Environmental Engineering Reference
In-Depth Information
110. Harvey, B.G., Wright, M.E. and Quintana, R.L. (2010) High-density renewable fuels based
on the selective dimerization of pinenes.
Energy and Fuels
,
24
, 267-273.
111. Meylemans, H.A., Quintana, R.L. and Harvey, B.G. (2012) Efficient conversion of pure
and mixed terpene feedstocks to high density fuels.
Fuel
,
97
, 560-568.
112. Swift, K.A.D. (2004) Catalytic transformations of the major terpene feedstocks.
Topics in
Catalysis
,
27
(1-4), 143-155.
113. Stanciulescu, M. and Ikura, M. (2007) Limonene ethers from tire pyrolysis oil - part 2:
continuous flow experiments.
Journal of Analytical and Applied Pyrolysis
,
78
(1),
76-84.
114. Stanciulescu, M. and Ikura, M. (2006) Limonene ethers from tire pyrolysis oil - part 1:
batch experiments.
Journal of Analytical and Applied Pyrolysis
,
75
(2), 217-225.
115. Sannita, E., Aliakbarian, B., Casazza, A.A.
et al.
(2012) Medium-temperature conversion
of biomass and wastes into liquid products, a review.
Renewable and Sustainable Energy
Reviews
,
16
(8), 6455-6475.
116. de Jong, E., Higson, A., Walsh, P. and Wellisch, M. (2011)
Bio-Based Chemicals: Value
Added Products From Biorefineries
, IEA Bioenergy.Task 42 Biorefinery, Wageningen,
Netherlands.
117. Sheldrake, G.N. and Schleck, D. (2007) Dicationic molten salts (ionic liquids) as re-usable
media for the controlled pyrolysis of cellulose to anhydrosugars.
Green Chemistry
,
9
(10),
1044-1046.
118. Long, J.X., Guo, B., Li, X.H.
et al.
(2011) One step catalytic conversion of cellulose to
sustainable chemicals utilizing cooperative ionic liquid pairs.
Green Chemistry
,
13
(9),
2334-2338.
119. Jang, Y.S., Kim, B., Shin, J.H.
et al.
(2012) Bio-based production of C2-C6 platform
chemicals.
Biotechnology and Bioengineering
,
109
(10), 2437-2459.
120. Fenouillot, F., Rousseau, A., Colomines, G.
et al.
(2010) Polymers from renewable
1,4:3,6-dianhydrohexitols (isosorbide, isomannide and isoidide): a review.
Progress in
Polymer Science
,
35
(5), 578-622.
121. Mascal, M. and Nikitin, E.B. (2010) High-yield conversion of plant biomass into the key
value-added feedstocks 5-(hydroxymethyl)furfural, levulinic acid, and levulinic esters via
5-(chloromethyl)furfural.
Green Chemistry
,
12
(3), 370-373.
122. Xiao, Z.J., Wang, X.M., Huang, Y.L.
et al.
(2012) Thermophilic fermentation of acetoin
and 2,3-butanediol by a novel geobacillus strain.
Biotechnology for Biofuels
,
5
, 88.
123. Gao, C., Zhang, L.J., Xie, Y.J.
et al.
(2013) Production of (3S)-acetoin from diacetyl by
using stereoselective NADPH-dependent carbonyl reductase and glucose dehydrogenase.
Bioresource Technology
,
137
, 111-115.
124. Curran, K.A., Leavitt, J., Karim, A. and Alper, H.S. (2013) Metabolic engineering of
muconic acid production in Saccharomyces cerevisiae.
Metabolic Engineering
,
15
,
55-66.
125. Frost, J.W., Miermont, A., Draths Corporation, Schweitzer, D. and Bui, V. (2010)
Preparation of trans,trans muconic acid and trans,trans muconates, Patent No. WO
2010/148049 A2.
126. Wright, M.M. and Brown, R.C. (2007) Comparative economics of biorefineries based on
the biochemical and thermochemical platforms.
Biofuels, Bioproducts and Biorefining-
Biofpr
,
1
(1), 49-56.
127. Cheiky, M., Sills, R.A. and Jarand, M.L. (2012) Method for enhancing soil growth using
bio-char, Cool Planet Biofuels Inc., US Patent 8,236,085.
