| 1101 - 1102 |
Managing the transition decades: Tactical options for an uncertain route towards a clear strategic goal
Campbell GM, Azapagic A, Vadlani P |
| 1103 - 1119 |
Maximum fossil fuel feedstock replacement potential of petrochemicals via biorefineries
Brehmer B, Boom RM, Sanders J |
| 1120 - 1139 |
From petrochemical complexes to biorefineries? The past and prospective co-evolution of liquid fuels and chemicals production in the UK
Bennett SJ, Pearson PJG |
| 1140 - 1146 |
Relation of biofuel to bioelectricity and agriculture: Food security, fuel security, and reducing greenhouse emissions
Thomas VM, Choi DG, Luo D, Okwo A, Wang JH |
| 1147 - 1161 |
The biorefining opportunities in Wales: Understanding the scope for building a sustainable, biorenewable economy using plant biomass
Charlton A, Elias R, Fish S, Fowler P, Gallagher J |
| 1162 - 1170 |
A fuzzy multiple-objective approach to the optimization of bioenergy system footprints
Tan RR, Ballacillo JAB, Aviso KB, Culaba AB |
| 1171 - 1183 |
Biorefining: Computer aided tools for sustainable design and analysis of bioethanol production
Alvarado-Morales M, Terra J, Gernaey KV, Woodley JM, Gani R |
| 1184 - 1190 |
Optimal procurement and operational planning for risk management of an integrated biorefinery process
Yun C, Kim Y, Park J, Park S |
| 1191 - 1205 |
Integration of a small biofuel refinery in a rural context
Simone M, Bientinesi M, Nicolella C, Petarca L |
| 1206 - 1216 |
Production of bioethanol and other bio-based materials from sugarcane bagasse: Integration to conventional bioethanol production process
Dias MOS, Ensinas AV, Nebra SA, Maciel R, Rossell CEV, Maciel MRW |
| 1217 - 1231 |
Assessment of different strategies for the co-production of bioethanol and beet sugar
Krajnc D, Glavic P |
| 1232 - 1238 |
Evaluating the feasibility of commercial arabinoxylan production in the context of a wheat biorefinery principally producing ethanol. Part 1. Experimental studies of arabinoxylan extraction from wheat bran
Du C, Campbell GM, Misailidis N, Mateos-Salvador F, Sadhukhon J, Mustafa M, Weightman RM |
| 1239 - 1250 |
Evaluating the feasibility of commercial arabinoxylan production in the context of a wheat biorefinery principally producing ethanol Part 2. Process simulation and economic analysis
Misailidis N, Campbell GM, Du C, Sadhukhan J, Mustafa M, Mateos-Salvador F, Weightman RM |
| 1251 - 1260 |
Multiscale modelling of biomass pretreatment for biofuels production
Hosseini SA, Shah N |
| 1261 - 1268 |
Integrated biorefinery wastewater design
Ryan D, Gadd A, Kavanagh J, Barton GW |
| 1269 - 1275 |
Addressing the increased energy demand of a Kraft mill biorefinery: The hemicellulose extraction case
Marinova M, Mateos-Espejel E, Jemaa N, Paris J |
| 1276 - 1292 |
An integrated process to produce vanillin and lignin-based polyurethanes from Kraft lignin
da Silva EAB, Zabkova M, Araujo JD, Cateto CA, Barreiro MF, Belgacem MN, Rodriques AE |
| 1293 - 1317 |
A gasification-based biorefinery for the pulp and paper industry
Consonni S, Katofsky RE, Larson ED |
| 1318 - 1327 |
Process integration for the conversion of glucose to 2,5-furandicarboxylic acid
Boisen A, Christensen TB, Fu W, Gorbanev YY, Hansen TS, Jensen JS, Klitgaard SK, Pedersen S, Riisager A, Stahlberg T, Woodley JM |
| 1328 - 1339 |
Thermally integrated bio-syngas-production for biorefineries
Bludowsky T, Agar DW |
| 1340 - 1348 |
Economic assessment of an integrated bioethanol-biodiesel-microbial fuel cell facility utilizing yeast and photosynthetic algae
Powell EE, Hill GA |
