Nawa Raj Baral
Publications
Viewing 23 of 23 publications
2023
, , , , , and . "Solvent-Assisted Poly(lactic acid) Upcycling under Mild Conditions." ACS Sustainable Chemistry & Engineering 11.22 (2023) 8208–8216.
, , , , , , , , , , and . "Biorenewable and circular polydiketoenamine plastics." Nature Sustainability (2023).
, , , , and . "Machine learning for surrogate process models of bioproduction pathways." Bioresource Technology 370 (2023) 128528.
, , , , and . "Torrefaction of almond shell as a renewable reinforcing agent for plastics: techno-economic analyses and comparison to bioethanol process." Environmental Research: Infrastructure and Sustainability (2023).
, , , and . "Co-Processing Agricultural Residues and Wet Organic Waste Can Produce Lower-Cost Carbon-Negative Fuels and Bioplastics." Environmental Science & Technology (2023).
2021
, , , , , , and . "Production Cost and Carbon Footprint of Biomass-Derived Dimethylcyclooctane as a High-Performance Jet Fuel Blendstock." ACS Sustainable Chemistry & Engineering 9.35 (2021) 11872–11882.
, , , , , , , , , , and . "Alkanolamines as Dual Functional Solvents for Biomass Deconstruction and Bioenergy Production." Green Chemistry 23.21 (2021) 8611–8631.
, , , , and . "Identifying Forage Sorghum Ideotypes for Advanced Biorefineries." ACS Sustainable Chemistry & Engineering 9.23 (2021) 7873–7881.
, , , , , , , , and . "Use of ensiled biomass sorghum increases ionic liquid pretreatment efficiency and reduces biofuel production cost and carbon footprint." Green Chemistry (2021).
, , , , , , and . "Leveling the cost and carbon footprint of circular polymers that are chemically recycled to monomer." Science Advances 7.15 (2021) eabf0187.
, , , , , , , , , , , , , , , and . "High-Efficiency Conversion of Ionic Liquid-Pretreated Woody Biomass to Ethanol at the Pilot ScaleHigh-Efficiency Conversion of Ionic Liquid-Pretreated Woody Biomass to Ethanol at the Pilot Scale." ACS Sustainable Chemistry & Engineering 9.11 (2021) 4042–4053.
, , , , and . "Technoeconomic analysis for biofuels and bioproducts." Current Opinion in Biotechnology 67 (2021) 58–64.
2022
, , , , , , , and . "Comparing planta accumulation with microbial routes to set targets for a cost-competitive bioeconomy." Proceedings of the National Academy of Sciences 119.30 (2022).
, , , , , and . "Multifunctional landscapes for dedicated bioenergy crops lead to low-carbon market-competitive biofuels." Renewable and Sustainable Energy Reviews 169 (2022) 112857.
, , , , , , , and . "In Situ Synthesis of Protic Ionic Liquids for Biomass Pretreatment." ACS Sustainable Chemistry & Engineering 10.37 (2022) 12090–12098.
2020
, , , , and . "Cost and Life-Cycle Greenhouse Gas Implications of Integrating Biogas Upgrading and Carbon Capture Technologies in Cellulosic Biorefineries." Environmental Science & Technology 54.20 (2020) 12810–12819.
, , , , and . "Cost and Life-Cycle Greenhouse Gas Implications of Integrating Biogas and Upgrading Carbon Capture Technologies in Cellulosic Biorefineries." Environmental Science & Technology 54.20 (2020) 12810–12819.
, , , , and . "Supply Cost and Life-Cycle Greenhouse Gas Footprint of Dry and Ensiled Biomass Sorghum for Biofuel Production." ACS Sustainable Chem. Eng. (2020).
, , , , , and . "Accumulation of high-value bioproducts in planta can improve the economics of advanced biofuels." Proceedings of the National Academy of Sciences 117.15 (2020) 8639–8648.
2019
, , , , , , and . "Greenhouse Gas Footprint, Water-Intensity, and Production Cost of Bio-Based Isopentenol as a Renewable Transportation Fuel." ACS Sustainable Chem. Eng. (2019) 15434–15444.
, , , , , , and . "Greenhouse Gas Footprint, Water-Intensity, and Production Cost of Bio-Based Isopentenol as a Renewable Transportation Fuel." ACS Sustainable Chemistry & Engineering 7.18 (2019) 15434–15444.
, , , , , , and . "Techno-economic analysis and life-cycle greenhouse gas mitigation cost of five routes to bio-jet fuel blendstocks." Energy & Environmental Science 12.3 (2019) 807–824.
, , , , , , , , and . "Approaches for More Efficient Biological Conversion of Lignocellulosic Feedstocks to Biofuels and Bioproducts." ACS Sustainable Chemistry & Engineering 7.10 (2019) 9062–9079.