Page 51 - Biofuels for a More Sustainable Future

P. 51

Biofuel transitions 45

Luthra, S., Kumar, S., et al., 2015. Barriers to renewable/sustainable energy technologies
adoption: Indian perspective. Renew. Sust. Energ. Rev. 41, 762–776.
Malik, A., Lan, J., Lenzen, M., 2016. Trends in global greenhouse gas emissions from 1990 to
2010. Environ. Sci. Technol. 50 (9), 4722–4730.
Melillo, J., Reilly, J., Kickligher, D., Gurgel, A., Cronin, T., Paltsev, S., Felzer, B.,
Wang, X., Sokolov, A., Schlosser, C.A., 2009. Indirect emissions from biofuels: how
important? Science 326, 1397–1399.
Moioli, E., Salvati, F., Chiesa, M., Siecha, R.T., Manenti, F., Laio, F., Rulli, M.C., 2018.
Analysis of the current world biofuel production under a water–food–energy nexus per-
spective. Adv. Water Resour. 121, 22–31.
Morone, P., Cottoni, L., 2016. Transition to a sustainable agro-food system: the role of inno-
vation policies. In: Galanakis, C.M. (Ed.), Innovation Strategies in the Food Industry:
Tools for Implementation. Elsevier Inc., pp. 61–76
Mosnier, A., Havlik, P., Valin, H., Baker, J., Murray, B., Feng, S., Obersteiner, M.,
McCarl, B., Rose, S., Schneider, U., 2013. The net global effects of alternative U.S. bio-
fuel mandates: fossil fuel displacement, indirect land use change, and the role of agricul-
tural productivity growth. Energy Policy vol. 57. 602–614.
Murali, P., Hari, K., Puthira Prathap, D., 2016. An economic analysis of biofuel production
and food security in India. Sugar Tech 18 (5), 447–456.
National Research Council (NRC), 2011. Committee on Economic and Environmental
Impacts of Increasing Biofuels Production, Renewable Fuel Standard: Potential Eco-
nomic and Environmental Effects of U.S. Biofuel Policy. The National Academies Press,
Washington, DC.
O’Neill, D.W., Fanning, A.L., Lamb, W.F., Steinberger, J.K., 2018. A good life for all within
planetary boundaries. Nat. Sustain. 1, 88–95.
Obidzinski, K., Andriani, R., Komarudin, H., Andrianto, A., 2012. Environmental and
social impacts of oil palm plantations and their implications for biofuel production in
Indonesia. Ecol. Soc. 17(1).
Paris, A., 2018. On the link between oil and agricultural commodity prices: do biofuels mat-
ter? Int. Econ. 155, 48–60.
Pfau, S.F., Hagens, J.E., Dankbaar, B., Smits, A.J.M., 2014. Visions of sustainability in bioec-
onomy research. Sustainability 6, 1222–1249.
Purohit, P., Dhar, S., 2018. Lignocellulosic biofuels in India: current perspectives, potential
issues and future prospects. AIMS Energ. 6 (3), 453–486.
Raftery, A.E., Zimmer, A., Frierson, D.M.W., Startz, R., Liu, P., 2017. Less than 2°C
warming by 2100 unlikely. Nat. Clim. Chang. 7, 637–641.
Raman, S., Mohr, A., Helliwell, R., Ribeiro, B., Shortall, O., Smith, R., Millar, K., 2015.
Integrating social and value dimensions into sustainability assessment of lignocellulosic
biofuels. Biomass Bioenergy 82, 49–62.
Rutherford, A.P., 2016. Regulatory framework for biofuels in Brazil: history and challenges
under the law of the WTO. J. Energ. Nat. Resour. Law 34 (2), 213–238.
Searchinger, T., Heimlich, R., Houghton, R.A., Dong, F., Elobeid, A., Fabiosa, J.,
Tokgoz, S., Hayes, D., Yu, T.H., 2008. Use of US croplands for biofuels increases green-
house gases through emissions from land-use change. Science 319, 1238–1240.
Shove, E., Pantzar, M., Watson, M., 2012. The Dynamics of Social Practice. Everyday Life
and How It Changes? Sage, London.
STAR-ProBio, 2018. STAR-ProBio Deliverable D9.1, Comprehensive Overview of Exist-
ing Regulatory and Voluntary Frameworks on Sustainability Assessment. Available at:
www.star-probio.eu.
Stokes, L.C., Breetz, H.L., 2018. Politics in the U.S. energy transition: case studies of solar,
wind, biofuels and electric vehicles policy. Energy Policy 113, 76–86.
Thompson, W., Johansson, R., Meyer, S., Whistance, J., 2018. The US biofuel mandate as a
substitute for carbon and trade. Energy Policy 113, 368–375.

46 47 48 49 50 51 52 53 54 55 56