| 2163 - 2173 |
Acid-catalyzed production of 5-hydroxymethyl furfural from D-fructose in subcritical water
Asghari FS, Yoshida H |
| 2174 - 2178 |
Kinetic study of hexenuronic and methylglucuronic acid reactions in pulp and in dissolved xylan during kraft pulping of hardwood
Danielsson S, Kisara K, Lindstrom ME |
| 2179 - 2186 |
Development of a new microreactor based on annular microsegments for fine particle production
Nagasawa H, Mae K |
| 2187 - 2193 |
Synthesis and UV-visible-light photoactivity of noble-metal-SrTiO3 composites
Subramanian V, Roeder RK, Wolf EE |
| 2194 - 2198 |
Catalytic performance of autoclave liners in the wet oxidation of naphthalene
Onda A, Suzuki Y, Kajiyoshi K, Yanagisawa K |
| 2199 - 2205 |
Kinetic investigation of photocatalytic effects on poly(vinyl butyral) photodegradation
Liau LCK, Tung MT |
| 2206 - 2212 |
Multiwalled carbon nanotubes for liquid-phase oxidation. Functionalization, characterization, and catalytic activity
Ovejero G, Sotelo JL, Romero MD, Rodriguez A, Ocana MA, Rodriguez G, Garcia J |
| 2213 - 2219 |
Effect of alumina binder on catalytic performance of PtSnNa/ZSM-5 catalyst for propane dehydrogenation
Zhang YW, Zhou YM, Qiu AD, Wang Y, Xu Y, Wu PC |
| 2220 - 2228 |
Selective oxidation of 1-butene by molecular oxygen in a porous membrane Taylor flow reactor
Lapkin AA, Bozkaya B, Plucinski PK |
| 2229 - 2234 |
Sulfolene hydrogenation over an amorphous Ni-B alloy catalyst on MgO
Ge SH, Wu ZJ, Zhang MH, Li W, Tao KY |
| 2235 - 2248 |
Surfactant adsorption and Marangoni flow in liquid jets. 3. Modeling in the presence of micellar surfactant
Weiss M, Darton RC, Battal T, Bain CD |
| 2249 - 2254 |
A Monte Carlo model for the formation of core-shell nanocrystals in reverse micellar systems
Jain R, Shukla D, Mehra A |
| 2255 - 2260 |
Modification of poly(hydroethyl acrylate)-grafted cross-linked poly(vinyl chloride) particles via surface-initiated atom-transfer radical polymerization (SI-ATRP). Competitive adsorption of some heavy metal ions on modified polymers
Liu P, Liu YS, Su ZX |
| 2261 - 2271 |
Global bounds on optimal solutions for the production of 2,3-dimethylbutene-1
Gangadwala J, Kienle A, Haus UU, Michaels D, Weismantel R |
| 2272 - 2280 |
Stage-based online quality control for batch processes
Lu NY, Gao FR |
| 2281 - 2286 |
The superior technical choice for dual fluidized bed gasification
Xu GW, Murakami T, Suda T, Matsuzawa Y, Tani H |
| 2287 - 2293 |
Recrystallization of a pharmaceutical compound using liquid and supercritical antisolvents
Park SJ, Jeon SY, Yeo SD |
| 2294 - 2302 |
Removal of lignin and associated impurities from xylo-oligosaccharides by activated carbon adsorption
Montane D, Nabarlatz D, Martorell A, Torne-Fernandez V, Fierro V |
| 2303 - 2314 |
Adsorption dynamics of organic compounds and water vapor in activated carbon beds
Qi N, Appel WS, LeVan MD, Finn JE |
| 2315 - 2330 |
Modeling of rotary cement kilns: Applications to reduction in energy consumption
Mujumdar KS, Arora A, Ranade VV |
| 2331 - 2340 |
Using swirl dies to spin solid and hollow fibers
Marla VT, Shambaugh RL, Papavassiliou DV |
| 2341 - 2350 |
Vapor-liquid equilibrium of carbon dioxide-perfluoroalkane mixtures: Experimental data and SAFT modeling
Dias AMA, Carrier H, Daridon JL, Pamies JC, Vega LF, Coutinho JAP, Marrucho IM |
| 2351 - 2360 |
Cure-window-based proactive quality control in topcoat curing
Xiao J, Li J, Lou HH, Huang Y |
| 2361 - 2373 |
Modified LIQUAC and modified LIFAC - A further development of electrolyte models for the reliable prediction of phase equilibria with strong electrolytes
Kiepe J, Noll O, Gmehling J |
| 2374 - 2380 |
Controlled seasoning of Scots pine chips using an albino strain of Ophiostoma
Josefsson P, Nilsson F, Sundstrom L, Norberg C, Lie E, Jansson MB, Henriksson G |
| 2381 - 2393 |
A novel technique to identify flow patterns during liquid-liquid two-phase upflow through a vertical pipe
Jana AK, Das G, Das PK |
| 2394 - 2404 |
High-pressure characterization of dynamic viscosity and derived properties for squalane and two pentaerythritol ester lubricants: Pentaerythritol tetra-2-ethylhexanoate and pentaerythritol tetranonanoate
Pensado AS, Comunas MJP, Lugo L, Fernandez J |
| 2405 - 2407 |
Comment on the removal mechanism of hexavalent chromium by biomaterials or biomaterial-based activated carbons
Park D, Yun YS, Park JM |
| 2408 - 2408 |
Reply to "Comment on the removal mechanism of hexavalent chromium by biomaterials or biomaterials-based activated carbons" - (Comment on "Diffusion kinetic study of Chromium(VI) biosorption by Aeromonas caviae")
Loukidou MX, Karapantsios TD, Zouboulis AI, Matis KA |
| 2409 - 2410 |
Reply to "Comments on the removal mechanism of hexavalent chromium by biomaterials or biomaterial-based activated carbons" - (Comment on "Synthesis, characterization, and application as a Chromium(VI) adsorbent of amine-modified polyacrylamide grafted coconut coir pith")
Unnithan MR, Vinod VP, Anirudhan TS |
| 2411 - 2412 |
Reply to "Comment on the removal mechanism of hexavalent chromium by biomaterials or biomaterial-based activated carbons" - (Comment on "Removal of hexavalent chromium from aqueous solution using low-cost activated carbons derived from agricultural waste materials and activated carbon fabric cloth")
Mohan D, Singh KP, Singh VK |
