Fuel Cell Publications

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Bacirhonde, P. M., A. Y. Mohamed, B. Han, D.-Y. Cho, S. Devendra, J.-W. Choi, C.-R. Lim, E. O. Afranie, K.-H. Baik, K. Kang, S. Lee, E.-S. Jeong, N. Komalla, N. Y. Dzade, C. H. Park, and C. S. Kim, (2023). Ruthenium Engineered A2B2O6-Hybrid Columbite Ferrite for Bifunctional pH-Universal Water Splitting, Advanced Energy Materials, 2300174. doi.org/10.1002/aenm.202300174

Eya, H.I. and N.Y. Dzade, (2023). Density Functional Theory Insights the Structural, Electronic, Optical, Surface and Band Alignment Properties of BaZrS3 Chalcogenide Perovskite for Photovoltaics, ACS Appl. Energy Mater., v. 6, pp. 5729–5738. doi.org/10.1021/acsaem.3c00103

Mali, S. S., J. V. Patil, J.-Y. Shao, Y.-W. Zhong, S. R. Rondiya, N. Y. Dzade, and C. K. Hong, (2023). Phase-heterojunction all-inorganic perovskite solar cells surpassing 21.5% efficiency, Nature Energy, pp. 1-13.

Doan, T. L. L., D. C. Nguyen, R. Amaral, N. Y. Dzade, C. S. Kim, and C. Park, (2022). Rationally designed NiS2-MnS/MoS2 hybridized 3D hollow N-Gr microsphere framework-modified celgard separator for highly efficient Li-S batteries, Applied Catalysis B: Environmental, v. 319 [121934]. doi.org/10.1016/j.apcatb.2022.121934.

Mali, S. S., J. V. Patil, S. R. Rondiya, N. Y. Dzade, M. K. Nazeeruddin, P. S. Patil, and C. K. Hong, (2022). Terbium-Doped and Dual-Passivated γ-CsPb(I1−xBrx )3 Inorganic Perovskite Solar Cells with Improved Air Thermal Stability and High Efficiency, Advanced Materials, v. 34, [2203204]. doi.org/10.1002/adma.202203204.

Fang, B., J. Lou, Y. Chen, B. N. Wanjala, R. Loukrakpam, J. A. Hon, J. Yin, X. A. Hu, P. P. Hu, and C. J. Zhong, (2011). Nanoenigneered PtVFe/C Cathode Electrocatalysts in PEM Fuel Cells: Catalyst Activity and Stability. Chemcatchem, v. 3, DE-cctc.201000316, pp. 583-593.

Jankovic, Z., V. G. Papangelakis, and S. N. Lvov, (2009). Effect of nickel sulphate and magnesium sulphate on pH of sulphuric acid solutions at elevated temperatures, Journal of Applied Electrochemistry, v. 39, pp. 751-759.

Lvov, S. N., S. R. Narayanan, D. D. Macdonald, and D. J. Wesolowski, (2008). Interfacial Electrochemistry and Chemistry in High Temperature Media, Electrochemical Society, v. 11 (27).

Palmer, D., and S. N. Lvov, (2008). High Temperature Potentiometry, in Hydrothermal Properties of Materials, ed. V. Valyashko, Ch.3, Wiley, pp. 195-206.

Song, C. S., (2008). Recent Advances in Catalysis for Hydrogen Production and Fuel Processing for Fuel Cells, Topics in Catalysis, v. 49, pp. 1-3, DE-s11244-0089069-0.

Zhang, Z. C., E. Chalkova, M. V. Fedkin, C. Wang, S. N. Lvov, S. Komarneni, and T.-C. M. Chung, (2008). Synthesis and Characterization of Poly(vinylidene fluoride)-g-sulfonated Polystyrene Graft Copolymers for Proton Exchange Membrane, Macromolecules, v. 41, pp. 9130-9139.

Zheng, J., J. J. Strohm, and C. S. Song, (2008). Steam Reforming of Liquid Hydrocarbon Fuels for Mirco-fuel Cells: Pre-reforming of Model Jet Fuels over Supported Metal Catalysts, Fuel Processing Technology, v. 89, pp. 440-448, DE-j.fuproc.2007.11.024.

Engelhardt, G. R., R. Biswas, Z. Ahmed, S. N. Lvov, and D. D. Macdonald, (2007). The Use of Channel Flow Cells for Electrochemical Kinetic Studies in High Temperature Aqueous Solutions, Electrochimica Acta, v. 52, pp. 4124-4131.

Zhou, Z. F., R. Kumar, S. T. Thakur, L. R. Rudnick, H. H. Schobert, and S. N. Lvov, (2007). Direct Oxidation of Waste Vegetable Oil in Solid-Oxide Fuel Cells, Journal of Power Sources, v. 171, pp. 856-860.

Machesky, M. L., D. J. Wesolowski, D. A. Palmer, M. K. Ridley, P. Benezeth, S. N. Lvov, and M. V. Fedkin, (2006). Ion Adsorption into the Hydrothermal Regime: Experimental and Modeling Approaches, Ch.12, in Surface Complexation Modeling, ed. J. Lutzenkirchen, Elsevier, Amsterdam, pp. 324-358.

Strohm, J. J., J. Zheng, and C. S. Song, (2006). "Low-Temperature Steam Reforming of Jet Fuel in the Absence and Presence of Sulfur over Rh and Rh-Ni Catalysts for Fuel Cells," Journal of Catalysis, v. 238 (2), pp. 309-320.

Chalkova, E., M. B. Pague, M. V. Fedkin, D. J. Wesolowski, and S. N. Lvov, (2005). Nafion/TiO2 Proton Conductive Composite Membranes for PEM Fuel Cells Operating at Elevated Temperature and Reduced Relative Humidity, J. Electrochem. Soc, v. 152, A1035-A1040.

Chalkova, E., M. V. Fedkin, D. J. Wesolowski, and S. N. Lvov, (2005). Effect of TiO2 Surface Properties on Performance of Nafion-Based Composite Membranes in High Temperature and Low Relative Humidity PEM Fuel Cells, J. Electrochem. Soc. v. 152, pp. A1742.

Katikaneni, S. P., A. M. Gaffney, S. Ahmed, and C. S. Song, (2005). Recent Advances in Fuel Processing Catalysts for Fuel Cell Applications – Preface. Catalysis Today, v. 99, DE-j.cattod.2004.10.001, pp. 255-256.

Ma, X. L., M. Sprague, and C. S. Song, (2005). Deep Desulfurization if Gasoline by Selective Adsorption over Nickel-Based Adsorbent for Fuel Cell Applications, Industrial & Engineering Chemistry Research, v. 44, pp. 5768-5775, DE-ie0492810.

Ma, X. L., S. Velu, J. H. Kim, and C. S. Song, (2005). Deep Desulfurization of Gasoline by Selective Adsorption over Solid Adsorbents and Impact of Analytical Methods on ppm-level Sulfur Quantification for Fuel Cell Applications, Applied Catalysis B-Environmental, v. 56, pp. 137-147, DE-s10562-005-4901-7.

Velu, S., X. L. Ma, C. S. Song, M. Namazian, S. Sethuraman, and G. Venkataraman, (2005). Desulfurization of JP-8 Jet Fuel by Selective Adsorption over a Ni-based Adsorbent Mirco Solid Oxide Fuel Cells, Energy & Fuels, v. 19, pp. 1116-1125, DE-ef049800b.

Xu, X. C., I. Novochinskii, and C. S. Song, (2005). Low-temperature Removal of H2S by Nanoporous Composite of Polymer-mesoporous Molecular Sieve MCM-41 as Adsorbent for Fuel Cell Applications, Energy & Fuels, v. 19, pp. 2214-2215, DE-ef050061o.

Allcock, H. R., M. A. Hofmann, S. N. Lvov, D. D. Macdonald, and X. Y. Zhou, (2004 July 6). Proton Conducting Polymer Membranes, U. S. Patent 6,759,157 B1.

Novochinskii, I. I., C. S. Song, X. L. Ma, X. S. Liu, L. Shore, J. Lampert, and R. J. Farrauto, (2004). Low-temperature H2S Removal from Steam-containing Gas Mixtures with ZnO for Fuel Cell Application. 1. ZnO Particles and Extrudates, Energy & Fuels, v. 18, pp. 576-583, [DE-ef0301371].

Zhou, Z. F., C. Gallo, M. B. Pague, H. H. Schobert, and S. N. Lvov, (2004). Direct Oxidation of Jet Fuels and Pennsylvania Crude Oil in a Solid Oxide Fuel Cell, Journal of Power Sources, v. 133, pp. 181-187.

Zhou, X. Y., J. Weston, E. Chalkova, S. N. Lvov, M. Hofmann, C. M. Ambler, and H. R. Allcock, (2003). "High Temperature Transport Properties of Polyphosphazene Membranes for Direct Methanol Fuel Cells," Electrochimica Acta, v. 48, pp. 2173-218.

Allcock, H. R., M. A. Hofmann, C. M. Ambler, S. N. Lvov, X. Y. Zhou, E. Chalkova, and J. Weston, (2002). Phenylphosphonic Acid Functionalized Poly[aryloxyphosphazenes] as Proton-Conducting Membranes for Direct Methanol Fuel Cells, J. Membrane Science, v. 202, pp. 47-54.

Chalkova, E., X. Y. Zhou, C. M. Ambler, M. A. Hofmann, J. A. Weston, H. R. Allcock, and S. N. Lvov, (2002). Sulfonimide Polyphosphazene-Based Hydrogen/Oxygen Fuel Cells, Electrochemical and Solid State Letters, v. 10, pp. 221-223.

Chalkova, E., X. Y. Zhou, C.Ambler, M. A. Hofmann, J. A. Weston, and H. R. Allcock, (2002). Sulfonimide Polyphosphazene-Based H2 /O2 Fuel Cells, Electrochem. Solid-State Lett., v. 5, pp. A221-A222.

Hofmann, M. A., C. M. Ambler, A. E. Maher, E. Chalkova, X. Y. Zhou, S. N. Lvov, and H. R. Allcock, (2002). Synthesis of Polyphosphazenes with Sulfonimide Side Groups, Macromolecules, v. 35, pp. 6490-6493.

Ma, X. L, L. Sun, and C. S. Song, (2002). A New Approach to Deep Desulfurization of Gasoline, Diesel Fuel, and Jet Fuel by Selective Adsorption for Ultra-clean Fuels and Fuel for Fuel Cell Application, Catalysis Today, v. 77, pp. 107-116, DE-S0920-5861(02)00237-7.

Shen, J. P., and C. S. Song, (2002). Influence of Preparation Method on Performances of Cu/Zn-based Catalysts for Low-temperature Steam Reforming and Oxidative Steam Reforming of Methanol for H2 Production for Fuel Cells, Catalysis Today, v. 77, pp. 89-98, DE-S0920-5861(02)00235-3.

Song, C. S., (2002). Fuel Processing for Low-temperature and High-temperature Fuel Cells – Challenges, and Opportunities for Sustainable Development in the 21st Century, Catalysis Today, v. 77, pp. 17-49, DE-S0920-5861(02)00231-6.

Allcock, H. R., M. A. Hofmann, S. N. Lvov, X. Y. Zhou, E. Chalkova, and J. A. Weston, (2001). Phenyl Phosphonic Acid Functionalized Poly[aryloxyphosphazenes] as Proton-Conducting Membranes for Direct Methanol Fuel Cells, J. Membr. Sci., v. 201, pp. 47-54.

Basu, R. N., O. Altin, M. J. Mayo, C. A. Randall, and S. Eser, (2001). Pyrolytic Carbon Deposition on Porous Cathode Tubes and Its Use as an Interlayer for Solid Oxide Fuel Cell Zirconia Electrolyte Fabrication. Journal of the Electrochemical Society, v. 148, DE-1.136620, pp. A506-A512.

Lvov, S. N., R. Pastres, A. Sfriso, and A. Marcomini, (2000). Far–From–Equilibrium Thermodynamic Modelling of Aquatic Shallow Environments, Ch.29, in The Venice Lagoon Ecosystem. Input and Interactions Between Land and Sea, eds. P. Lasserre and A. Marzollo, Parthenon Publishing, pp. 481-496.

Lvov, S. N., and X. Y. Zhou, (1998). pH Measurements in Supercritical Hydrothermal Systems, Mineralogical Magazine, v. 62A, pp. 929-930.

Lvov, S. N., H. Gao, D. Kouznetsov, I. Balashov, and D. D. Macdonald, (1998). Potentiometric pH Measurements in High Subcritical and Supercritical Aqueous Solutions, Fluid Phase Equilibria, v. 150/151, pp. 515-523.

Lvov, S. N., M. M. Ulyanova, G. R. Engelhardt, and D. D. Macdonald, (1998). Importance of Thermal Diffusion in High Subcritical and Supercritical Aqueous Solutions, International Journal of Thermophysics, v. 19, pp. 1567-1575.

Lvov, S. N., and D. D. Macdonald, (1996). Estimation of the Thermal Liquid Junction Potential of an External Pressure Balanced Reference Electrode, Journal of Electroanalytical Chemistry, v. 403, pp. 25-30.

Lvov, S. N., R. Pastres, and A. Marcomini, (1996). Thermodynamic Stability Analysis of the Carbon Biogeochemical Cycle in Aquatic Shallow Environments, Geochimica et Cosmochimica Acta, v. 60, pp. 3569-3579.

Crovetto, R., S. N. Lvov, and R. H. Wood, (1993). Vapor pressures and densities of NaCl(aq) and KCl(aq) at the temperature 623 K and CaCl2(aq) at the temperature 623 K and 643 K, J. Chem. Thermod., v. 25, pp. 127-138.

Lvov, S. N., and R. H. Wood, (1990). Equation of state of aqueous NaCl-H2O system over a wide range of temperatures, pressures and concentrations, Fluid Phase Equil, v. 60, pp. 273-287.

Lvov, S. N., V. A. Umniashkin, A. Sharygin, and M. F. Holovko, (1990). The molecular statistical theory of infinitely dilute solutions based on the ion-dipole model with Lennard-Jones interaction, Fluid Phase Equilibria, v. 58, pp. 283-305.

Suprun, M. M., I. A. Dibrov, and S. N. Lvov, (1990). The initial temperature coefficients of the thermo-e.m.f. and entropy of transport of electrolytes in aqueous solutions, Russian Journal of Physical Chemistry, v. 64, pp. 1226-1231.

Suprun, M. M., I. I. Dibrov, and S. N. Lvov, (1990). The stationary temperature coefficients of the thermo-e.m.f. and the entropy of the moving bromide ion in potassium bromide solution, Russian Journal of Physical Chemistry, v. 64, pp. 232-1236.

Dibrov, I. A., M. M. Suprun, and S. N. Lvov, (1989). Activity coefficients of individual ions at high temperature, Russ. J. Phys. Chem., v. 63, pp. 3182-3185.

Rakhmilevich, Y. D., I. A. Dibrov, and S. N. Lvov, (1987). Thermoelectric studies of aqueous solutions of electrolytes, Effect of temperature on the entropy of transfer of the electrolyte and on the entropy of moving ion in solution, Russian Journal of Physical Chemistry, v. 61, pp. 2391-2396.

Rakhmilevich, Y. D., M. M. Suprun, S. N. Lvov, and I. A. Dibrov, (1987). Termoelectric studies of systems consisting of silver chloride electrodes and aqueous solutions of rubidium, cesium, and hydrogen chlorides, Russian Journal of Physical Chemistry, v. 61, pp. 554-556.