO.sub.2] emissions by 0.075 kg [CO.sub.2] per MJ of fuel combustion or a 70 percent reduction in emission over residual fuel oil. The bio-oil production life-cycle stage consumed 92 percent of the total cradle-to-grave energy requirements, while feedstock collection, preparation, and transportation consumed 4 percent each. This model provides a framework to better understand the major factors affecting greenhouse gas emissions related to bio-oil production and conversion to boiler fuel during fast pyrolysis., ********** This report has been produced as part of the Consortium for Research on Renewable Industrial Materials (CORRIM) Phase I reports on the life-cycle inventory (LCI) and life-cycle impact assessment [...]

Published
2012

20. Cradle-to-gate life-cycle inventory and impact assessment of wood fuel pellet manufacturing from hardwood flooring residues in the Southeastern United States

Author

Reed, Daniel, Taylor, Adam, Knowles, Chris, Bergman, Richard, Harper, David, Puettmann, Maureen E., Kim, Jae-Woo, and Jones, David

Subjects
Pelletizing -- Analysis, Pulp industry -- Analysis, Fuelwood -- Analysis, Business, Forest products industry
Abstract

In this article, we present cradle-to-gate life-cycle inventory (LCI) data for wood fuel pellets manufactured in the Southeast United States. We surveyed commercial pellet manufacturers in 2010, collecting annual production data for 2009. Weighted-average inputs to, and emissions from, the pelletization process were determined. The pellet making unit process was combined with existing LCI data from hardwood flooring residues production, and a life-cycle impact assessment was conducted using the Tool for the Reduction and Assessment of Chemical and Other Environmental Impacts (TRACI) model. The potential bioenergy and embodied nonrenewable energy in 907 kg (1 ton, the functional unit of this study) of wood fuel pellets was also calculated. The pelletization of wood requires significant amounts of electrical energy (145 kWh/Mg), but the net bioenergy balance is positive. Wood pellets require 5.8 GJ of fossil energy to produce 17.3 GJ of bioenergy (a net balance of 10.4 GJ/Mg). However, if environmental burdens are allocated to the pellet raw material (flooring residues) by value, then the embodied fossil energy is reduced to 2.3 GJ. The pelletization unit process data collected here could be used in an assessment of the environmental impacts of pellet fuel, or when pellets are a pretreatment step in wood-based biorefinery processes., ********** The wood manufacturing industry in the United States obtains more than 50 percent of their heat energy requirements by burning wood residues produced during production (Puettmann and Wilson 2005, [...]

Published
2012

21. Woody biomass substitution for thermal energy at softwood lumber mills in the US in land Northwest

Author

Puettmann, Maureen E. and Lippke, Bruce

Subjects
Electric power -- Analysis, Biomass energy -- Analysis -- Economic aspects, Environmental impact analysis -- Methods, Business, Forest products industry
Abstract

Using life-cycle inventory production data, the net global warming potential (GWP) of a typical inland Northwest softwood lumber mill was evaluated for a variety of fuel types used as boiler inputs and for electricity generation. Results focused on reductions in carbon emissions in terms of GWP relative to natural gas as the fossil alternative. Woody feedstocks included mill residues, forest residuals, and wood pellets. In all fuel-substitution scenarios, increasing the use of biomass for heat generation decreased GWP. Using woody biofuels for electricity production is somewhat less effective in lowering carbon emissions than when used for heat energy. Heat generation at the mill under the current practice of using about half self-generated mill residues and half natural gas resulted in a 35 percent reduction in GWP over 100 percent natural gas. The greatest reduction in GWP (66%) was from increased use of forest residuals for heat energy, eliminating the use of fossil fuels as a direct heating fuel at the mill. We summarize the results by documenting that greater use of woody biomass for heat energy will reduce carbon emissions over fossil-based fuels., ********** Recent technological advances have provided numerous options for the conversion of biomass to energy. These technologies include electricity production, pellet production for residential and industrial heating, woody and agricultural [...]

Published
2012

22. Life-cycle inventory of wood pellet manufacturing and utilization in Wisconsin

Author

Katers, John F., Snippen, Adam J., and Puettmann, Maureen E.

Subjects
Pelletizing -- Analysis, Energy minerals -- Analysis, Fossil fuels -- Analysis, Life cycle assessment -- Analysis, Business, Forest products industry
Abstract

This study summarizes environmental impacts of 'premium' wood pellet manufacturing and use through a cradle-to-grave life-cycle inventory. The system boundary began with growing and harvesting timber and ended with use of wood pellet fuel. Data were collected from Wisconsin wood pellet mills, which produce wood pellets from a variety of feedstocks. Three groups of manufacturers were identified, those who use wet coproduct, dry coproduct, and harvested timber. Pellet mill data were weight averaged on a per unit basis of 1.0 short ton of 'premium' wood pellets, and burdens for all substances and energy consumed were allocated among the products on a 0 percent moisture basis. Wood pellets produced from dry coproduct required 60 percent less energy at the pellet mill. However, when considering all cradle-to-gate energy inputs, producing wood pellets from whole logs used the least energy. Pellets from wet coproduct and dry coproduct used 9 and 56 percent more energy across the life cycle, respectively. This study also compared environmental impacts of residential heating fuels with wood pellet fuel. Environmental impacts were measured on net atmospheric carbon emissions, nonrenewable energy use, and global warming potential (GWP). Assuming 'better than break-even' forest carbon management, cordwood and wood pellet fuels emitted 67.3 and 26.6 percent less atmospheric carbon emissions per megajoule of residential heat across the life cycle than natural gas, the best fossil fuel alternative. Cordwood and wood pellets consumed fewer nonrenewable resources than natural gas, which consumed fewer resources than petroleum-based residual fuel oil. However, wood pellet fuels had a smaller GWP and effect on respiratory health because they have more efficient combustion., ********** The increasing economic and environmental cost of acquiring energy from fossil fuels has led the United States to explore the development of a variety of renewable and domestic energy [...]

Published
2012

23. Comparing life-cycle carbon and energy impacts for biofuel, wood product, and forest management alternatives

Author

Lippke, Bruce, Gustafson, Richard, Venditti, Richard, Steele, Philip, Volk, Timothy A., Oneil, Elaine, Johnson, Leonard, Puettmann, Maureen E., and Skog, Kenneth

Subjects
Biomass energy -- Analysis, Atmospheric carbon dioxide -- Environmental aspects, Forest products -- Analysis -- Usage, Forest management -- Methods, Business, Forest products industry
Abstract

The different uses of wood result in a hierarchy of carbon and energy impacts that can be characterized by their efficiency in displacing carbon emissions and/or in displacing fossil energy imports, both being current national objectives. When waste wood is used for biofuels (forest or mill residuals and thinnings) fossil fuels and their emissions are reduced without significant land use changes. Short rotation woody crops can increase yields and management efficiencies by using currently underused land. Wood products and biofuels are coproducts of sustainable forest management, along with the other values forests provide, such as clean air, water, and habitat. Producing multiple coproducts with different uses that result in different values complicates carbon mitigation accounting. It is important to understand how the life-cycle implications of managing our forests and using the wood coming from our forests impacts national energy and carbon emission objectives and other forest values. A series of articles published in this issue of the Forest Products Journal reports on the life-cycle implications of producing ethanol by gasification or fermentation and producing bio-oil by pyrolysis and feedstock collection from forest residuals, thinnings, and short rotation woody crops. These are evaluated and compared with other forest product uses. Background information is provided on existing life-cycle data and methods to evaluate prospective new processes and wood uses. Alternative management, processing, and collection methods are evaluated for their different efficiencies in contributing to national objectives., ********** Sustainably managed forests remove carbon from the atmosphere during their growth cycle, transferring that carbon by harvesting and processing to product carbon stores or fuels that displace fossil fuel-intensive [...]

Published
2012

25. Introduction to special issue: Evaluating the environmental performance of wood-based biofuels

Author

Lippke, Bruce, Bergman, Richard, Taylor, Adam, and Puettmann, Maureen E.

Subjects
Biomass energy -- Analysis, Life cycle assessment -- Analysis, Forest products -- Analysis, Business, Forest products industry
Abstract

The nonprofit Consortium for Research on Renewable Industrial Materials (CORRIM) has been developing comprehensive environmental performance information on wood building materials consistent with life-cycle standards (http://www.corrim.org/). The articles published in [...]

Published
2012

26. The Plant a Trillion Trees Campaign to Reduce Global Warming – Fleshing Out the Concept.

Author

Lippke, Bruce, Puettmann, Maureen, Oneil, Elaine, and Dearing Oliver, Chadwick

Subjects
*GLOBAL warming, *FORESTS & forestry, *WOOD products, *TREE growth, *DISPLACEMENT (Mechanics)
Abstract

The campaign to plant a trillion trees provided an easily understood approach to reduce the threat of global warming. However, focusing on trees does not consider that a maturing forest releases carbon (C) from dying trees offsetting C intake from growth of other trees, and results in only a one-time carbon storage benefit. Under sustainable management that harvests before forest growth slows down, forest C is transferred to wood products that substitute for fossil fuel (FF)-intensive products, reducing the carbon dioxide (CO2) emissions with every harvest. Sustainably managed forests maintain growth by replanting (or regenerating), sustaining the C stored in products, as well as avoiding FF-intensive product emissions with every harvest. This paper addresses the question: Could planting more trees significantly reduce atmospheric CO2; and if so, how? Survey data from many wood-producing mills show life cycle inventory (LCI) data on C that has been tracked through every stage of processing for many different wood products specific to each United States (USA) supply region, as well as C displacement measurements when substituting wood for FF-intensive products. Results show that more and better-managed forest lands and more efficient product uses provide significant opportunities to reduce CO2 emissions, especially in highly productive forest regions. [ABSTRACT FROM AUTHOR]

Published
2021
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27. LIFE CYCLE ENERGY AND ENVIRONMENTAL IMPACTS OF CROSS LAMINATED TIMBER MADE WITH COASTAL DOUGLAS-FIR.

Author

Puettmann, Maureen, Sinha, Arijit, and Ganguly, Indroneil

Subjects
CARBON sequestration in forests, ENERGY consumption, SOFTWOOD, WOOD products, FOSSIL fuels
Abstract

In this study, a cradle-to-gate life-cycle assessment (LCA) of Oregon-made cross-laminated timber (CLT) was conducted as per the ISO guidelines. Primary data pertaining to CLT manufacturing was collected from a production facility in Oregon and modeled with existing LCA data of Pacific Northwest softwood lumber production and harvesting operations. Primary energy is reported and encompasses all processes within the system boundary. Carbon emissions are reported and include fossil-based emissions from transportation and all production processes and carbon storage in CLT. LCA results are presented for five impact categories, primary energy consumption, and net carbon impact of CLT. Results show the environmental advantage of CLT due to storing of large amounts of biogenic carbon in a building structure for a lifetime. The amount of carbon stored in CLT offsets the emissions released from all production processes; this indicates that CLT is a net negative carbon emitter, as more carbon is stored in the product than is emitted to produce the product. This study shows the importance of using the LCA methodology for showing the net amount and type of energy used for production and the potential climatic impacts of using wood products. This LCA study makes no comparative assertions. [ABSTRACT FROM AUTHOR]

Published
2019
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30. ENVIRONMENTAL IMPACT ASSESSMENT OF LIGHT-FRAME AND TIMBER FRAME STRUCTURES.

Author

Malone, Brian P., Gupta, Rakesh, Miller, Thomas H., and Puettmann, Maureen E.

Subjects
ENVIRONMENTAL impact analysis, WOODEN-frame houses, CONSTRUCTION industry, FOSSIL fuels, ENERGY consumption
Abstract

The objective of this study was to analyze the environmental performance of different wood structural assemblies for residential buildings. Two structural systems (a traditional timber frame and a light-frame) were compared together with alternate material options for each system. Environmental impacts were determined using the Athena Impact Estimator for Buildings software. Design alterations for generalization were made to an existing timber frame (TF) structure used as the basis of this analysis, and an equivalent light-frame (LF) structure was designed based on the International Residential Code (IRC). Environmental impacts observed include total energy consumption, fossil fuel consumption, global warming potential (GWP), and wood fiber use. All analyses were considered cradle-to-gate, including the manufacturing and construction life-cycle stages. Results show how GWP is linked to both fossil fuel consumption and wood fiber use, and how ultimate environmental impact is driven by energy source. Environmental impacts of structures are driven by material choice, and levels of carbon stored in structural wood serve to decrease GWP. Of the structural assemblies analyzed, the most traditional TF structure outperformed all other options in almost every measure. [ABSTRACT FROM AUTHOR]

Published
2014
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31. Sustainable Biofuel Contributions to Carbon Mitigation and Energy Independence.

Author

Lippke, Bruce, Gustafson, Richard, Venditti, Richard, Volk, Timothy, Oneil, Elaine, Johnson, Leonard, Puettmann, Maureen, and Steele, Phillip

Subjects
BIOMASS energy, CARBON & the environment, ENERGY security, FOSSIL fuels, WOOD products, ECONOMICS
Abstract

The growing interest in US biofuels has been motivated by two primary national policy goals, (1) to reduce carbon emissions and (2) to achieve energy independence. However, the current low cost of fossil fuels is a key barrier to investments in woody biofuel production capacity. The effectiveness of wood derived biofuels must consider not only the feedstock competition with low cost fossil fuels but also the wide range of wood products uses that displace different fossil intensive products. Alternative uses of wood result in substantially different unit processes and carbon impacts over product life cycles. We developed life cycle data for new bioprocessing and feedstock collection models in order to make life cycle comparisons of effectiveness when biofuels displace gasoline and wood products displace fossil intensive building materials. Wood products and biofuels can be joint products from the same forestland. Substantial differences in effectiveness measures are revealed as well as difficulties in valuing tradeoffs between carbon mitigation and energy independence. [ABSTRACT FROM AUTHOR]

Published
2011
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33. A Lifecycle Assessment of a Low-Energy Mass-Timber Building and Mainstream Concrete Alternative in Central Chile.

Author

Felmer, Gabriel, Morales-Vera, Rodrigo, Astroza, Rodrigo, González, Ignacio, Puettmann, Maureen, and Wishnie, Mark

Abstract

While high-rise mass-timber construction is booming worldwide as a more sustainable alternative to mainstream cement and steel, in South America, there are still many gaps to overcome regarding sourcing, design, and environmental performance. The aim of this study was to assess the carbon emission footprint of using mass-timber products to build a mid-rise low-energy residential building in central Chile (CCL). The design presented at a solar decathlon contest in Santiago was assessed through lifecycle analysis (LCA) and compared to an equivalent mainstream concrete building. Greenhouse gas emissions, expressed as global warming potential (GWP), from cradle-to-usage over a 50-year life span, were lower for the timber design, with 131 kg CO2 eq/m2 of floor area (compared to 353 kg CO2 eq/m2) and a biogenic carbon storage of 447 tons of CO2 eq/m2 based on sustainable forestry practices. From cradle-to-construction, the embodied emissions of the mass-timber building were 42% lower (101 kg CO2 eq/m2) than those of the equivalent concrete building (167 kg CO2 eq/m2). The embodied energy of the mass-timber building was 37% higher than that of its equivalent concrete building and its envelope design helped reduce space-conditioning emissions by as much as 83%, from 187 kg CO2 eq/m2 as estimated for the equivalent concrete building to 31 kg CO2 eq/m2 50-yr. Overall, provided that further efforts are made to address residual energy end-uses and end-of-life waste management options, the use of mass-timber products offers a promising potential in CCL for delivering zero carbon residential multistory buildings. [ABSTRACT FROM AUTHOR]

Published
2022
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34. What Is the Impact of Mass Timber Utilization on Climate and Forests?

Author

Pasternack, Rachel, Wishnie, Mark, Clarke, Caitlin, Wang, Yangyang, Belair, Ethan, Marshall, Steve, Gu, Hongmei, Nepal, Prakash, Dolezal, Franz, Lomax, Guy, Johnston, Craig, Felmer, Gabriel, Morales-Vera, Rodrigo, Puettmann, Maureen, and Van den Huevel, Robyn

Abstract

As the need to address climate change grows more urgent, policymakers, businesses, and others are seeking innovative approaches to remove carbon dioxide emissions from the atmosphere and decarbonize hard-to-abate sectors. Forests can play a role in reducing atmospheric carbon. However, there is disagreement over whether forests are most effective in reducing carbon emissions when left alone versus managed for sustainable harvesting and wood product production. Cross-laminated timber is at the forefront of the mass timber movement, which is enabling designers, engineers, and other stakeholders to build taller wood buildings. Several recent studies have shown that substituting mass timber for steel and concrete in mid-rise buildings can reduce the emissions associated with manufacturing, transporting, and installing building materials by 13%-26.5%. However, the prospect of increased utilization of wood products as a climate solution also raises questions about the impact of increased demand for wood on forest carbon stocks, on forest condition, and on the provision of the many other critical social and environmental benefits that healthy forests can provide. A holistic assessment of the total climate impact of forest product demand across product substitution, carbon storage in materials, current and future forest carbon stock, and forest area and condition is challenging, but it is important to understand the impact of increased mass timber utilization on forests and climate, and therefore also on which safeguards might be necessary to ensure positive outcomes. To thus assess the potential impacts, both positive and negative, of greater mass timber utilization on forests ecosystems and emissions associated with the built environment, The Nature Conservancy (TNC) initiated a global mass timber impact assessment (GMTIA), a five-part, highly collaborative research program focused on understanding the potential benefits and risks of increased demand for mass timber products on forests and identifying appropriate safeguards to ensure positive outcomes. [ABSTRACT FROM AUTHOR]

Published
2022
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35. Mass Timber Building Life Cycle Assessment Methodology for the U.S. Regional Case Studies.

Author

Gu, Hongmei, Liang, Shaobo, Pierobon, Francesca, Puettmann, Maureen, Ganguly, Indroneil, Chen, Cindy, Pasternack, Rachel, Wishnie, Mark, Jones, Susan, and Maples, Ian

Abstract

The building industry currently consumes over a third of energy produced and emits 39% of greenhouse gases globally produced by human activities. The manufacturing of building materials and the construction of buildings make up 11% of those emissions within the sector. Whole-building life-cycle assessment is a holistic and scientific tool to assess multiple environmental impacts with internationally accepted inventory databases. A comparison of the building life-cycle assessment results would help to select materials and designs to reduce total environmental impacts at the early planning stage for architects and developers, and to revise the building code to improve environmental performance. The Nature Conservancy convened a group of researchers and policymakers from governments and non-profit organizations with expertise across wood product life-cycle assessment, forest carbon, and forest products market analysis to address emissions and energy consumption associated with mass timber building solutions. The study disclosed a series of detailed, comparative life-cycle assessments of pairs of buildings using both mass timber and conventional materials. The methodologies used in this study are clearly laid out in this paper for transparency and accountability. A plethora of data exists on the favorable environmental performance of wood as a building material and energy source, and many opportunities appear for research to improve on current practices. [ABSTRACT FROM AUTHOR]

Published
2021
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36. Comparative LCAs of Conventional and Mass Timber Buildings in Regions with Potential for Mass Timber Penetration.

Author

Puettmann, Maureen, Pierobon, Francesca, Ganguly, Indroneil, Gu, Hongmei, Chen, Cindy, Liang, Shaobo, Jones, Susan, Maples, Ian, and Wishnie, Mark

Abstract

Manufacturing of building materials and construction of buildings make up 11% of the global greenhouse gas emission by sector. Mass timber construction has the potential to reduce greenhouse gas emissions by moving wood into buildings with designs that have traditionally been dominated by steel and concrete. The environmental impacts of mass timber buildings were compared against those of functionally equivalent conventional buildings. Three pairs of buildings were designed for the Pacific Northwest, Northeast and Southeast regions in the United States to conform to mass timber building types with 8, 12, or 18 stories. Conventional buildings constructed with concrete and steel were designed for comparisons with the mass timber buildings. Over all regions and building heights, the mass timber buildings exhibited a reduction in the embodied carbon varying between 22% and 50% compared to the concrete buildings. Embodied carbon per unit of area increased with building height as the quantity of concrete, metals, and other nonrenewable materials increased. Total embodied energy to produce, transport, and construct A1–A5 materials was higher in all mass timber buildings compared to equivalent concrete. Further research is needed to predict the long-term carbon emissions and carbon mitigation potential of mass timber buildings to conventional building materials. [ABSTRACT FROM AUTHOR]

Published
2021
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37. Life cycle assessment of biochar produced from forest residues using portable systems.

Author

Puettmann, Maureen, Sahoo, Kamalakanta, Wilson, Kelpie, and Oneil, Elaine

Subjects
*BIOCHAR, *FOREST thinning, *SLASH (Logging), *FORESTS & forestry, *FUELWOOD, *FOREST fires
Abstract

Forest fires are getting extreme and more frequent because of increased fuel loads in the forest and extended dry conditions. Fuel treatment (i.e., thinning) methods to mitigate forest fires will generate large volumes of forest residues together with available logging residues that can be used to produce biochar. It has been proposed that portable biochar systems are economical means to utilize forest residues as an alternative to slash burning. In this study, the environmental impacts of biochar produced from forest residues using three portable systems [1. Biochar Solutions Incorporated (BSI), 2. Oregon Kiln, and 3. Air-curtain Burner] were evaluated using a cradle-to-gate life-cycle assessment approach. Environmental impacts were analyzed considering the various quality of feedstock, biomass collection methods, different production sites, and various sources of power used in the production of biochar. The results illustrate that the global warming potential (GWP) of biochar production from forest residues through BSI, Oregon Kiln, and Air-Curtain Burner were 0.25–0.31, 0.11, and 0.16 tonne CO 2 eq./tonne of fixed carbon in biochar respectively. Compared to pile burn, biochar production from forest residues with a portable system at the landing, reduced global warming potential (GWP) by 1.92–2.83, 2.7, and 1.9 tonnes CO 2 eq./tonne of biochar through BSI, Oregon Kiln, and Air-Curtain Burner respectively. The Air-Curtain Burner and Oregon Kiln have minimal feedstock preparation, thus have lower environmental impacts than the BSI system. The BSI system requires feedstock preparation and power to operate the system. The use of the biomass-gasifier generator improved the environmental performance substantially (16–280%) compared with a diesel generator in biochar production. Overall, the net GWP in biochar produced (0.10–1.63 tonne CO 2 eq./tonne of residues) from forest residues can reduce environmental impacts (2–40 times lower net CO 2 eq. emissions) compared to slash burning. [ABSTRACT FROM AUTHOR]

Published
2020
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38. Borate surpasses five-year mark in termite barrier study.

Author

Williams, Lonnie and Puettmann, Maureen Mitchoff

Subjects
BORATES, TERMITES, TERMITE control
Abstract

Makes observations on the use of borate as effective, long-lasting wood-applied termite control and prevention method. Mechanics of applying boron penetration tests; Avoidance of treated tubes by underground termites.

Published
1998

39. Life Cycle Assessment of products from Alaskan salmon processing wastes: Implications of coproduction, intermittent landings, and storage time.

Author

Cooper, Joyce, Diesburg, Steven, Babej, Alaric, Noon, Michael, Kahn, Ezra, Puettmann, Maureen, and Colt, John

Subjects
*LIFE cycles (Biology), *SALMON, *FISHERY processing plant waste, *CLIMATE change, *ACIDIFICATION, *EUTROPHICATION, *COMPARATIVE studies
Abstract

Highlights: [•] We model the gate-to-grave life cycles of four salmon offal management options. [•] We examine contributions to climate change, acidification, and eutrophication. [•] Impact is reduced by processing the offal into coproducts as compared to grind and discharge disposal. [Copyright &y& Elsevier]

Published
2014
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