Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
about
Agave as a model CAM crop system for a warming and drying worldLight to liquid fuel: theoretical and realized energy conversion efficiency of plants using crassulacean acid metabolism (CAM) in arid conditionsDevelopment and use of bioenergy feedstocks for semi-arid and arid landsBioenergy and African transformation.A roadmap for research on crassulacean acid metabolism (CAM) to enhance sustainable food and bioenergy production in a hotter, drier world.Nocturnal versus diurnal CO2 uptake: how flexible is Agave angustifolia?Development of Agave as a dedicated biomass source: production of biofuels from whole plantsToward systems-level analysis of agricultural production from crassulacean acid metabolism (CAM): scaling from cell to commercial production.Chemicals from Agave sisalana biomass: isolation and identification.Informing the improvement and biodesign of crassulacean acid metabolism via system dynamics modelling.A system dynamics model integrating physiology and biochemical regulation predicts extent of crassulacean acid metabolism (CAM) phases.Conversion of lignocellulosic agave residues into liquid biofuels using an AFEX™-based biorefinery.Life cycle energy and greenhouse gas analysis for algae-derived biodieselThe potential of CAM crops as a globally significant bioenergy resource: moving from ‘fuel or food’ to ‘fuel and more food’Fuzzy GIS-based multi-criteria evaluation for USAgaveproduction as a bioenergy feedstockLife-Cycle Energy Use and Greenhouse Gas Emissions Analysis for Bio-Liquid Jet Fuel from Open Pond-Based Micro-Algae under China Conditions
P2860
Q26781230-D0C3F797-9122-43F6-BC16-1733B685054AQ26858931-66FB403D-DD35-4DE9-880D-56B3D3ADAAF6Q27014038-5B731180-EAAC-440B-A500-DC4F8C94BDEAQ28649570-B0FE0FF7-CCE2-49EF-BB74-E1B865D97D0AQ30979179-619000CD-DF60-41DE-A560-FF5C0992475CQ35125529-68E7DF45-DAA8-4DA9-9181-441FEEA38458Q35694603-35E47670-9F03-46C6-B9EB-31EBF37CD130Q38533294-CA9B041F-C48A-4A30-8A45-0A9F81FE19DDQ40458768-92C9DD73-8781-4163-8316-0DC7C75928EEQ43600016-61CD2C29-28EC-4B16-888A-561C9AAA3CD1Q45353961-483A1FDE-EF77-4B58-A097-042B86B078B8Q48162268-B08C96CC-3C59-4531-AA0F-0DC717E19FF7Q56522464-AA4B98E6-B5B0-47BC-B27D-8AA0DA5F6AD8Q56656179-3576B7D1-AFC3-4A7C-9F04-D323603F5A9FQ58110650-98D0282C-55BE-4B19-B0BE-B4671EFF0D52Q58201258-FED483B5-AF71-40C7-86DC-D7E72E1404BB
P2860
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
description
article
@en
im Januar 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2011
@uk
ലേഖനം
@ml
name
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@en
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@nl
type
label
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@en
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@nl
prefLabel
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@en
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@nl
P2093
P2860
P356
P1476
Life cycle energy and greenhouse gas analysis for agave-derived bioethanol
@en
P2093
Daniel K. Y. Tan
David A. King
J. A. C. Smith
Oliver R. Inderwildi
P2860
P356
10.1039/C1EE01107C
P50
P577
2011-01-01T00:00:00Z