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105. Economics, Environmental Impacts, and Supply Chain Analysis of Cellulosic Biomass for Biofuels in the Southern US: Pine, Eucalyptus, Unmanaged Hardwoods, Forest Residues, Switchgrass, and Sweet Sorghum.

Author

Daystar, Jesse, Gonzalez, Ronalds, Reeb, Carter, Venditti, Richard, Treasure, Trevor, Abt, Robert, and Kelley, Steve

Subjects
*BIOMASS energy, *SWITCHGRASS, *SORGO, *SUPPLY chains, *EUCALYPTUS, *HARDWOODS
Abstract

The production of six regionally important cellulosic biomass feedstocks, including pine, eucalyptus, unmanaged hardwoods, forest residues, switchgrass, and sweet sorghum, was analyzed using consistent life cycle methodologies and system boundaries to identify feedstocks with the lowest cost and environmental impacts. Supply chain analysis was performed for each feedstock, calculating costs and supply requirements for the production of 453,592 dry tonnes of biomass per year. Cradle-togate environmental impacts from these modeled supply systems were quantified for nine mid-point indicators using SimaPro 7.2 LCA software. Conversion of grassland to managed forest for bioenergy resulted in large reductions in GHG emissions due to carbon uptake associated with direct land use change. By contrast, converting forests to cropland resulted in large increases in GHG emissions. Production of forest-based feedstocks for biofuels resulted in lower delivered cost, lower greenhouse gas (GHG) emissions, and lower overall environmental impacts than the agricultural feedstocks studied. Forest residues had the lowest environmental impact and delivered cost per dry tonne. Using forest-based biomass feedstocks instead of agricultural feedstocks would result in lower cradle-to-gate environmental impacts and delivered biomass costs for biofuel production in the southern U.S. [ABSTRACT FROM AUTHOR]

Published
2014

107. Impacts of Feedstock Composition on Alcohol Yields and Greenhouse Gas Emissions from the NREL Thermochemical Ethanol Conversion Process.

Author

Daystar, Jesse S., Venditti, Richard A., Gonzalez, Ronalds, Jameel, Hasan, Jett, Mike, and Reeb, Carter W.

Subjects
FEEDSTOCK, ALCOHOL, GREENHOUSE gases, EMISSIONS (Air pollution), THERMOCHEMISTRY, ETHANOL, ENERGY conversion
Abstract

There has been great attention focused on the effects of first and second generation biofuels on global warming. The Energy Independence and Security Act (EISA) and the Renewable Fuel Standard (RFS) have mandated production levels and performance criteria of biofuels in the United States. The thermochemical conversion of biomass to ethanol shows potential as a biofuel production pathway. The objective of this research was to examine the alcohol yields and GHG emissions from the thermochemical conversion process for six different feedstocks on a gate-to-gate basis. GHG analyses and life cycle assessments were performed for natural hardwood, loblolly pine, eucalyptus, miscanthus, corn stover, and switchgrass feedstocks using a NREL thermochemical model and SimaPro. Alcohol yield and GHG emission for the hybrid poplar baseline feedstock conversion were 105,400 L dry metric ton-1 and 2.8 kg CO2 eq. per liter, respectively. Compared with the baseline, loblolly pine produced the highest alcohol yields, an 8.5% increase, and the lowest GHG emissions per liter of ethanol, a 9.1% decrease. Corn stover, due to its high ash content, had the lowest yields and the highest GHG emissions per liter of ethanol. The results were highly sensitive to the ash and water content of the biomass, indicating that biomass properties can significantly affect the environmental impact of the thermochemical ethanol conversion process. [ABSTRACT FROM AUTHOR]

Published
2013
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108. FUEL PROPERTIES AND SUITABILITY OF EUCALYPTUS BENTHAMII AND EUCALYPTUS MACARTHURII FOR TORREFIED WOOD AND PELLETS.

Author

Pirraglia, Adrian, Gonzalez, Ronalds, Saloni, Daniel, Wright, Jeff, and Denig, Joseph

Subjects
*FUELWOOD, *EUCALYPTUS, *WOOD pellets, *BIOMASS energy, *PLANT species, *PLANT growth, *CHEMICAL reduction
Abstract

Torrefaction is the process of heating a material in the absence of oxygen, a pretreatment that represents a promising option for biofuels. Two eucalyptus species harvested in South Carolina, E. benthamii and E. macarthurii, were processed in a torrefier, and wood pellets were manufactured. Eucalyptus represents a promising biomass source in southern U.S. due to fast growth rates and the availability of cold-tolerant plantations. Analyses of moisture content, proximate and elemental composition, and net heating value of "light roasted" wood were assessed. The heating value of the eucalypts and pellets was enhanced by 19% (average), compared to the original material, while the moisture and volatiles content were drastically reduced. This reduction leads to an increase in the amount (w/w) of carbon, enhancing the energy content in the material. Thus, torrefaction is useful for improving the heating value of woody biomass, consuming little external energy due to recirculation and burning of gases for the process. The pellets showed increased energy density, providing improved properties for transportation and handling. [ABSTRACT FROM AUTHOR]

Published
2012

109. AUTOHYDROLYSIS PRETREATMENT OF MIXED HARDWOODS TO EXTRACT VALUE PRIOR TO COMBUSTION.

Author

Yan Pu, Treasure, Trevor, Gonzalez, Ronalds, Venditti, Richard, and Jameel, Hasan

Subjects
HYDROLYSIS, HARDWOODS, COMBUSTION, SOLUBILITY, WOOD products, TEMPERATURE effect, EXTRACTION (Chemistry), FERMENTATION, MONOMERS
Abstract

Biomass pretreatment by autohydrolysis uses hot-water to extract soluble components from wood prior to converting the woody residuals into paper, wood products, or fuel, etc. Mixed hardwood chips were autohydrolyzed in hot-water at 150, 160, 170, and 180 ºC, for 1 and 2 h. The tradeoff between fermentable sugar yield and caloric value of the residual solids was studied for a process that will be referred to as "value prior to combustion". The extracted liquid was treated with dilute sulfuric acid to break down sugar oligomers into fermentable monomers. Material balances were performed around autohydrolysis to evaluate the role of temperature and residence time on sugar production and residual solid heating value. The composition (sugars and byproducts) of the extracted liquid was determined. As the autohydrolysis temperature increased, the material balance became less precise, presumably due to more volatile byproducts being formed that were not quantified. More hemicelluloses were extracted from the wood by the hot water extraction process under higher temperature and longer residence time, but a greater degree of sugar degradation was also observed. After hot-water extraction the heating value of the solid residues was higher than the original wood. The total energy content of the residual solid after extraction ranged from 74 to 95% of the original energy content of the feed. [ABSTRACT FROM AUTHOR]

Published
2011
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113. Relationship Value in the Hardwood Lumber Industry in U.S.

Author

Gonzalez, Ronalds W.

Subjects
marketing, hardwood, relationship
Abstract

This study explores the influence of relationship value in buyer’s decision making in the hardwood lumber industry in the U.S. Results indicate that purchase decisions of hardwood lumber buyers are very sensitive to product quality, relationship with buyer-supplier, overall service and price (presented in order of importance). The dimension of relationship is ranked before overall service and price but it is ranked after that product quality. This sequence indicates that relationship with supplier is important only after quality product standards have been achieved. Customer loyalty and commitment can be achieved in this price driven commodity industry. Customer loyalty and commitment are consequence of higher customer satisfaction, which in this study depends on the overall relationship value, dimension that is supported by: supplier know-how, product quality, personal interaction with supplier, and delivery performance/service. Suppliers in the hardwood lumber industry can use these findings to reinforce their relational marketing strategies. At the same time, managers need to pay more close attention and invest on these four attributes/variables to improve their buyer’s overall perception of value in their relationship. The information obtained in this study is useful at the time of assigning scarce resource in marketing programs to improve buyer’s perception. A combination of high standards in the delivery of product quality, overall service, relationship value and supplier performance result in a higher satisfaction and loyalty in business relationships with the supplier. Overall increase in perceived relationship value will most likely help improve the hardwood lumber buyer’s satisfaction with the supplier.

Published
2008

114. Transforming non-wood feedstocks into dissolving pulp via organosolv pulping: An alternative strategy to boost the share of natural fibers in the textile industry.

Author

Vera, Ramon E., Vivas, Keren A., Urdaneta, Fernando, Franco, Jorge, Sun, Runkun, Forfora, Naycari, Frazier, Ryen, Gongora, Stephanie, Saloni, Daniel, Fenn, Larissa, Zhu, J.Y., Chang, Hou-min, Jameel, Hasan, and Gonzalez, Ronalds

Subjects
*NATURAL fibers, *WHEAT straw, *SWITCHGRASS, *TEXTILE fiber industry, *TEXTILE fibers, *SYNTHETIC fibers, *TEXTILE industry
Abstract

This work evaluates wheat straw, switchgrass, and hemp hurd as potential alternatives for producing dissolving pulp using sulfur dioxide (SO 2)-ethanol-water (SEW) pulping. The SEW process is described in detail for wheat straw, and the best pulping conditions for this feedstock were 130 °C, 4 h, and 10% SO 2 concentration, comprised in a sulfur-ethanol-water ratio of 10-45-45. This resulted in a viscose-grade pulp with 93% α-cellulose, 2.0% hemicelluloses, <0.1% lignin, 0.2% ash content, and a viscosity of 4.7 cP. The best pulping conditions for wheat straw were applied to switchgrass and hemp hurd. Wheat straw and switchgrass had similar pulp quality, while hemp hurd pulp had a higher hemicellulose content and lower viscosity. This work suggests that non-wood feedstocks such as wheat straw and switchgrass can be promising alternatives for dissolving pulp production, which can help reduce the pressure on the textile industry to increase the use of natural fibers and mitigate the environmental impact of non-biodegradable synthetic fibers. [Display omitted] • Wheat straw, switchgrass, and hemp hurd were evaluated for dissolving pulp production. • Viscose-grade dissolving Pulp can be obtained from non-wood feedstocks. • SEW pulping can provide dissolving grade pulp. • Non-wood sources are a promising alternative for natural textile fibers. • Dissolving pulp quality changes based on the nature of the non-wood feedstock. [ABSTRACT FROM AUTHOR]

Published
2023
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115. Environmentally friendly oxidation pretreatments to produce sugar-based building blocks from dyed textile wastes via enzymatic hydrolysis.

Author

Vera, Ramon E., Zambrano, Franklin, Marquez, Ronald, Vivas, Keren A., Forfora, Naycari, Bedard, John, Farrell, Matthew, Ankeny, Mary, Pal, Lokendra, Jameel, Hasan, and Gonzalez, Ronalds

Subjects
*TEXTILE waste, *HYDROLYSIS, *COTTON fibers, *COTTON textiles, *CORN stover, *OXIDATION
Abstract

[Display omitted] • Enzymatic hydrolysis is a potential method to upcycle textile wastes. • Mechanical refining promotes high-yield enzymatic hydrolysis of textiles. • Dyes inhibit the enzymatic hydrolysis of textile wastes. • Chlorine-free oxidation removes dyes and whitens textiles with low chemical dosage. • Mechanical refining + oxidation processes boost enzyme conversion of dyed textiles. Given the increasing concern over textile waste management and the proliferation of textile landfills, enzymatic hydrolysis of cotton represents a potential pathway to upcycle textile waste into valuable chemical building blocks. However, this pathway is challenged by the presence of persistent dyes, hindering enzyme performance. To overcome this issue, environmentally friendly and total chlorine free oxidation methods such as ozone and alkaline hydrogen peroxide were used in combination with mechanical refining pretreatment. The results showed that the enzymatic conversion of black-dyed cotton, without oxidation, resulted in a glucose yield of only 60% as compared to 95% for undyed cotton fibers. On the other hand, the inclusion of oxidation processes in the pretreatment stage resulted in a glucose yield of 90% via enzymatic hydrolysis at expense of using low oxidation chemicals and low enzyme charges. This work highlights the potential of oxidation methods, enzymatic hydrolysis, and mechanical refining as an ecofriendly pathway for generating value-added chemicals from cotton textile waste while promoting economic circularity. [ABSTRACT FROM AUTHOR]

Published
2023
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116. Is sugarcane-based polyethylene a good alternative to fight climate change?

Author

Suarez, Antonio, Ford, Ericka, Venditti, Richard, Kelley, Stephen, Saloni, Daniel, and Gonzalez, Ronalds

Subjects
*ENVIRONMENTAL impact analysis, *POLYETHYLENE, *ENVIRONMENTAL indicators, *ECOLOGICAL impact, *BIODEGRADABLE plastics, *POLYETHYLENE oxide
Abstract

The need to decarbonize and reduce the impact of human activities is opening the window for new bioproducts. The industry of bioplastics has grown exponentially in the past years, and its production is expected to triple by 2026. Different bioplastics are currently produced, but bio-polyethylene constitute an interesting opportunity since its fossil counterpart is one of the most used materials worldwide, and its precursor, ethylene, is one of the highest contributors to GHG emissions in the chemical industry. The true environmental impact of this bio-based plastic remains under controversial discussions due to a wide distribution of environmental indicators values found in the literature for this material. We aim to thoroughly evaluate the environmental impact of bio-polyethylene made from sugarcane across the different production stages through a life cycle analysis. Our goal is also to assess unintended consequences (consequential effects) of producing it. It was determined that land-use change represents the main aspect affecting the environmental sustainability of bio-polyethylene. From an attributional point of view, this bioplastic could present lower carbon footprints than fossil polyethylene if no deforestation occurs. From a consequential standpoint, indirect deforestation as a response to producing more bioplastic could negatively impact the environmental profile of this material. Policies restricting deforestation are required to ensure that bio-polyethylene can constitute an alternative to reduce the carbon footprint of products in both scenarios. We expect this work to provide a robust evaluation to understand the environmental impact of bio-polyethylene, which will help the industry understand the place of this bio-based plastic and increase the offering of more sustainable products. • This study reports environmental impacts related to sugarcane-based polyethylene. • Land-use change highly influences the global warming potential of bio-polyethylene. • Bio-polyethylene can help fight climate change if no deforestation occurs. • Policies protecting forests are required to ensure benefits of bio-polyethylene. [ABSTRACT FROM AUTHOR]

Published
2023
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117. Global timber investments and trends, 2005-2011

Author

Cubbage, Frederick, Mac Donagh, Patricio, Balmelli, Gustavo, Morales Olmos, Virginia, Bussoni, Adriana, Rubilar, Rafael, De La Torre, Rafael, Lord, Roger, Huang, Jin, Afonso Hoeflich, Vitor, Murara, Mauro, Kanieski, Bruno, Hall, Peter, Yao, Richard, Adams, Paul, Kotze, Heyns, Monges, Elizabeth, Hernández Pérez, Carmelo, Wikle, Jeff, Abt, Robert, Gonzalez, Ronalds, and Carrero, Omar

118. Lignin self-assembly phenomena and valorization strategies for pulping, biorefining, and materials development: Part 1. The physical chemistry of lignin self-assembly.

Author

Trovagunta R, Marquez R, Tolosa L, Barrios N, Zambrano F, Suarez A, Pal L, Gonzalez R, and Hubbe MA

Abstract

Physical chemistry aspects are emphasized in this comprehensive review of self-assembly phenomena involving lignin in various forms. Attention to this topic is justified by the very high availability, low cost, and renewable nature of lignin, together with opportunities to manufacture diverse products, for instance, polymers/resins, bioplastics, carbon fibers, bio-asphalt, sunscreen components, hydrophobic layers, and microcapsules. The colloidal lignin material, nanoparticles, and microstructures that can be formed as a result of changes in solvent properties, pH, or other adjustments to a suspending medium have been shown to depend on many factors. Such factors are examined in this work based on the concepts of self-assembly, which can be defined as an organizing principle dependent on specific attributes of the starting entities themselves. As a means to promote such concepts and to facilitate further development of nano-scale lignin products, this article draws upon evidence from a wide range of studies. These include investigations of many different plant sources of lignin, processes of delignification, solvent systems, anti-solvent systems or other means of achieving phase separation, and diverse means of achieving colloidal stability (if desired) of resulting self-assembled lignin structures. Knowledge of the self-organization behavior of lignin can provide significant structural information to optimize the use of lignin in value-added applications. Examples include chemical conditions and preparation procedures in which lignin-related compounds of particles organize themselves as spheres, hollow spheres, surface-bound layers, and a variety of other structures. Published articles show that such processes can be influenced by the selection of lignin type, pulping or extraction processes, functional groups such as phenolic, carboxyl, and sulfonate, chemical derivatization reactions, solvent applications, aqueous conditions, and physical processes, such as agitation. Precipitation from non-aqueous solutions represents a key focus of lignin self-assembly research. The review also considers stabilization mechanisms of self-assembled lignin-related structures., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier B.V. All rights reserved.)

Published
2024
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119. Survivability of Salmonella Typhimurium (ATCC 14208) and Listeria innocua (ATCC 51742) on lignocellulosic materials for paper packaging.

Author

Zwilling JD, Whitham J, Zambrano F, Pifano A, Grunden A, Jameel H, Venditti R, and Gonzalez R

Abstract

Lignocellulosic materials are widely used for food packaging due to their renewable and biodegradable nature. However, their porous and absorptive properties can lead to the uptake and retention of bacteria during food processing, transportation, and storage, which pose a potential risk for outbreaks of foodborne disease. Thus, it is of great importance to understand how bacteria proliferate and survive on lignocellulosic surfaces. The aim of this research was to compare the growth and survivability of Salmonella Typhimurium and Listeria innocua on bleached and unbleached paper packaging materials. Two different paper materials were fabricated to simulate linerboard from fully bleached and unbleached market pulps and inoculated with each bacterium at high bacterial loads (10 7 CFU). The bacteria propagated during the first 48 h of incubation and persisted at very high levels (>10 7 CFU/cm 2 ) for 40 days for all paper and bacterium types. However, the unbleached paper allowed for a greater degree of bacterial growth to occur compared to bleached paper, suspected to be due to the more hydrophobic nature of the unbleached, lignin-containing fibers. Several other considerations may also alter the behavior of bacteria on lignocellulosic materials, such as storage conditions, nutrient availability, and chemical composition of the fibers., Competing Interests: The authors declare no competing interests., (© 2023 The Authors.)

Published
2023
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120. Microfiber shedding from nonwoven materials including wipes and meltblown nonwovens in air and water environments.

Author

Kwon S, Zambrano MC, Venditti RA, Frazier R, Zambrano F, Gonzalez RW, and Pawlak JJ

Subjects
Wastewater, Water, Textiles, Water Pollutants, Chemical analysis
Abstract

Nonwoven products are widely used in disposable products, such as wipes, diapers, and masks. Microfibers shed from these products in the aquatic and air environment have not been fully described. In the present study, 15 commercial single-use nonwoven products (wipes) and 16 meltblown nonwoven materials produced in a pilot plant were investigated regarding their microfiber generation in aquatic and air environments and compared to selected textile materials and paper tissue materials. Microfibers shed in water were studied using a Launder Ometer equipment (1-65 mg of microfibers per gram material), and microfibers shed in air were evaluated using a dusting testing machine that shakes a piece of the nonwoven back and forth (~ 4 mg of microfibers per gram material). The raw materials and bonding technologies affected the microfiber generation both in water and air conditions. When the commercial nonwovens contained less natural cellulosic fibers, less microfibers were generated. Bonding with hydroentangling and/or double bonding by two different bonding methods could improve the resistance to microfiber generation. Meltblown nonwoven fabrics generated fewer microfibers compared to the other commercial nonwovens studied here, and the manufacturing factors, such as DCD (die-to-collector distance) and air flow rate, affected the tendency of microfiber generation. The results suggest that it is possible to control the tendency of microfiber shedding through the choice of operating parameters during nonwoven manufacturing processes., (© 2022. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published
2022
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