| 3557 - 3570 |
Fuel-cycle analysis of early market applications of fuel cells: Forklift propulsion systems and distributed power generation
Elgowainy A, Gaines L, Wang M |
| 3571 - 3577 |
Potential opportunities and impacts of a hydrogen economy for the Australian minerals industry
McLellan BC |
| 3578 - 3588 |
Economic & commercial viability of hydrogen fuel cell vehicles from an automotive manufacturer perspective
Frenette G, Forthoffer D |
| 3589 - 3603 |
Political, economic and environmental impacts of biomass-based hydrogen
Balat M, Balat M |
| 3604 - 3611 |
High temperature and pressure alkaline electrolysis
Ganley JC |
| 3612 - 3620 |
Ion transport resistance in Microbial Electrolysis Cells with anion and cation exchange membranes
Sleutels THJA, Hamelers HVM, Rozendal RA, Buisman CJN |
| 3621 - 3630 |
Highly dispersed phase of SnO(2) on TiO(2) nanoparticles synthesized by polyol-mediated route: Photocatalytic activity for hydrogen generation
Sasikala R, Shirole A, Sudarsan V, Sakuntala T, Sudakar C, Naik R, Bharadwaj SR |
| 3631 - 3638 |
Electronic structure and water splitting under visible light irradiation of BiTa(1-x)Cu(x)O(4) (x=0.00-0.04) photocatalysts
Zhang HJ, Chen G, Li X, Wang Q |
| 3639 - 3646 |
Alkalinity and high total solids affecting H(2) production from organic solid waste by anaerobic consortia
Valdez-Vazquez I, Poggi-Varaldo HM |
| 3647 - 3652 |
Hydrogen production from glucose by co-culture of Clostridium Butyricum and immobilized Rhodopseudomonas faecalis RLD-53
Ding J, Liu BF, Ren NQ, Xing DF, Guo WQ, Xu JF, Xie GJ |
| 3653 - 3658 |
Source of methane and methods to control its formation in single chamber microbial electrolysis cells
Wang AJ, Liu WZ, Cheng SA, Xing DF, Zhou JH, Logan BE |
| 3659 - 3670 |
Thermophilic biohydrogen production from energy plants by Caldicellulosiruptor saccharolyticus and comparison with related studies
Ivanova G, Rakhely G, Kovacs KL |
| 3671 - 3678 |
Hydrogen generation from glycerol in batch fermentation process
Seifert K, Waligorska M, Wojtowski M, Laniecki M |
| 3679 - 3688 |
Long-term stability of hydrogen and organic acids production in an anaerobic fluidized-bed reactor using heat treated anaerobic sludge inoculum
Shida GM, Barros AR, dos Reis CM, de Amorim ELC, Damianovic MHRZ, Silva EL |
| 3689 - 3696 |
Effect of organic loading rate on fermentative hydrogen production from continuous stirred tank and membrane bioreactors
Shen LH, Bagley DM, Liss SN |
| 3697 - 3709 |
Modeling of fermentative hydrogen production from the bacterium Ruminococcus albus: Definition of metabolism and kinetics during growth on glucose
Ntaikou I, Gavala HN, Lyberatos G |
| 3710 - 3716 |
Kinetic model of homogeneous thermal decomposition of methane and ethane
Younessi-Sinaki M, Matida EA, Hamdullahpur F |
| 3717 - 3733 |
Dynamic modeling and optimization of a novel methanol synthesis loop with hydrogen-permselective membrane reactor
Parvasi P, Mostafazadeh AK, Rahimpour MR |
| 3734 - 3742 |
Methane autothermal reforming with CO(2) and O(2) to synthesis gas at the boundary between Ni and ZrO(2)
Gao J, Hou ZY, Liu XS, Zeng YW, Luo MF, Zheng XM |
| 3743 - 3754 |
Ultrasonic-assisted synthesis of highly active catalyst Au/MnO(x)-CeO(2) used for the preferential oxidation of CO in H(2)-rich stream
Tu YB, Luo JY, Meng M, Wang G, He JJ |
| 3755 - 3763 |
Hydrogen production by steam reforming of liquefied natural gas (LNG) over Ni/Al(2)O(3)-ZrO(2) xerogel catalysts: Effect of calcination temperature of Al(2)O(3)-ZrO(2) xerogel supports
Seo JG, Youn MH, Park SY, Chung JS, Song IK |
| 3764 - 3770 |
Hydridic, thermodynamic and kinetic properties of Hf(2)Ni intermetallic phase
Stojic DL, Kumric SV, Belosevic-Cavor JN, Radakovic JS, Cekic BD, Mentus SV |
| 3771 - 3777 |
Comparison of hydrogen storage properties of Ti(0.37)V(0.38)Mn(0.25) alloys prepared by mechanical alloying and vacuum arc melting
Wang JY |
| 3778 - 3783 |
Decomposition mechanism of magnesium amide Mg(NH(2))(2)
Song Y, Yang R |
| 3784 - 3798 |
Storage of hydrogen in nanostructured carbon materials
Yurum Y, Taralp A, Veziroglu TN |
| 3799 - 3809 |
Hydrogen storage in an activated carbon bed: Effect of energy release on storage capacity of the tank
Momen G, Hermosilla G, Michau A, Pons M, Firdaouss M, Hassouni K |
| 3810 - 3815 |
Porous grape-like spherical silica with hydrogen storage capability, synthesized using neutral dual surfactants as templates
Du L, Liao SJ, Liu QB, Yang X, Song HY, Fu ZY, Ji S |
| 3816 - 3822 |
Preparation and catalysis of poly(N-vinyl-2-pyrrolidone) (PVP) stabilized nickel catalyst for hydrolytic dehydrogenation of ammonia borane
Umegaki T, Yan JM, Zhang XB, Shioyama H, Kuriyama N, Xu Q |
| 3823 - 3832 |
Determination of the optimal active area for proton exchange membrane fuel cells with parallel, interdigitated or serpentine designs
Wang XD, Zhang XX, Yan WM, Lee DJ, Su A |
| 3833 - 3837 |
Vibration tests on a PEM fuel cell stack usable in transportation application
Rajalakshmi N, Pandian S, Dhathathreyan KS |
| 3838 - 3844 |
Preparation and evaluation of electrodeposited platinum nanoparticles on in situ carbon nanotubes grown carbon paper for proton exchange membrane fuel cells
Saminathan K, Kamavaram V, Veedu V, Kannan AM |
| 3845 - 3857 |
Liquid water visualization in PEM fuel cells: A review
Bazylak A |
| 3858 - 3872 |
Development of some exergetic parameters for PEM fuel cells for measuring environmental impact and sustainability
Midilli A, Dincer I |
| 3873 - 3884 |
A key geometric parameter for the flow uniformity in planar solid oxide fuel cell stacks
Bi WX, Chen DF, Lin ZJ |
| 3885 - 3893 |
Performance and effective kinetic models of methane steam reforming over Ni/YSZ anode of planar SOFC
Wang YZ, Yoshiba F, Kawase M, Watanabe T |
| 3894 - 3907 |
Integration of solid oxide fuel cell and palladium membrane reactor: Technical and economic analysis
Piroonlerkgul P, Kiatkittipong W, Arpornwichanop A, Soottitantawat A, Wiyaratn W, Laosiripojana N, Adesina AA, Assabumrunrat S |
| 3908 - 3914 |
Effect of over-oxidation treatment of Pt-Co/polypyrrole-carbon nanotube catalysts on methanol oxidation
Zhao HB, Yang J, Li L, Li H, Wang JL, Zhang YM |
| 3915 - 3921 |
Long-term performance of DMFC based on the blend membrane of sulfonated poly(ether ether ketone) and poly(vinylidene fluoride)
Jung HY, Park JK |
| 3922 - 3929 |
Role of mixture richness, spark and valve timing in hydrogen-fuelled engine performance and emission
Salimi F, Shamekhi AH, Pourkhesalian AM |
| 3930 - 3944 |
Impact of H(2) addition on flame stability and pollutant emissions for an atmospheric kerosene/air swirled flame of laboratory scaled gas turbine
Frenillot JP, Cabot G, Cazalens M, Renou B, Boukhalfa MA |
| 3945 - 3952 |
Parametric studies on a metal-hydride cooling system
Mellouli S, Askri F, Dhaou H, Jemni A, Ben Nasrallah S |
| 3953 - 3964 |
Multi-loop nonlinear predictive control scheme for a simplistic hybrid energy system
Wu W, Xu JP, Hwang JJ |
| 3965 - 3976 |
Enhancement of gasoline production in a novel hydrogen-permselective membrane reactor in Fischer-Tropsch synthesis of GTL technology
Forghani AA, Elekaei H, Rahimpour MR |
| 3977 - 3982 |
Aligned CNT/Polymer nanocomposite membranes for hydrogen separation
Sharma A, Kumar S, Tripathi B, Singh M, Vijay YK |
| 3983 - 3987 |
First-principles study of hydrogen diffusion in alpha Ti
Han XL, Wang Q, Sun DL, Sun T, Guo Q |
| 3988 - 3991 |
X-ray induced nonbridging oxygen hole center in soda-lime silicate glass
Sheng JW, Yang XJ, Dong W, Zhang J |
| 3992 - 4004 |
New process concepts for CO(2) post-combustion capture process integrated with co-production of hydrogen
Abu-Zahra MRM, Feron PHM, Jansens PJ, Goetheer ELV |
| 4005 - 4013 |
Computed extinction limits and flame structures of H(2)/O(2) counterflow diffusion flames with CO(2) dilution
Shih HY |
| 4014 - 4020 |
A novel approach for treatment of CO(2) from fossil fired power plants, Part A: The integrated systems ITRPP
Minutillo M, Perna A |
| 4021 - 4028 |
Catalytic performance of a copper-promoted CeO(2) catalyst in the CO oxidation: Influence of the operating variables and kinetic study
Schonbrod B, Marino F, Baronetti G, Laborde M |
| 4029 - 4029 |
Comments on the paper "Sulfur-iodine thermochemical cycle: HI decomposition flow sheet analysis"
Borgard JM |
| 4030 - 4030 |
Response to "Comments by Dr Jean-Marc Borgard on paper: Sulfur-iodine thermochemical cycle: HI decomposition flow sheet analysis, Cheikhou Kane, Shripad T. Revankar, Int J Hydrogen Energy 33 (2008) 5996-6005"
Kane C, Revankar ST |
| 4031 - 4032 |
SPECIAL ISSUE 2007 AIChE-ACS Management Conference Preface
Gorensek MB |
| 4033 - 4040 |
Process model-free analysis for thermodynamic efficiencies of sulfur-iodine processes for thermochemical water decomposition
O'Connell JP, Narkprasert P, Gorensek MB |
| 4041 - 4048 |
Survey of Bunsen reaction routes to improve the sulfur-iodine thermochemical water-splitting cycle
Giaconia A, Caputo G, Sau S, Prosini PP, Pozio A, De Francesco M, Tarquini P, Nardi L |
| 4049 - 4056 |
Decomposition of hydrogen iodide in the S-I thermochemical cycle over Ni catalyst systems
Favuzza P, Felici C, Lanchi M, Liberatore R, Mazzocchia CV, Spadoni A, Tarquini P, Tito AC |
| 4057 - 4064 |
Activated carbon catalysts for the production of hydrogen via the sulfur-iodine thermochemical water splitting cycle
Petkovic LM, Ginosar DM, Rollins HW, Burch KC, Deiana C, Silva HS, Sardella MF, Granados D |
| 4065 - 4073 |
High-temperature sulfuric acid decomposition over complex metal oxide catalysts
Ginosar DM, Rollins HW, Petkovic LM, Burch KC, Rush MJ |
| 4074 - 4087 |
Design of a composite sulfuric acid decomposition reactor, concentrator, and preheater for hydrogen generation processes
Connolly SM, Zabolotny E, McLaughlin DF, Lahoda EJ |
| 4088 - 4096 |
Membrane separation processes for the benefit of the sulfur-iodine and hybrid sulfur thermochemical cycles
Orme CJ, Klaehn JR, Stewart FF |
| 4097 - 4114 |
Hybrid sulfur flowsheets using PEM electrolysis and a bayonet decomposition reactor
Gorensek MB, Summers WA |
| 4115 - 4124 |
Evaluation of alternative thermochemical cycles, Part I: The methodology
Lewis MA, Masin JG, O'Hare PA |
| 4125 - 4135 |
The evaluation of alternative thermochemical cycles - Part II: The down-selection process
Lewis MA, Masin JG |
| 4136 - 4145 |
Evaluation of alternative thermochemical cycles - Part III further development of the Cu-Cl cycle
Lewis MA, Ferrandon MS, Tatterson DF, Mathias P |
| 4146 - 4154 |
A systematic methodology for the evaluation of alternative thermochemical cycles for hydrogen production
Andress RJ, Huang XQ, Bequette BW, Martin LL |
| 4155 - 4167 |
Modeling and analysis of calcium bromide hydrolysis
Lottes SA, Lyczkowski RW, Panchal CB, Doctor RD |
| 4168 - 4178 |
Analysis of alternative flow sheets for the hybrid chlorine cycle
Gooding CH |
| 4179 - 4188 |
Analysis of the hybrid copper oxide-copper sulfate cycle for the thermochemical splitting of water for hydrogen production
Gonzales RB, Law VJ, Prindle JC |
| 4189 - 4197 |
3D CFD model of a multi-cell high-temperature electrolysis stack
Hawkes G, O'Brien J, Stoots C, Hawkes B |
| 4198 - 4207 |
Post-test evaluation of oxygen electrodes from solid oxide electrolysis stacks
Mawdsley JR, Carter JD, Kropf AJ, Yildiz B, Maroni VA |
| 4208 - 4215 |
Results of recent high temperature coelectrolysis studies at the Idaho National Laboratory
Stoots C, O'Brien J, Hartvigsen J |
| 4216 - 4226 |
Parametric study of large-scale production of syngas via high-temperature co-electrolysis
O'Brien JE, McKellar MG, Stoots CM, Herring JS, Hawkes GL |
| 4227 - 4236 |
Meeting US liquid transport fuel needs with a nuclear hydrogen biomass system
Forsberg CW |
| 4237 - 4242 |
Relative economic incentives for hydrogen from nuclear, renewable, and fossil energy sources
Gorensek MB, Forsberg CW |
