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REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 161
REFERENCES
1. Abbi, M., Kuhad, R.C., and Singh, A., (1996). Bioconversion of pentose sugar
to ethanol by free and immobilized cells of Candida shehatae NCL-3501:
fermentation behavior. Process Biochem. 31: 555-560.
2. Agblevor, F.A., Batz, S., and Trumbo, J., (2003). Composition and ethanol
production potential of cotton gin residues. Appl Biochem Biotechnol. 105:
219-230.
3. Agarwal, A.K., (2007). Biofuels (alcohols and biodiesel) applications as fuels
for internal combustion engines. Prog Energ Combust. 33(3): 7-13.
4. Agbogbo, F., and Wenger, K., (2006). Effect of pretreatment chemicals on
xylose fermentation by Pichia stipites. Biotechnol Lett. 28: 2065-2069.
5. AIDA, (2006). All India Distilleries Association. www.aidaindia.org
6. Aithal, S.C., (2001). Studies on utilization of blackened sorghum for
production of ethanol. Ph.D. Thesis. Swami Ramanand Teerth Marathwada
University, Nanded.
7. Alfenore, S., Cameleyre, X., Benbadis, L., Bideaux, C., Uribelarrea, J.L.,
Gooma, G., Molina-Jouve, C., and Guillouet, S.E., (2004). Aeration strategy:
A need for very high ethanol performance in Saccharomyces cerevisiae fed-
batch process. Appl Microbiol Biotechnol. 63: 537-542.
8. Alizadeh, H., Teymouri, F., Gilbert, T. I., and Dale, B.E., (2005). Pretreatment
of switch grass by Ammonia Fiber Explosion (AFEX). Appl Biochem
Biotechnol. 121-124: 1133-1142.
9. Angelova, M., and Petricheva, E., (1997). Glucose and nitrogen dependence
acid proteinase production in semi-continuous culture with immobilized cells
of Humicola lutea. J Biotechnol. 58: 51-58.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 162
10. Anonymous, (2012). Chemical and physical characteristic of ethanol and
hydrocarbon fuels, Module 2, p 5-6. http://www.ethanolrfa.org/page/-/rfa-
association-site/pdf/module2.pdf
11. Anonymous, (2013). Effect of inoculum size on growth span. Percell
Biolytica, application note 109. www.percell.se/109.pdf
12. AOAC, (1990). Official methods of analysis, Ed. 12. Association of Official
Analytical Chemist, Washington DC.
13. Arm, G., and Demirbas, A., (2004). Mathematical modeling the relations of
pyrolytic products from lignocellulosic material. Energ source. 26: 1023-
1032.
14. Asaduzzaman, MD., (2007). Standardization of yeast growth curves from
several curves with different initial size. Master’s Thesis. Department of
mathematical sciences, Chalmers University of technology and Goteborg
University SE, Goteborg, Sweden.
15. Badger, P.C., (2002). Ethanol from cellulose: a general review. In: Janick J,
Whipkey A, editors. Trends in new crops and new uses. Alexandria, VA:
ASHS Press. 17-21.
16. Bajaj, B.K., Yousuf, S., and Thakur, R.L., (2001). Selection and
characterization of yeasts for desirable fermentation characteristics. Ind J
Microbiol. 41: 107-110.
17. Bakers, M., Laukevics, J., Karsakevich, A., Ventina, E., Kaminska, E., Upite,
D., Vina, I., Linde, R., and Scherbaka, R., (2001). Levan-ethanol biosynthesis
using Zymomonas mobilis cells immobilized by attachment and entrapment.
Process Biochem. 36: 979-986.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 163
18. Bakoyianis, V.,Kanellaki, M.,Kalliafas, A., and Koutinas, A.A., (1992). Low
temperature wine-making by immobilized cells on mineral kissiris. J Agric
Food Chem. 40: 1293-1296.
19. Balat, M., (2007). Global biofuel processing and production trends. Energy
Explore Exploit. 25: 195-218.
20. Balat, M., Balat, H., and Oz, C., (2008). Progress in bioethanol processing.
Prog Energ Combust. 34: 551-573.
21. Balat, M., and Balat, H., (2009). Recent trends in global production and
utilization of bioethanol fuel. Appl Energy. 86: 2273-2282.
22. Baminger, U., Subramaniam, S. S., Renganathan, V., and Haltrich, D., (2001).
Characterization of cellobiose dehydrogenase from the plant pathogen
Sclerotium (Athelia) rolfsii. Appl Environ Microbiol. 67 (4): 1766–1774.
23. Baptista, C.M.S.G., Colas, J.M.A., Oliveira, A.C.M., Oliveira, N.M.C., Roche,
J.M.C., Dempsey, M.J., Lannigan, K.C., and Benson, P.S., (2006). Natural
immobilization of microorganism for continuous ethanol production. Enzyme
Microb Technol. 40: 127-131.
24. Behera, S., Kar, S., Mohanty, R.C., and Ray, R.C., (2010). Comparative study
of bioethanol production from mahula (Madhuca latifolia L.) flowers by
Saccharomyces cerevisiae cells immobilized in agar agar and Ca-alginate
matrices. Appl Energy. 87:96-100.
25. Bertilsson, M., (2007). Simultaneous saccharification and fermentation of
sprucc-a comparison of pretreatment condition and different enzyme
preparations. Master Thesis. Department of Chemical Engineering, Lund
University, Sweden.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 164
26. Bezbradica, D., Obradovic, B.,Leskosek-Cukalovic, I., Bugarski, B., and
Nedovic, V., (2007). Immobilization of yeast cell in PVA particles for beer
fermentation. Process Biochem.42: 1338-1351.
27. Bharadwaj, A., Tongia R., and Arunachalam, V.S., (2007). Scoping
technology options for India’s oil security: part I- ethanol for petrol. Curr Sci.
92(8): 1071-1077.
28. Bholmann, G.M., (2006). Process economic considerations for production of
ethanol from biomass feedstocks. Ind Biotechnol. 2: 14-20.
29. Binod, P., kuttiraja, M., Archana, M., Janu, K.U., Sindhu, R., Sukumaran,
R.K., and Pandey, A., (2012). High temperature pre-treatment and hydrolysis
of cotton stalk for producing sugars for bioethanol production. Fuel. 92: 340-
345.
30. Binod, P., Sindhu, R., Singhania, R.R., Vikram, S., Devi, L., Nagalaxmi, S.,
Kurien, N., Sukumaran, R.K., and Pandey, A., (2010). Bioethanol production
from rice straw: an overview. Bioresour Technol. 101: 4767-4774.
31. Boudet, A.M., Kajita, S., Grima-Pettenati, J., and Goffner, D., (2003). Lignin
and lignocellulosic: a better control of synthesis for new and improved uses.
Trends Plant Sci. 8(12): 576-581.
32. Brandberg, T., (2005). Fermentation of undetoxified dilute acid
lignocelluloses hydrolyzates for fuel ethanol production. PhD Thesis.
Chalmers University of technology
33. Bregmeyer, H.U., Gawehn, K., and Grassl, M., (1974). Methods of enzymatic
analysis (Bregmeyer, H.U., ed) academic press Inc., New York. Volume one,
second edition, 457-458.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 165
34. Brett, C.T., and Waldron, K.W., (1996). Physiology and biochemistry and
plant cell walls (2nd
Edition). London: Chapman and Hall.
35. Bridgeman, T.G., Darvell, J.J., Jones, J.M., Williams, P.T., Fahmi, R.,
Bridgwater, A.V., Barraclough, T., Shield, I., Yates, N., Thain, S.C., and
Donnison, I.S., (2007). Influence of particle size on the analytical and
chemical properties of two energy crops. Fuel. 86(1-2): 60-72.
36. Browning, B.L., (1967). Methods of wood chemistry. Wiley-Interscience,
New york, 75-269.
37. Bulawayo, B., Brochora, J.M., Muzondom, M.I., and Zuauya, R., (1996).
Ethanol production by fermentation of sweet-sorghum juice suing various
yeast strains. World J Microbiol Biotechnol. 12: 357-360.
38. Bvochora, J.M., Read, J.S., and Zvauya, R., (2000). Application of very high
gravity technology to the co-fermentation of sweet stem sorghum juice and
sorghum grain. Ind Crop Prod. 11: 11-17.
39. Cadenas, A., and Cabezudo, S., (1998). Biofuels as sustainable technologies:
prospective for less developed countries. Technol Forecast Social Change. 58:
83-103.
40. Canilha, L., Carvalho, W., Felipe, M.G.A., and Silva, J.B.A., (2008). Xylitol
production from wheat straw hemicellulose hydrolyzate: hydrolyzate
detoxification and carbonsource used for inoculum preparation. Brazillian J
Microbiol. 39: 333-336.
41. Carcieri, S., Clardy, E., and Zahid, N.S., (2010). Analyzing the ability of
modified yeast to ferment xylose to ethanol. Project report, Worcester
Polytechnic Institute (WPI), April, 27.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 166
42. Cardona, C.A., and Sanchez, O.J., (2007). Fuel ethanol production: process
design trends and integration opportunities. Bioresour Technol. 98: 2415-
2457.
43. Carrott, S., and Carrott, M., (2007). Lignin – from natural adsorbent to
activated carbon: a review. Bioresour Technol. 98: 2301-2312.
44. Carvalho, W., Silva, S.S., Converti, A., Viltolo, M., Felipe, M.G.A., Roberto,
I.C., Silva, M.B., and Manciha, I.M., (2002). Use of immobilized Candida
yeast cells for xylitol production from sugarcane bagasse hydrolyzate. Appl
Biochem Biotechnol. 98-100:489-496.
45. Chandel, A.K., Chen, E.C., Rudravaram, R., Narasu, M.L., Rao, L.V., and
Ravindra, P., (2007a). Economics and environmental impact of bioethanol
production technologies: an appraisal. Biotechnol Mol Biol Rev. 2: 14-32.
46. Chandel, A.K., Kapoor, R;K.,Singh, A., and Kuhad, R.C., (2007b).
Detoxification of sugarcane bagasse hydrolyzate improves ethanol production
by Candida shehatae NCIM 3501. Bioresour Technol. 98: 1947-1950.
47. Chandel, A.K, Narasu, A.K., Rudravaram, R., Pogaku, R., and Rao, L.V.,
(2009a). Bioconversion of De-Oiled Rice Bran (DORB) hemi cellulosic
hydrolyzate into ethanol by Pichiastipites NCM3499 under optimized
condition. Int Jfood Eng. 5(1): 1-12.
48. Chandel, A.K., Narasu, M.L., Chandrashekhar, G., Manikyam, A., and Rao,
L.V., (2009b). Use of Saccharum spontaneum (wild sugarcane) as biomaterial
for cell immobilization and modulated ethanol production by thermo tolerant
Saccharomycescerevisiae VS3. Bioresour Technol. 100 (8): 2404-2410.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 167
49. Chandel, A.K., Chandrashekhar, G., Radhika, K., Ravinder, R., and Ravindra,
P., (2011). Bioconversion of pentose sugars into ethanol: A review and future
directions. BiotechnolMol Biol Rev. 6(1): 008-020.
50. Chang, V.S., and Holtzapple, M., (2000). Fundamental factor affecting
biomass enzymatic reactivity. Appl Biochem Biotechnol. 84-86(1-9): 5-37
51. Chang, V.S., Nagwani, M., and Holtzapple, M.T., (1998). Lime pretreatment
of crop residues bagasse and wheat straw. Appl Biochem Biotechnol. 74(3):
135-159.
52. Chatwal, G.R., and Anand, S.K., (2005). Instrumental methods of chemical
analysis. Himalaya Publication House.
53. Chaudhary, N., and Qazi, J.I., (2011). Lignocellulose for ethanol production:
A review of issues relating to bagasse as a source material. Afr J Biotechnol.
10(8): 1270-1274.
54. Chen, S.L., and Gutmanis, F., (1976). Carbon dioxide inhibition of yeast
growth in biomass production. Biotech Bioeng. 18(10): 1455-1462.
55. Chen, Y., Sharma-Shivappa, R.R., and Chen, C., (2007). Ensiling agricultural
residues for bioethanol production. Appl Biochem Biotechnol. 143(1): 80-92.
56. Choinowski, T.,Blodig, W.,Winterhalter, K.H., and Piontek, K., (1999). The
crystal structure of lignin peroxidase at 1.70 angstrom resolution reveals
hydroxy group on the C-beta of tryptophan 171: a novel radical site formed
during the redox cycle. J Mol Biol. 286: 809-827.
57. Converti, A., Perego, P., Dominguez, J.M., and Silva, S.S., (2001). Effect of
temperature on the microaerophilic metabolism of Pachysolentannophilus.
Enz Micro Technol. 28: 339-345.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 168
58. Cysewski, G.R., and Wilke, C.R., (1967). Utilization of cellulosic materials
through enzymatic hydrolysis. I. Fermentation of hydrolyzate to ethanol and
single cell protein. Biotechnol Bioeng. 18: 1297-1313.
59. Dale, B.E., Henk, L.L., and Shiang, M., (1985). Fermentation of
lignocellulosic materials treated by ammonia freeze explosion. Dev Ind
Microbiol. 26: 223-233.
60. Dale, B.E., Leong, C.K., Pham, T.K., Esquivel, V.M., Rios, I., and Latimer,
V.M., (1996). Hydrolysis of lignocellulosic at low enzyme levels: application
of the AFEX process. Bioresour Technol. 56: 111-116.
61. Damasco, M.C.T., de Castro, A.M., Castro, R.M., Andrade, C., and Pereira,
N., (2004). Application of xylanase from Thermomyceslanuginosus IOC-4145
for enzymatic hydrolysis of corncob and sugarcane bagasse. Appl Biochem
Biotechnol. 113-116: 1003-1012.
62. David, T.W., (1994). Determination of ethanol concentration in biomass to
ethanol fermentation supernatant by Gas Chromatography. NREL, LAP-011.
63. Davis, T.A., Volesky, B., and Mucci, A., (2003). A review of the biochemistry
heavy metal bio sorption by brown algae. Water Res. 37:4311-30.
64. Dehkhoda, A., (2008). Concentrating lignocellulosic hydrolyzate by
evaporation and its fermentation by repeated fed-batch using flocculating
Saccharomyces cerevisiae. Master’s Thesis, University College of Boras,
Sweden.
65. Demirbas, A., (2005a). Bioethanol from cellulosic material: a renewable
motor fuel from biomass. Energ Source.Part A. 27(8): 327-337.
66. Demirbas, A., (2005b). Estimating of structural composition of wood and non-
wood biomass samples. Energ Source. 27(8): 761-767.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 169
67. Demirbas, A., (2007a). Progress and recent trends in biofuels. Prog Energy
Combus Sci. 33: 1-18.
68. Demirbas, A., (2007b). Producing and using bioethanol as an automotive fuel.
Energ Source. Part B-Economics planning and policy. 2(4): 391-401.
69. Demirbas, A., (2008). The importance of bioethanol and biodiesel form
biomass. Energ Source. Part B. 3: 177-185.
70. Derkacheva, O., and Sukhov, D., (2008). Investigation of lignin by FTIR
spectroscopy. Macromol Symp. 265: 61-8.
71. de Vries, R.P., and Visser, J., (2001). Aspergillus enzymes involved in
degradation of plant cell wall polysaccharides. Microbiol Mol Biol Rev. 65(4):
497-522.
72. de Vries, R.P., (2003). Regulation of Aspergillus genes encoding plant cell
wall polysaccharide degrading enzymes, relevance for industrial production.
Appl Micrbiol Biotechnol. 61: 10-20.
73. Diaz-Villanueva, M.J., Cara-Corpas, C., Ruiz-Ramos, E., Romero-Pulido, I.,
and Castro-Galiano, E., (2012). Olive tree pruning as an agricultural residue
for ethanol production. Fermentation of hydrolyzates from dilute acid
pretreatment. Span J Agric Res. 10(3): 643-648.
74. Dien, B.S., Iten, L.B., and Bothast, R.J., (1999). Conversion of corn fiber to
ethanol by recombinant E.coli strain FBR3. J Ind Microbiol. 22: 575-581.
75. Dien, B.S., Cotta, M.A., and Jeffries, T.W., (2003). Bacteria engineered for
fuel ethanol production: current status. Appl Microbiol Biotechnol. 63: 258-
266.
76. Dien, B.S., Li, X.L., Iten, L.B., Jordan, D.B., Nichols, N.N., O’Bryan, P.J.,
and Cotta, M.A., (2006). Enzymatic saccharification of hot-water pretreated
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 170
corn fiber for production of monosaccharaides. Enzyme Microb Technol. 39:
1137-1144.
77. Dipardo J., (2000). Outlook for biomass ethanol production and demand.
Energy information administration (EIA), Washington, DC;
[http://www.ethanol-gec.org/information/briefing/6.]
78. Du Preez, J.C., (1994). Process parameters and environmental factors affecting
D-xylose fermentation by yeasts. Enzyme Microb Technol. 16(11): 944-956.
79. Edgerton, M. D., (2009). Increasing crop productivity to meet global needs for
feed, food, and fuel. Plant Physiol. 149: 7-13.
80. Ehrman, T., (1994). Method for determination of total solids in biomass.
Laboratory analytical procedure no. 001. Golden, CO: National Renewable
Energy Laboratory.
81. EL- Abyad, M. S., EL-Refai A.H., EL-Diwany, A. L. Sallam, L. A. and
Allam, R. F., (1992). Effect of some fermentation parameter on ethanol
production form beet molasses by Saccharomyces cerevisiae Y-7. Bioresour
Technol 42 (3): 191-195.
82. EL-Refai A.H., EL- Abyad, M. S., EL-Diwany, A. L. Sallam, L. A. and
Allam, R. F., (1992). Some physiological parameter for ethanol production
from beet molasses by Saccharomyces cerevisiae Y-7. Bioresour Technol 56:
183-189.
83. Esteghlalian, A., Hashimoto, A. G., Fenske, J.J., and Penner, M.H., (1996).
Modeling and optimization of the dilute-sulfuric acid pretreatment of corn
stover, poplar and switchgrass. Bioresour Technol. 59: 129-136.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 171
84. European Commission, (EC). (2008). Proposal for a directive of the European
Parliament and of the Council on the promotion of use of energy from
renewable sources. Brussels. January 2008.
85. Fan, L.T., Gharpuray, M.M., and Lee, Y.H., (1987). In: Cellulose hydrolysis
Biotechnology Monographs. Springer, Berlin, p. 57
86. Farmakis, L., Kapolos, J., Koliadima, A., and Karaiskakis, G., (2007). Study
of the growth rate of Saccharomycescerevisiae strains using wheat starch
granules as support for yeast immobilization monitoring by
sedimentation/steric field-flow fractionation. Food Res. Int. 40: 717-24.
87. Farooqi, R., and Sam, A.G., (2004). Ethanol as transportation fuel. Centre for
Applied Business Research in Energy and the Environment (CABREE),
climate Chang Initiative. University of Alberta, Canada. [
www.business.ualberta.ca/cabree]
88. Freer, S.N., Skory, C.D., and Bothast, R.J., (1997). D-xylose metabolism in
Rhodosporidiumtoruloides. Biotechnol Lett. 19(11): 1119-1122.
89. Gaber, Z.B., (2010). Production of 16% ethanol from 35% sucrose. Biomass
Bioenerg. 34(8): 1243-1249.
90. Ge, J.P, Cai, B.Y., Liu,G.M., Ling,H.Z., Fang,B.Z., Song, G., Yang,X.F., and
Ping,W.X., (2011). Comparison of different detoxification methods for corn
cob hemicellulose hydrolyzates to improve ethanol production by Candida
shehatae ACCC 20335. Afr J Microbiol Res. 5(10): 1163-1168.
91. Goksungur, Y., and Zorlu, N., (2001). Production of ethanol from beet
molasses by Ca-Alginate immobilized yeast cells in a packed bed bioreactor.
Turk J Boil. 25: 265-275.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 172
92. Gollapalli, L.E., Dale, B.E., and Rivers, D.M., (2002). Predicting digestibility
of ammonia fiber explosion (AFEX)-treated rice straw. Appl Biochem
Biotechnol. 98-100: 23-35.
93. Gopal Reddy, M., Reddy, M.N., Saigopal, DVR and Mallaiah, K.V., (2008).
Laboratory experiments in microbiology.Third edition. Himalaya Publishing
House, Mumbai.
94. Graf, A., and Koehler, T., (2000). Oregon cellulose-ethanol study: an
evaluation of the potential for ethanol production in Oregon using cellulosic
based feedstocks. Salem, Oregon, USA: Oregon Dept. of Energy; June 96 , [
www.ethanol-gec.org/information/briefing/20a]
95. Gray, K. A., Zhao, L., and Emptage, M., (2006). Bioethanol. Curr Opin Chem
Biol. 10: 141-146.
96. Grzenia, D.L., Schell, D.J., and Wickramsinghe, S.R., (2010). Detoxification
of biomass hydrolyzates by reactive membrane extraction. J Membr Sci. 348:
6-12.
97. Guhagarkar, S.J., (1997). Cotton stalk for commercial production of glucose.
TASAE. 40(1): 169-171.
98. Gupta, R., Sharma, K.K., and Kuhad, R.C., (2009). Separate hydrolysis and
fermentation (SHF) of Prosopis juliflora, a woody substrate, for the production
of cellulosic ethanol by Saccharomyces cerevisiae and Pichia stipitis-NCIM
3498. Bioresour Technol. 100: 1214-1220.
99. Hahn-Hagerdal, B., and Pamment, N., (2004). Microbial pentose metabolism.
Appl Biochem Biotech. 113-116: 1207-1209.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 173
100. Hahn-Hagerdal, B., Galbe, M., Gorwa-Grauslund, M.F., Liden, G., and
Zacchi, G., (2006). Bioethanol- the fuel of tomorrow from the residues of
today. Trends Biotechnol. 24(12): 549-56.
101. Hahn-Hagerdal, B., Karhumaa, K., Fonseca, C., Spencer-Martins, I., and
Gorwa-Grauslund, M.F., (2007). Towards industrial pentose-fermenting yeast
strains. Appl Microbial Biotechnol. 74: 937-953.
102. Hamelinck, C.N., Van Hooijdonk, G, and Faaij, A.P.C., (2005). Ethanol from
lignocellulosic biomass: techno-economic performance in short-, middle- and
long-term. Biomass Bioenerg. 28: 384-410.
103. Hammond, J., (2000). Yeast growth and nutrition. In Brewing yeast
fermentation performance; Smart, K., Ed.; Oxford Brookes University Press:
Oxford, UK.
104. Hammond, G.M., Kallu, S., and McManus, M.C., (2009). Development of
biofuels for the UK automotive market. Appl Energy. 86: 506-15.
105. Harkins, J.M., and Rowe, J.W., (1971). Bark and its possible uses. USDA For
Serv Res. Note FPL-091, For Prod Lab., Madison, Wis.
106. Harun, M.Y., Dayang Radiah, A.B., Zainal Abidin, Z, and Yunus, R., (2011).
Effect of physical pretreatment on dilute acid hydrolysis of water hyacinth
(Eichhornia crassipes). Bioresour Technol. 102(8): 5193-5199.
107. Hatakka, A., (1994). Lignin-modifying enzymes from selected white-rot
fungi- production and role in lignin degradation. FEMS Microbiol Rev. 13:
125-135.
108. Havannavar, R.B., and Geeta, G.S., (2007). Bioethanol production from
enzyme hydrolyzate agro residues. Karnataka J Agric Sci. 20: 971-972.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 174
109. Hector, R.E., Mertens, J.A., Bowman, M.J., Nichols, N.N., Cotta, M.A., and
Hughes, S.R., (2011). Saccharomyces cerevisiae engineered for xylose
metabolism requires gluconeogenesis and the oxidative branch of the pentose
phosphate pathway for aerobic xylose assimilation. Yeast. 28: 645-660.
110. Heipieper, H.J., Weber, F.J., Sikkema, J., Kewelo, H., and de Bont, J.A.M.,
(1994). Mechanisms of resistance of whole cell to toxic organic solvents.
TIBTECH. 12: 409-415.
111. Himmel, M.E., Ruth, M.F., and Wyman, C.E., (1999). Cellulases for
commodity products from cellulosic biomass. Curr Opin Biotechnol. 10: 358-
364.
112. Himmel, M.E., Ding, S.Y., Johnson, D.K., Adney, W.S., Nimlos, M.R.,
Brady, J.W., and Foust, T.D., (2007). Biomass recalcitrance: Engineering
plants and enzymes for biofuel production. Science. 315: 804-807.
113. Hoebler, C., Barry, J.L., David, A., and Delort-Laval, J., (1989). Rapid acid
hydrolysis of plant cell wall polysaccharides and simplified quantitative
determination of their neutral monosaccharaides by gas-liquid
chromatography. J Agric food chem. 37(2): 360-367.
114. Houston, P., Simon, P.J., and Broach, J.R., (2004). The Saccharomyces
cerevisiae recombination enhancer biases recombination during
interchromosomal mating-type switching but not in interchromosomal
homologous recombination. Genetics 166 (3): 1187-1197.
115. Iranmahboob, J., Nadim, F., and Monemi, S., (2002). Optimizing acid
hydrolysis: a critical step for production of ethanol form mixed wood chips.
Biomass Bioenerg. 22: 401-404.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 175
116. Jeffries, T.W., (1983a). Utilization of xylose by bacteria, yeast and fungi. Adv
Biochem Eng Biotechnol. 27: 1-32.
117. Jeffries, T.W., (1983b). Effects of Nitrate on fermentation of xylose and
glucose by Pachysolen tannophilus. Biotechnol. 1: 503-506.
118. Jeffries, T.W., and Jin, Y.S., (2000). Ethanol and thermotolerance in the
bioconversion of xylose by yeasts. Adv Appl Microbiol. 47: 221-68.
119. Jeffries, T.W., and Jin, Y.S., (2004). Metabolic engineering for improved
fermentation of pentoses by yeasts. Appl Microbiol Biotechnol. 63: 495-509.
120. Jiang, Q., Yao, S., and Mei, L., (2002). Tolerance of immobilized baker’s
yeast in organic solvents. Enz Microbiol Technol. 30: 721-725.
121. Johansen, C.L., Coolen, L., and Hunik, J.H., (1998). Influence of morphology
on product formation in Aspergillus awamori during submerged fermentation.
Biotechnol Prog. 14: 233-240.
122. Jonsson, L.J., Palmqvist, E., Nilvebrant, N.O., and Hahn-Hagerdal, B., (1998).
Detoxification of wood hydrolyzates with laccase and peroxidase from the
white-rot fungus Trametes versicolor. Appl Microbiol Biotechnol. 49: 691-
697.
123. Karel, S. F., Libicki, S.B., and Robertson, C.R., (1985). The immobilization of
whole cells: Engineering principles. Chem Eng Sci. 40(8): 1321-1354.
124. Karimi, K., Emtiazi, G., and Taherzadeh, M.J., (2006). Ethanol production
from diluted acid pretreated rice straw by simultaneous saccharification and
fermentation with Mucor indicus, Rhizopus oryzae and
Saccharomycescerevisiae. Enzyme Microb Technol. 40: 138-144.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 176
125. Karr, W.E., and Holtzapple, M.T., (2000). Using lime pretreatment to
facilitate the enzymatic hydrolysis of corn stover. Biomass Bioenerg. 18:
1099-1120.
126. Kaur, U., Oberoi, H.S., Bhargav, V.K., Sharma-Shivappa, R.R., and Dhaliwal,
S.S., (2012). Ethanol production from alkali and ozone treated cotton stalk
using thermo tolerant Pichia kudriavzevii HOP-1. Ind crop prod. 37, 219-226.
127. Kaya, F., Heitmann, J.A., and Thomas, W.J., (2000). Influence of lignin and
its degradation products on enzymatic hydrolysis of xylan. J Biotechnol.
80:241-247.
128. Keshwani, D. R., Cheng, J. J., Burns, J.C., Li, L., and Chiang, V., (2007).
Microwave pretreatment of switch grass to enhance enzymatic hydrolysis.
ASABE Paper No. 077127. St. Joseph, Mich.: ASABE.
129. Kim, S.B., and Lee, Y.Y., (1996). Fractionation of herbaceous biomass by
ammonia-hydrogen peroxide percolation treatment. Appl Biochem Biotechnol.
57-58: 147-156.
130. Kim, T.H., Kim, J.S., Sunwoo, C., and Lee, Y.Y., (2003). Pretreatment of corn
stover by aqueous ammonia. Bioresour Technol. 90: 39-47.
131. Kim, S., and Dale, B.E., (2004). Global potential bioethanol production from
wasted crops and crop residues. Biomass Bioenerg. 26:361-75.
132. Klass, D.L., (1998). Biomass for renewable energy, fuels and chemicals.
California: Academic, Press. San Diego, CA.
133. Klinke, H.B., Thomsen, A.B., and Ahring, B.K., (2004). Inhibition of ethanol
producing yeast and bacteria by degrading products produced during
pretreatment of biomass. Appl Microbiol Biotechnol. 66: 10-26.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 177
134. Kontturi, E.J., (2005). Surface chemistry of cellulose: From natural fibers to
model surfaces. Eindhoven University of Technology, pp. 06.
http://alexandria.tue.nl/extra2/200510620.pdf
135. Kourkoutas, Y., et al., Bekatorou, A., Banatb, I.M., Marchant, R., and
Koutinas, A.A., (2004). Immobilization technologies and support materials
suitable in alcohol beverages production: a review. Food Microbiol. 21(4):
377-397.
136. Kranthi, K.R., Venugopalan, M.V., Sabesh, M., and Yadav, M.S., (2011),
Vision 2030. Central Institute for Cotton Research, Nagpur.
http://www.cicr.org.in/pdf/CICR_VISION_2030.pdf
137. Kumar, P., Barrett, D.M., Delwiche, M.J., and Stroeve, P., (2009).
Pretreatment of lignocellulosic biomass for efficient hydrolysis and biofuel
production. Ind Eng Chem Res. 48 (8): 3713-3729.
138. Larsson, S., Palmqvist, E., Hahn-Hagerdal, B., Tengborg, C., Stenberg, K.,
Zacchi, G., Nilvebrant, N.O., (1998). The generations of fermentation
inhibitors during dilute acid hydrolysis of soft wood. Enz Microb Technol.
24:151-159.
139. Lali, A., (2010). Bio-alcohol technology for India. In: 7th
International Biofuel
Conference, New Delhi, 11-12 February.
140. Lee, H., (1992). Reversible inactivation of D-xylose utilization by D-glucose
in the pentose fermenting yeast Pachysolen tannophilus. FEMS Micrbiol Lett.
92: 1-4.
141. Lee, Y., Iyer, P., and Torget, R., (1999). Dilute acid hydrolysis of
lignocellulosic biomass. Adv Biochem Eng/Biotechnol. 65: 93-115.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 178
142. Leonard, R.H., and Hajny, G.J., (1945). Fermentation of wood sugars to ethyl
alcohol. Ind Eng Chem. 37: 390-395.
143. Liao, W., Liu, Y., Liu, C., Wen, Z., and Chen, S., (2006). Acid hydrolysis of
fiber from dairy manure. Bioresour Technol. 97: 1687-1695.
144. Licht, F.O., (2006). World Ethanol Market: The Outlook to 2015, Tunbridge
Wells, Agra Europe Special Report, UK.
145. Lin, Y., and Tanaka, S., (2006). Ethanol fermentation from biomass resources:
current state and prospects. Appl Microbiol Biotechnol. 69: 627-645.
146. Linoj Kumar, N.V., Dhavala, P., Goswami, and A., Maithel, S.,(2006). Liquid
biofuels in South Asia: resources and technologies. Asian Biotechnol Develop
Rev. 8: 31-49.
147. Liu, Y., Qi, T.,Shen N., Gan, M., Jin, Y., and Zhao, H., (2009). Improvement
of ethanol concentration and yield by initial aeration and agitation culture in
very high gravity fermentation. Chin J Appl Environ Biol. 15(4), 563-567.
148. Lin, Y.H., Chien, W.S., Duan, K.J., and Chang, P.R., (2011). Effect of
aeration timing and interval during very-high-gravity ethanol fermentation.
Process Biochem. 46: 1025-1028.
149. Lu, Z., and Kumakura, M., (1995). Enzymatic hydrolysis of wheat straw
irradiated by electron-beam in presence of per acetic acid solution. Isot
Environ Health Stud. 31 (1): 151-160.
150. Luo, C., Brink, D.L., and Blanch, H.W., (2002). Identification of potential
fermentation inhibitors in conversion of hybrid poplar hydrolyzate to ethanol.
Biomass Bioenerg. 22: 125-138.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 179
151. Lynd, L.R., Weimer, P.J., Van Zyl, W.H., and Pretorius, I.S., (2002).
Microbial cellulases utilization: fundamentals and biotechnology. Microbiol
Mol Biol Rev. 66(3): 506-577.
152. Ma, F., and Hanna, M.A., (1999). Biodiesel production: a review. Bioresour
Technol. 70: 1-15.
153. Mabee, W.E., Gregg, D.J., Arato, C., Berlin, A., Bura, R., and Gilkes, N.,
(2006). Updates on softwood-to-ethanol process development. Appl Bio-chem
Biotchnol. 129-132: 55-70.
154. Mach, R.L., and Zeilinger, S., (2003). Regulation of gene expression in
industrial fungi: Trichoderma. Appl Microbiol Biotechnol. 60: 515-522.
155. Malca, J, and Freire, F., (2006). Renewability and life cycle energy efficiency
of bioethanol and bio-ethyl tertiary butyl ether (bioETBE): assessing the
implication of allocation. Energy. 31: 3362-3380.
156. Maleszka, R., Wang, P.Y., and Schneider, H., (1982). Ethanol production
from D-galactose and glycerol by Pachysolen tannophilus. Enz Microb
Technol. 4: 349-352.
157. Martinez, A., Rodriguez, M.E., York, .S.W., Preston, J.F., and Ingram, L.O.,
(2000). Effect of Ca (OH) 2 treatments (“overliming”) on the composition and
toxicity and bagasse of hemicellulose hydrolyzates. Biotechnol Bioeng. 69:
526-536.
158. Martinez, A., Rodriguez, M.E., Wells M.L., York, S.W., Preston, J.F., and
Ingram, L.O., (2001). Detoxification of dilute acid hydrolyzate of
lignocellulose with lime. Biotechnol Prog. 17: 287-293.
159. McKendry, P., (2002). Energy production from biomass (part one): overview
of biomass. Bioresour Technol. 83(1): 37-46.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 180
160. Millati, R., Edebo, L., and Taherzadeh, M.J., (2005). Performance of Rizopus,
Rhizomocur, and Mucor in ethanol production form glucose, xylose and wood
hydrolyzates. Enz Microb Technol. 36: 294-300.
161. Miller, G.L., (1959). Use of dinitrosalicylic acid reagent for determination of
reducing sugars. Anal chem. 31: 426-428.
162. Millar, D.G., Griffiths-Smith, K.,Algar, E., and Scopes, R.K.,(1982). Activity
and stability of glycolytic enzymes in the presence of ethanol. Biotechnol Lett.
4: 601-606.
163. Miyafuji, H., Danner, H., Neureiter, M., Thomasser, C., Bvochora, J., Szolar,
O., and Braun, R., (2003). Detoxification of wood hydrolyzates with charcoal
for increasing the fermentability of hydrolyzates. Enz Microb Technol. 32:
396-400.
164. Mohan, D., Pittman, C.U., and Steele, P.H., (2006). Pyrolysis of
wood/biomass for bio-oil; a critical review. Energy Fuels. 20:848-89.
165. Mok, W.S.L., and Antal Jr., M.J., (1992). Uncatalyzed solvolysis of whole
biomass hemicellulose by hot compressed liquid water. Ind Eng Chem Res.
31: 1157-1161.
166. Mosier, N., Wyman, C., Dale,B., Elander, R., Lee, Y.Y., Holtzapple, M., and
Ladish, M., (2005). Features of promising technologies for pretreatment of
lignocellulosic biomass. Bioresour Technol. 96 (6): 673-686.
167. MPNG, (2009). Petroleum Statistics. Ministry of Petroleum and Natural Gas,
Government of India. http://petroleum.nic.in/petstat.pdf
168. Munroe, J., (1994). Fermentation. In: Hardwick WA, editor. Handbook of
brewing. New York: Marcel Dekker Inc. 323-53.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 181
169. Neelakandan, T., and Usharani, G., (2009). Optimization and production of
Bioethanol from cashew apple juice using immobilized yeast cell by
Saccharomycescerevisiae. American-Eurasian J Sci Res. 4(2): 85-88.
170. Nikolic, S., Mojovic, L., Pejin, D., Rakin, M., and Vukasinovi, M.C., (2010).
Production of bioethanol from corn meal hydrolyzates by free and
immobilized cells of saccharomyces cerevisiaevar. ellipsoideus. Biomass
Bioenergy. 34(10):1449-1456.
171. Nigam, J.N., (2002). Bioconversion of water-hyacinth (Eichhornia crassipes)
hemicellulose acid hydrolyzate to motor fuel ethanol by xylose-fermenting
yeast. J Biotechnol. 97: 107-116.
172. NSS, (2007). National Sample Survey Report. National Sample Survey
Organization, Ministry of Statics and Program Implementation, Government
of India. http://www.mospi.gov.in/mospi_nsso_rept_pubn.htm
173. Oberoi, H.S., Vadlani, P.V. Madl, R.L., Saida, L., and Abeykoon, J.P., (2010).
Ethanol production from orange peels: two-stage hydrolysis and fermentation
studies using optimized parameters through experimental design. J Agric Food
Chem. 58: 3422-3429,
174. Olsson, L., and Hahn-Hagerdal. B., (1993). Fermentative performance of
bacteria and yeast in lignocellulose hydrolyzate. Process Biochem. 28(8):
249257.
175. Olsson, L., and Hahn-Hagerdal, B., (1996). Fermentation of lignocellulosic
hydrolyzates for ethanol production. Enzyme Microb Technol. 18: 312-331.
176. Osakwe, E., (2009). Cotton fact sheet- India.
http://www.icac.org/econ_stats/country_facts/e_india.pdf
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 182
177. Oztop, H.N., Yasemin, Oztop, A., Karadag, E., Isikver, Y., and Saraydin, D.,
(2003). Immobilization of Saccharomyces cerevisiae on to acrylamide-sodium
acrylate hydrogels for production ethyl alcohol. Enzyme Microb Technol.
32:114-9.
178. Palmqvist, E., Hahn-Hagerdal, B., Szengyel, Z., Zacchi, and G., Reczey,
K.,(1997). Simultaneous detoxification and enzyme production of
hemicellulose hydrolyzates obtained after steam pretreatment. Enz Microb
Technol. 20: 286-293.
179. Palmqvist, E., Almeida, J.S., and Hahn-Hagerdal, B., (1999). Influence of
furfural on anaerobic glycolytic kinetics of Saccharomyces cerevisiae in batch
culture. Biotechnol Bioeng. 62: 447-454.
180. Palmqvist, E., and Hahn-Hagerdal, B., (2000a). Fermentation of
lignocellulosic hydrolyzate. I: inhibition and detoxification. Bioresour
Technol. 74: 17-24.
181. Palmqvist, E., and Hahn-Hagerdal, B., (2000b). Fermentation of
lignocellulosic hydrolyzate. II: inhibitors and mechanism of inhibition.
Bioresour Technol. 74: 25-33.
182. Pandey, K.K., (1999). A study of chemical structure of soft and hardwood and
wood polymers by FTIR spectroscopy. J Appl Poly Sci. 71: 1969-1975.
183. Pasha, C., Kuhad, R.C., and Rao, L.V., (2007). Strain improvement of thermo
tolerant Saccharomyces cerevisiae VS3 strain for better utilization of
lignocellulosic substrates. J Appl Microbiol. 103: 1480-1489.
184. Paturau, J.M., (1987). Alternative uses of sugarcane and its byproducts in agro
industries. Food and Agricultural Organization of the United Nations (FAO).
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 183
185. Perlack, R.D., Wright, L.L., Turhollow, A.F., Graham, R.L., Strokes, B. J.,
and Erbach, D.C., (2005). Biomass as feedstock for a bioenergy and bio
products industry: the technical feasibility of a billion-ton annual supply: April
2005. Avail at: [http://feedstockreview.ornl.gov/pdf/billion_ton_vision.pdf]
186. Pfuderer, S., and del Castillo, M., (2008). The impact of biofuel on commodity
prices. The department of environment. Food and rural affair, DEFRA,
London: April 2008.
187. Picart, P., Diaz, P., and Poster, F.I.J., (2007). Cellulases from two Penicillum
sp. Strains isolated from subtropical forest soil: production and
characterization. Lett Appl Microbiol. 45: 108-113.
188. Piontek, K., Antorini, M., and Choinowski, T., (2002). Crystal structure of a
laccase from the fungus Trametes versicolor at 1.90-angstrom resolution
containing a full complement of coppers. J Biol Chem. 277:37663-37669.
189. Planning Commission, (2003). Report of the committee on development of
biofuels. Planning Commission, Government of India.
http://planningcommission.nic.in/repots/genrep/cmtt_bio.pdf
190. Plessas, S., Bekatorou, A., Koutinas, A.A., Soupioni, M., Banat, I.M., and
Marchant, R., (2007). Use of Saccharomyces cerevicae cells immobilizd on
orange peel as biocatalyst for alcoholic fermentation. Bioresour Technol. 98:
860-5.
191. Pongaswatmanit, R., Temsiripong, T., and Suwonsichon, T., (2007). Thermal
and rheological properties of tapioca starch and xyloglucan mixtures in the
presence of sucrose. Food Res Int. 40:239-48.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 184
192. Perez. J., Munoz-Dorado, J., de La Rubia, T., and Martinez, J., (2002).
Biodegradation and biological treatment of cellulose, hemicellulose and
lignin: an overview. Int Microbiol. 5(2): 53-63.
193. Prasad. B., (1995). On the kinetics and effectiveness of immobilized while-cell
batch cultures. Bioresour Technol. 53: 269-75.
194. Purwadi, R., (2006). Continuous ethanol production from dilute-acid
hydrolyzate: detoxification and fermentation strategy. (PhD Thesis)
(Taherzadeh, M.J.). Chalmers University, Sweden.
195. Qian, M., Tian, S., Li, X., Zhang, J., Pan, Y., and Yang, X., (2006). Ethanol
production from dilute-acid softwood hydrolyzate by co-culture. Appl biochem
biotechnol. 134: 273-283.
196. Ragauskas, A.J., Williams, C.K., Davison, B.H., Britovsek, G., Cairney, J.,
Eckert, C.A., Frederick, W.J., Hallett, J.P., Leak, D.J., Liotta, C.L., Mielenz,
J.R., Murphy, R., Templer, R., and Tschaplinski, T., (2006). The path forward
for biofuels and biomaterials. Science. 311: 484-489.
197. Rahman, S.H.A., Choudhury, J.P., Ahmad. A.L., and Kamaruddin, A.H.,
(2007). Optimization studies on acid hydrolysis of oil palm empty fruit bunch
fiber for production of xylose. Bioresour Technol. 98: 554-9.
198. Raiskila, S., Pulkkinen, M., Laakso, T., Fagerstedt, K., Mia Loija, Mahlberg,
R., Paajanen, L., Ritschkoff, A.C., and Saranpaa, P., (2007). FTIR
spectroscopic prediction of Klason and acid soluble lignin variation in Norway
spruce cutting clones. Silva Fennica. 41(2): 351-371.
199. Rakin, M., Mojovic, L., Nikolic, S., Vukasinovic, M., and Nedovic, V.,
(2009). Bioethanol production by immobilized Saccharomyces cerevisiae var.
ellipsoideus cells. Afr J Biotechnol. 8(3): 4645-471.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 185
200. Ralph, E.H., Sims, Warren Mabee, Jack, N., Saddler, and Michael, T., (2010).
An overview of second generation biofuel technologies. Bioresour Technol.
101: 1570-1580.
201. Ramirez, S.E., (2005). Long term lime pretreatment of poplar wood. Master’s
Thesis. A&M University, Texas.
202. Rao, R.S., Jyothi, C.P., Prakashm, R.S., Sharma, P.N., and Rao, LV., (2006).
Xylitol production from corn fiber and sugarcane bagasse hydrolyzate by
Candida tropicalis. Bioresour Technol. 97: 1974-1978.
203. Ray, S., Miglani, S., and Goldar, A. (2011). Ethanol blending policy in India:
Demand and supply issues. ICRIER policy series No. 9, December.
www.icrier.org/pdf/policy_series_no_9.pdf
204. Razmovski, R., and Pejin, D., (1996). Immobilization of Saccharomyces
diastaticus, on wood chips for ethanol production. Folia Microbiol. 41: 201-
207.
205. Richard, T.M., Proulx, S., Moore, K.J., and Shouse, S., (2001). Ensilage
technology for biomass pretreatment and storage. ASAE Meeting paper No.
016019. St. Joseph, Mich.: ASAE.
206. Roehr, M., (2000). Biotechnology of Ethanol, Classic and future application.
Publication: Wiley
207. Romero, I., Sanchez, S., Moya, M., Cstro, E., Ruiz, E., and Bravo, V., (2007).
Fermentation of olive tree pruning acid-hydrolyzates by Pachysolen
tannophilus. Biochem Eng J. 36: 108-115.
208. Rose, A.H., and Harisson, J.S., (1993). The yeast. Second edition. Academic
press. London UK.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 186
209. Rottenberg, H., (1979). The measurement of membrane potential and δpH in
the cells, organelles and vesicles. Methods Enzymol. 55:547-569.
210. Rishi, A.S., Nelson, N.D., and Goyal, A., (2001). Molecular forming in plants:
a current perspective. J Plant Biochem Biotechnol. 10(1): 1-12.
211. Ruiz, R., and Ehrman, T., (1996). Determination of carbohydrates in biomass
by high performance liquid chromatography. Laboratory analytical procedure
no. 002. Golden CO: National Renewable Energy Laboratory.
212. Russell, J.B., (1992). Another explanation for the toxicity of fermentation
acids at low pH: anion accumulation versus uncoupling. J Appl Bacteriol.
73:363-370.
213. Saha, B.C., (2003). Hemicellulose bioconversion. J Ind Microbiol Biotechnol.
30(5): 279-291.
214. Saha, B.C., and Cotta, M.A., (2006). Ethanol production from alkaline
peroxide pretreated enzymatically saccharified wheat straw. Biotechnol Prog.
22: 449-453.
215. Saha, B.C., Iten, L.B.,Cotta, M.A., and Wu, Y.V., (2005). Dilute acid
pretreatment, enzymatic saccharification, and fermentation of rice hulls to
ethanol. Biotechnol Prog. 21:816-822.
216. Sakurai, A.,Nishida, Y.,Saito, H., and Sakakibara, M., (2000). Ethanol
production by repeated batch culture using yeast cells immobilized within
porous cellulose carriers. J Biosci Bioeng. 90(5): 526-529.
217. Salas, M.L., Vinuela, E., Salas, M., and Sols, A., (1965). Citrate inhibition of
phosphofructokinase and the Pasteur Effect. Biochem Biophys Res Commun;
Apr 23;19: 371-376.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 187
218. Sanchez, S., Bravo, V., Castro, E., Moya, A.J., and Camacho, F., (1999).
Comparative study of the fermentation of D-glucose/D-xylose mixtures with
Pachysolen tannophilus and Candida shehatae. Bioprocess Eng. 21: 525-532.
219. Sathesh-Prabu, C., and Murugesan, A.G., (2011). Potential utilization of
sorghum field waste for fuel ethanol production employing Pachysolen
tannophilus and Saccharomyces cerevisiae. Bioresour Technol. 102: 2788-
2792.
220. Shafizadeh, F., and Bradbury, A.G.W., (1979). Thermal degradation of
cellulose in air and nitrogen at low temperatures. J Appl Poly Sci. 23: 1431-
1442.
221. Shafizadeh, F., and Lai, Y.Z., (1975). Thermal degradation of cellulose in air
and nitrogen at low temperatures. J Appl Poly Sci. 23: 1431-1442.
222. Shakhashiri, (2009). Chemical of the Week: Ethanol. General Chemistry.
www.scifun.org
223. Shallom, D., and Shoham, Y., (2003). Microbial hemicellulases. Curr Opin
Microbiol. 6 (3): 219-228.
224. Shang, F., Wen, S., Wang, X., and Tan, T., (2006). High cell density
fermentation for ergosterol production by Saccharomyces cerevisiae. J Biosci
Bioeng. 101: 38-41.
225. Sharma, G., (1988). Developments in bioreactor for fuel ethanol production.
Process Biochem. 23:138-145.
226. Sharma, S.K., Karla, K.L., and Grewal, H.S., (2002). Fermentation of
enzymatically saccharified sunflower stalks for ethanol production and its
scale up. Bioresour Technol. 85: 31-33.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 188
227. Sharma, N., Kalra K. L., Oberoi H. S., and Bansal, S., (2007). Optimization of
fermentation parameters for production of ethanol from kinnow wastes and
banana peels by simultaneous saccharification and fermentation. Ind J
Microbiol. 47: 310-316.
228. Shi, J., Sharma-Shivappa, R.R., Chinn, M.S., and Howell, N., (2009). Effect of
microbial pretreatment on enzymatic hydrolysis and fermentation of cotton
stalk for ethanol production. Bioresour Technol. 33: 88-96.
229. Shinonaga, M.Kawamura, Y., and Yamane, T., (1992). Immobilization of
yeasts cell with cross linked chitosan beads. J Ferment Bioeng. 74: 90-94.
230. Silva, C.J.S.M., and Roberto, I.C., (2001). Improvement of xylitol production
by Candida guilliermondii FTI 20037 previously adapted to rice straw
hemicellulosic hydrolyzate. Lett Appl Microbiol. 32: 248-252.
231. Silverstein, R.A., (2004). A comparison of chemical pretreatment methods for
converting cotton stalk to ethanol. Master’s Thesis. Biological and
Agricultural Engineering, North Caroline State University.
232. Silverstein, R.A., Chen, Y., Sharma-Shivappa, R.R., Boyette, M.D., and
Osborn, J. A., (2007). A comparison of chemical pre-treatment methods for
improving saccharification of cotton stalks. Bioresour Technol. 98: 3000-
3011.
233. Singh, A., and Kumar, P.K., (1991).Fusarium oxysporum: status in bioethanol
production. Crit Rev Biotechnol. 11(2): 129-47.
234. Singleton, V.L., and Rossi, J.A., (1965). Colorimetric of total phenolics with
phosphomolybdic-phosphotungstic acid reagents. Am J Enol Viticult. 16: 144-
158.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 189
235. Siqueira, P.F., Karp, S.G., Carvalho, J.C., Sturm, W., Rodriguez-Leon, J.A.,
Tholozan, J.L., Singhania, R.R., Pandey, A., and Soccol, C.R., (2008).
Production of bioethanol from soybean molasses by Saccharomycescerevisiae
at laboratory, pilot and industrial scale. Bioresour Technol. 99: 8156-8163.
236. Slininger, P.J., Bolen, P.L., and Kurtzman, C.P., (1987). Pachysolen
tannophilus: properties and process consideration for ethanol production from
D-xylose. Enzyme Microb Technol. 9: 5-15.
237. Slininger, P.J., and Bothast, R.J., (1988). Continuous fermentation of feed
streams containing D-glucose and D-xylose in two-stage process utilizing
immobilized Saccharomyces cerevisiae and Pachysolen tannophilus.
Biotechnol Bioeng. 32:1104-1112.
238. Soccol, C.R., Vandenbarghe, L.P.S., Medeiros, A.B.P., Krap, S.G.,
Buckeridge, M., Ramos, L.P., Pitarelo, A.P., Ferreira-Leitao,V., Gottschalk,
L.M.F., Ferrara, M.A., Bon, E.P.S., Moraes, L.M.P., Araujo, J.A., and Torres,
F.A.G., (2010). Bioethanol from lignocelluloses: status and perspectives in
Brazil. Bioresour Technol. 101(13): 4820-4825.
239. Sohail, M.,Siddiqi, R., Ahmad, A., and Khan, S.A., (2009). Cellulases
production from Aspergillus nigerMS82: effect of temperature and pH. N
Biotechnol. 25: 437-441.
240. Solomon, B.D., Barnes, J.R., and Halvorsen, K.E., (2007). Grains and
cellulosic ethanol: History, economics, and energy policy. Biomass Bioenerg.
31: 416-425.
241. Somkid, D., and Wuttichai, K., (2009). Comparison of hydrolysis condition to
recover reducing sugar from various lignocellulosic materials. Chiang Mai J
Sci. 36(3): 384-394.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 190
242. Spatari, S.,Zhang, Y., and MacLean, H., (2005). Life cycles assessment of
switch grass and corn stover-derived ethanol-fueled automobiles. Environ Sci
Technol. 39: 9750-9758.
243. Sree, K.N., Sridhar, M., Suresh, K., and Rao, L.V., (1999). High alcohol
production by solid substrate fermentation from starchy substrates using
thermo tolerant Saccharomyces cerevisiae. Bioproc Eng. 20: 561-563.
244. Srilekha Yadav, K., Naseeruddin, S., Prashanthi, G.S., Sateesh, L., and Rao,
L.V., (2011). Bioethanol fermentation of concentrated rice straw hydrolyzate
using co-culture of Saccharomyces cerevisiae and Pichia stipites. Bioresour
Technol. 102(11): 6473-6478.
245. Stavrinides, A.J., Phipps, D.A., and Al-Shamma’a A., (2010). Review; current
and developing lignocellulosic pretreatment methods for bioethanol
production. 223-
242.[http://www.ljmu.ac.uk/BLT/BUE_Docs/Amended_PROCEEDINGS_BE
AN_2010_WEB_VERSION_24.pdf]
246. Sukumaran, R.K., Surender, V.J., Sindhu, R., Binod, P., Janu, K.U., Sajna,
K.V., Rajasree K.P., and Pandey, A., (2010). Lignocellulosic ethanol in India:
prospects, challenges and feed stocks availability. Bioresour Technol. 101,
4826-4833.
247. Sukumaran, R.K., and Pandey, A., (2009). Indian country report. In:
Eisentraut, A, (Ed.). Potential for sustainable production of 2nd generation
biofuel, IEA 2009, p. 26.
248. Sun, Y., and Cheng, J., (2002). Hydrolysis of lignocellulosic material for
ethanol production: a review. Bioresour Technol. 83: 1-11.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 191
249. Taherzadeh, M.J., Gustaffson, L., Niklasson, C., and Liden, G., (1999).
Conversion of furfural in aerobic and anaerobic batch fermentation of glucose
by Saccharomyces cerevisiae. J Biosci Bioeng. 87: 169-174.
250. Taherzadeh, M.J., Millati, R., and Niklasson, C., (2001). Continuous
cultivation of dilute-acid hydrolyzates to ethanol by immobilized
Saccharomyces cerevisiae. Appl Biochem Biotechnol. 95(1): 45-57.
251. Taherzadeh, M.J., and Karimi, K., (2007). Acid-Based hydrolysis processes
for ethanol from lignocellulosic materials: A Review. Bioreserces. 2: 472-499.
252. Taherzadeh, M.J., and Karimi, K., (2008). Pretreatment of lignocellulosic
wastes to improve ethanol and biogas production: A Review. Int J Mol Sci.
9:1621-1651.
253. Talebnia, F., (2008). Ethanol production from cellulosic biomass by
encapsulated Saccharomyces cerevisiae. PhD Thesis. Department of chemical
and biological engineering. Chalmers University of technology, Goteborg,
Sweden. P. 05.
254. TAPPI, (1992). Technical Association of Paper and Pulp Industries, Atlanta,
Georgia, USA.
255. Teramoto, Y., Lee, S-H, and Endo, T., (2008). Pretreatment of woody and
herbaceous biomass for enzymatic saccharification using sulfuric acid-free
ethanol cooking. Bioresour Technol. 99: 8856-8863.
256. Thamsiriroj, T., and Murphy,J.D., (2009). Is it better to import palm oil from
Thailand to produce biodiesel from indigenous Irish rape seed? Appl Energ.
86: 595-604.
257. Thimmaiah, S.R., (2006). Standard methods of biochemical analysis, kalyani
publishers, Ludhiana, India.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 192
258. Thomson, J.M., Gaucher, E.A., Burgan, M.F., De Kee, D.W., Li, T., Aris, J.P.,
and Benner, S.A., (2005). Resurrecting ancestral alcohol dehydrogenases from
yeast. Nat Genet. 37(6): 630-635.
259. Tolan, J.S., and Foody, B., (1999). Cellulases from submerged fermentation.
Adv Biochem Eng Biotechnol. 65: 41-67.
260. Tuite, M.F., and Oliver, G., (1991).Saccharomyces Handbook. Plenum press.
New York.
261. Van Zyl. C., Prior, B.A., and du Preez. J.C., (1988). Production of ethanol
from sugar cane bagasses hemicellulose hydrolyzate by Pichia stipites. Appl
Biochem Biotechnol. 17: 357-369.
262. Van Zyl, W.H., Lynd, L. R., Den Haan, R. and McBride, J. E., (2007).
Consolidated bioprocessing for bioethanol production using Saccharomyces
cerevisiae. Adv Biochem Eng Biotechnol. 108: 205-235.
263. Ververis, C., Georghiou, K., Christodoulakis, N., Santas, P., and Santas, R.,
(2004).Fiber dimensions, lignin and cellulose contents of various plant
materials and their suitability for paper production. Ind crop Prod.19(3): 245-
254.
264. Vincent,J.F.V., (1999). From cellulose to cell. J Exp Biol. 202: 3263-3268.
265. Virtus Global Partners, (2008). Investment opportunities in the Indian ethanol
industry. Indian ethanol market analysis. www.virtusglobal.com
266. Vullo, D.L., and Wachsman, M.B., (2005). A simple laboratory exercise for
ethanol production by immobilized bakery yeasts (Saccharomyces cerevisiae)
(Lab Exercises/Demonstrations). J Food Sci Edu. 4:53-55.
267. Walker, G., (1998). Yeast physiology and biotechnology . Willey Sons.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 193
268. Wang, M., Saricks, C., and Santini, D., (1999). Effect of fuel ethanol use on
fuel cycle energy and greenhouse gas emission. Argonne (IL): Argonne
National Laboratory.
269. Wang, M., Wu, M., and Huo, H., (2007). Life cycle energy and greenhouse
gas emission impact of different corn ethanol plant types. Environ Res Lett. 2:
1-13.
270. World watch Institute. State of the world (2006). Special focus: China and
India. A World watch Institute report on progress toward a sustainable society,
Washington, DC. World watch institute, January 7.
271. Weil, J.R., Sarikaya, A., Rau, S. L., Goetz, J., Ladisch, C.M., Brewer, M.,
Hendrickson, R., and Ladisch, M.R., (1997). Pretreatment of yellow poplar
sawdust by pressure cooking in water. Applied Biochem Biotechnol. 68(1-2):
21-40.
272. Wendhausen, R., Fregonesi, A., Moran, P.J.S., Joekes, I., Rodrigues, J.A.,
Tonella, E., and Althoff, K., (2001). Continuous fermentation of sugar cane
syrup using immobilized yeast cells. J Biosci Bioeng. 9(1): 48-52.
273. Wheals, A.E., Basso, L.C., Alves, Denise, M.G., and Amorin, H.V., (1999).
Fuel ethanol after 25 years. Trend Biotechnol. 17(12): 482-487.
274. Wickerham, L.J., (1970). Genus 14, Pachysolen Boidin et Adzet, pp. 448-
454. In J. Lodder (ed), The yeast. A taxonomic study, second edition. North-
Holland Publishing Co., Amsterdam.
275. Williams, K.C., (2006). Subcritical water and chemical pretreatments of cotton
stalk for the production of ethanol. Master’s Thesis. North Carolina State
University.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 194
276. Williams, M.B, and Reese, Darwin, (1950). Colorimetric determination of
ethyl alcohol. Anal Chem. 22.
277. Wise, L.E., Murphy, M., and D’Addieco, A.A., (1946). Chlorite holocellulose,
its fractionation and bearing on summative wood analysis and on studies on
the hemicellulose. Pap Trade J. 122 (2): 35-43.
278. Wyman, C.E., (1996). Ethanol production from lignocellulosic biomass:
Overview. In: Wyman CE, editor. Handbook on Bioethanol: production and
utilization. Washington DC: Taylor and Francis. p. 1-16.
279. Wyman, C., E., (1999). Biomass ethanol: technical progress, opportunities,
and commercial challenges. Annu Rev of Energy Environ. 24: 189-226.
280. Wyman, C.E., Dale, B.E., Elander, R.T., Holtzapple, M., Ladisch, M.R., and
Lee, Y.Y., (2005). Coordinated development of leading biomass pretreatment
technologies. Bioresour Technol. 69: 1959-1966.
281. Xu, L., (2012). Biofuel production by using integrated anaerobic fermentation.
PhD Thesis. University of Minnesota.
282. Xu, J., and Taylor, B., (1993). Characterization of ethanol production from
xylose and xylitol by a cell-free Pachysolen tannophilus system. Appl Environ
Microbiol. 59(1): 231-235.
283. Xiang, Q., Lee, Y.Y., and Torget, R.W., (2004). Kinetics of glucose
decomposition during dilute acid hydrolysis of lignocellulosic biomass. Appl
Biochem Biotechnol. 113-116: 1127-1138.
284. Yang, V.W., and Jeffries, T.W., (1997). Regulation of phosphotransferases in
glucose and xylose fermenting yeasts. Appl Biochem Biotechnol. 63-65: 97-
108.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 195
285. Yang, C., Shen, Z., Yu, G, and Wang, J., (2008). Effect and aftereffect of
Gamma-radiation pretreatment on enzymatic hydrolysis of wheat straw.
Bioresour Technol. 99 (14): 6240-6245.
286. Yang, Y., (2008). Ethanol production potential of acid pretreated switch grass
varieties. Master’s thesis. North Carolina State University.
287. Yoosin, S., and Sorapipatana, C., (2007). A study of ethanol production cost
for gasoline substitution in Thailand and its competitiveness. Thammasat Int J
Sci Technol. 12: 69-80.
288. You, K.M., Rosenfield, C.L., and Knipple, D.C., (2003). Ethanol tolerance in
yeast Saccharomyces cerevisiae is dependent on cellular oleic acid content.
Appl Environ Microbiol. 69:1499-1503.
289. Yu, J., Zhang, X., and Tan, T., (2007). A novel immobilization method of
Saccharomyces cerevisiae to sorghum bagasse for ethanol production. J
Biotechnol. 129: 415-20.
290. Yu, Z., and Zhang, H., (2004). Ethanol fermentation of acid-hydrolysed
cellulosic pyro lysate with Saccharomyces cerevisiae. Bioresour Technol. 93,
199-204.
291. Zaldivar, J., Nielsen, J., and Olsson, L., (2001). Fuel ethanol production from
lignocellulose: A challenge for metabolic engineering and process integration.
Appl Microbiol Biotechnol. 56: 17-34.
292. Zheng, Y., Lin, H.M., and Tsao, G.T., (1998). Pretreatment for cellulose
hydrolysis by carbon dioxide explosion. Biotechnol Prog. 14: 890-896.
293. Zheng, Y., Pan, Z., and Zhang, R., (2009). Overview of biomass pretreatment
for cellulosic ethanol production. Int J Agric Biol Eng. 2(3): 102-6.
REFERENCES Studies on Production of Bioethanol from Cotton Stalk
Ph. D. Thesis, Mirza Zaheer Baig, 2014, Dr.BAMU, Aurangabad Page 196
294. Zhu,S., Wu, Y., Yu., Z., Liao, j., and Zhang, Y., (2005). Pretreatment by
microwave/alkali of rice straw and its enzymatic hydrolysis. Process Biochem.
40: 3082-3086.
295. Zhu, L., O’Dwyer, J.P., Chang, V.S., Granda, C.B., and Holtzapple, M.T.,
(2008). Structural features affecting biomass enzymatic digestibility.
Bioressour Technol. 99(9): 3817-3828.