| publications-251 |
|
|
Nikitina, Elena |
Russiaās climate policy and the Kyoto ratification deal: Assessing the science-practice interface |
|
|
Uncategorized |
Uncategorized |
|
No abstract available |
226571 |
|
|
|
| publications-252 |
PEER REVIEWED ARTICLE |
2013 |
Lebel, Louis |
Institutional fit and river basin governance |
|
10.5751/es-05097-180101 |
Simulation & Modeling |
Uncategorized |
|
No abstract available |
226571 |
|
|
|
| publications-253 |
PEER REVIEWED ARTICLE |
2012 |
Pahl-Wostl, Claudia |
From applying panaceas to mastering complexity: Towards adaptive water governance in river basins |
|
10.1016/j.envsci.2012.07.014 |
Simulation & Modeling |
Uncategorized |
|
No abstract available |
226571 |
|
|
|
| publications-254 |
PEER REVIEWED ARTICLE |
2010 |
Weiss M, M Junginger, M.K. Patel, K Blok |
A review of experience curve analyses for energy demand technologies |
|
10.1016/j.techfore.2009.10.009 |
Data Management & Analytics |
Uncategorized |
|
No abstract available |
227078 |
|
|
|
| publications-255 |
PEER REVIEWED ARTICLE |
2010 |
Huijbregts MAJ, S Hellweg, R Frischknecht, HWM Hendriks, K Hungerbuhler, AJ Hendriks |
Cumulative Energy Demand As Predictor for the Environmental Burden of Commodity Production |
|
10.1021/es902870s |
Data Management & Analytics |
Uncategorized |
|
No abstract available |
227078 |
|
|
|
| publications-256 |
PEER REVIEWED ARTICLE |
2010 |
Michael Curran, L De Baan, AM De Schryver, R van Zelm, S Hellweg, T Koellner, G Sonneman, MAJ Huijbregts |
Toward Meaningful End Points of Biodiversity in Life Cycle Assessment |
|
10.1021/es101444k |
Simulation & Modeling |
Irrigation Systems |
|
No abstract available |
227078 |
|
|
|
| publications-257 |
PEER REVIEWED ARTICLE |
2011 |
Tobias Walser, Evangelia Demou, Daniel J. Lang, Stefanie Hellweg |
Prospective Environmental Life Cycle Assessment of NanosilverT-Shirts |
|
10.1021/es2001248 |
Simulation & Modeling |
Uncategorized |
|
No abstract available |
227078 |
|
|
|
| publications-258 |
PEER REVIEWED ARTICLE |
2011 |
De Schryver AM, Van Zelm R, Humbert S, Pfister S, McKone TE, MAJ Huijbregts |
Value choices in life cycle impact assessment of human health |
|
10.1111/j.1530-9290.2011.00371.x |
Uncategorized |
Uncategorized |
|
No abstract available |
227078 |
|
|
|
| publications-259 |
PEER REVIEWED ARTICLE |
2011 |
Pfister Stephan, P Bayer, A Koehler, S Hellweg |
Environmental Impacts of Water Use in Global Crop Production: Hotspots and Trade-Offs with Land Use |
|
10.1021/es1041755 |
Uncategorized |
Uncategorized |
|
No abstract available |
227078 |
|
|
|
| publications-260 |
PEER REVIEWED ARTICLE |
2011 |
De Meester, S., Callewaert, C., De Mol, E., Van Langenhove, H., Dewulf, J. |
The resource footprint of biobased products: a key issue in the sustainable development of biorefineries |
|
10.1002/bbb.304 |
Data Management & Analytics |
Uncategorized |
|
AbstractThe multifunctionality of bioresources is a major opportunity for the future; it offers the ability to replace fossilārelated market demands in a carbon neutral way. However, the switchover to a biobased economy faces two main challenges in comparison with the current fossilābased situation: biofeedstock requires an intensive cultivation step and furthermore there is a certain competition with the food chain which limits the amount of land available for new markets. So whilst biomass is seen as a ārenewableā resource, it is definitely not āgratuiteā, inducing the need of an efficient cultivation and valorization. In this paper, a case study is executed to highlight that biorefining feedstock into a wide range of products is a thermodynamically efficient (81.1%) way of processing all molecules of the bioresources for specific purposes in different segments of the market demand. On the other hand, it is demonstrated in the second part of the paper that replacing fossils requires a certain amount of inputs from the Earth's crust causing additional thermodynamic losses in the production chain (15.3% efficient), which are quantified based on the resource footprint of the Cumulative Exergy Extracted from the Natural Environment (CEENE) methodology. A scenario assessment demonstrates the resulting tradeoff between the carbon footprint of bioproducts and the land, water, and minerals footprint; in the case study executed, 27% fossil resources are saved at the cost of 93% extra land, water and mineral input from the natural environment. Ā© 2011 Society of Chemical Industry and John Wiley & Sons, Ltd |
227078 |
|
|
|
