| 1 |
Effect of the surface acid sites of tungsten trioxide for highly selective hydrogenation of cellulose to ethylene glycol
Li NX, Ji ZX, Wei LF, Zheng Y, Shen QH, Ma QH, Tan ML, Zhan MM, Zhou JC
Bioresource Technology, 264, 58, 2018 |
| 2 |
ZSM-5-supported multiply-twinned nickel particles: Formation, surface properties, and high catalytic performance in hydrolytic hydrogenation of cellulose
Liang GF, He LM, Cheng HY, Zhang C, Li XR, Fujita S, Zhang B, Arai M, Zhao FY
Journal of Catalysis, 325, 79, 2015 |
| 3 |
The hydrolytic hydrogenation of cellulose to sorbitol over M (Ru, Ir, Pd, Rh)-BEA-zeolite catalysts
Negoi A, Triantafyllidis K, Parvulescu VI, Coman SM
Catalysis Today, 223, 122, 2014 |
| 4 |
The hydrogenation/dehydrogenation activity of supported Ni catalysts and their effect on hexitols selectivity in hydrolytic hydrogenation of cellulose
Liang GF, He LM, Cheng HY, Li W, Li XR, Zhang C, Yu YC, Zhao FY
Journal of Catalysis, 309, 468, 2014 |
| 5 |
Analysis of the Products of Cellulosic Wastes Hydrogenation as Petrochemical Feedstock
Anagho SG, Ngomo HM, Ambe F
Energy Sources Part A-recovery Utilization and Environmental Effects, 32(11), 1052, 2010 |
| 6 |
Bituminous oils from the hydrogenation of cellulosic wastes: a kinetic study
Anagho SG, Ngomo HM, Edewor JO
Energy Sources, 26(4), 415, 2004 |
| 7 |
Importance of phase equilibria for understanding supercritical fluid environments
Arai K, Adschiri T
Fluid Phase Equilibria, 158-160, 673, 1999 |
