Ghezel-Ayagh, H., & Borglum, B. P. (2017). Review of Progress in Solid Oxide Fuel Cells at FuelCell Energy. ECS Transactions, 78(1), 77-86. doi:10.1149/07801.0077ecst
Park, B. H., & Choi, G. M. (2014). Ex-solution of Ni nanoparticles in a La0.2Sr0.8Ti1−xNixO3−δ alternative anode for solid oxide fuel cell. Solid State Ionics, 262, 345-348. doi:10.1016/j.ssi.2013.10.016
Chung, Y. S., Kim, T., Shin, T. H., Yoon, H., Park, S., Sammes, N. M., … Chung, J. S. (2017). In situ preparation of a La1.2Sr0.8Mn0.4Fe0.6O4 Ruddlesden–Popper phase with exsolved Fe nanoparticles as an anode for SOFCs. Journal of Materials Chemistry A, 5(14), 6437-6446. doi:10.1039/c6ta09692a
[+]
Ghezel-Ayagh, H., & Borglum, B. P. (2017). Review of Progress in Solid Oxide Fuel Cells at FuelCell Energy. ECS Transactions, 78(1), 77-86. doi:10.1149/07801.0077ecst
Park, B. H., & Choi, G. M. (2014). Ex-solution of Ni nanoparticles in a La0.2Sr0.8Ti1−xNixO3−δ alternative anode for solid oxide fuel cell. Solid State Ionics, 262, 345-348. doi:10.1016/j.ssi.2013.10.016
Chung, Y. S., Kim, T., Shin, T. H., Yoon, H., Park, S., Sammes, N. M., … Chung, J. S. (2017). In situ preparation of a La1.2Sr0.8Mn0.4Fe0.6O4 Ruddlesden–Popper phase with exsolved Fe nanoparticles as an anode for SOFCs. Journal of Materials Chemistry A, 5(14), 6437-6446. doi:10.1039/c6ta09692a
Sun, Y., Li, J., Zeng, Y., Amirkhiz, B. S., Wang, M., Behnamian, Y., & Luo, J. (2015). A-site deficient perovskite: the parent for in situ exsolution of highly active, regenerable nano-particles as SOFC anodes. Journal of Materials Chemistry A, 3(20), 11048-11056. doi:10.1039/c5ta01733e
Hu, Y., Bouffanais, Y., Almar, L., Morata, A., Tarancon, A., & Dezanneau, G. (2013). La2−xSrxCoO4−δ (x = 0.9, 1.0, 1.1) Ruddlesden-Popper-type layered cobaltites as cathode materials for IT-SOFC application. International Journal of Hydrogen Energy, 38(7), 3064-3072. doi:10.1016/j.ijhydene.2012.12.047
Li, Y., Zhang, W., Zheng, Y., Chen, J., Yu, B., Chen, Y., & Liu, M. (2017). Controlling cation segregation in perovskite-based electrodes for high electro-catalytic activity and durability. Chemical Society Reviews, 46(20), 6345-6378. doi:10.1039/c7cs00120g
Kharton, V. ., Yaremchenko, A. ., Shaula, A. ., Patrakeev, M. ., Naumovich, E. ., Logvinovich, D. ., … Marques, F. M. . (2004). Transport properties and stability of Ni-containing mixed conductors with perovskite- and K2NiF4-type structure. Journal of Solid State Chemistry, 177(1), 26-37. doi:10.1016/s0022-4596(03)00261-5
Skinner, S. (2000). Oxygen diffusion and surface exchange in La2−xSrxNiO4+δ. Solid State Ionics, 135(1-4), 709-712. doi:10.1016/s0167-2738(00)00388-x
Balachandran, P. V., Puggioni, D., & Rondinelli, J. M. (2013). Crystal-Chemistry Guidelines for Noncentrosymmetric A2BO4 Ruddlesden−Popper Oxides. Inorganic Chemistry, 53(1), 336-348. doi:10.1021/ic402283c
Autret, C., Martin, C., Hervieu, M., Retoux, R., Raveau, B., André, G., & Bourée, F. (2004). Structural investigation of Ca2MnO4 by neutron powder diffraction and electron microscopy. Journal of Solid State Chemistry, 177(6), 2044-2052. doi:10.1016/j.jssc.2004.02.012
Dailly, J., Fourcade, S., Largeteau, A., Mauvy, F., Grenier, J. C., & Marrony, M. (2010). Perovskite and A2MO4-type oxides as new cathode materials for protonic solid oxide fuel cells. Electrochimica Acta, 55(20), 5847-5853. doi:10.1016/j.electacta.2010.05.034
ZHAO, H., MAUVY, F., LALANNE, C., BASSAT, J., FOURCADE, S., & GRENIER, J. (2008). New cathode materials for ITSOFC: Phase stability, oxygen exchange and cathode properties of La2−xNiO4+δ. Solid State Ionics, 179(35-36), 2000-2005. doi:10.1016/j.ssi.2008.06.019
Yoo, Y.-S., Choi, M., Hwang, J.-H., Im, H.-N., Singh, B., & Song, S.-J. (2015). La2NiO4+δ as oxygen electrode in reversible solid oxide cells. Ceramics International, 41(5), 6448-6454. doi:10.1016/j.ceramint.2015.01.083
Das, A., Xhafa, E., & Nikolla, E. (2016). Electro- and thermal-catalysis by layered, first series Ruddlesden-Popper oxides. Catalysis Today, 277, 214-226. doi:10.1016/j.cattod.2016.07.014
Liping, S., Lihua, H., Hui, Z., Qiang, L., & Pijolat, C. (2008). La substituted Sr2MnO4 as a possible cathode material in SOFC. Journal of Power Sources, 179(1), 96-100. doi:10.1016/j.jpowsour.2007.12.090
Jin, C., Yang, Z., Zheng, H., Yang, C., & Chen, F. (2012). La0.6Sr1.4MnO4 layered perovskite anode material for intermediate temperature solid oxide fuel cells. Electrochemistry Communications, 14(1), 75-77. doi:10.1016/j.elecom.2011.11.008
Sandoval, M. V., Pirovano, C., Capoen, E., Jooris, R., Porcher, F., Roussel, P., & Gauthier, G. H. (2017). In-depth study of the Ruddlesden-Popper LaxSr2−xMnO4±δ family as possible electrode materials for symmetrical SOFC. International Journal of Hydrogen Energy, 42(34), 21930-21943. doi:10.1016/j.ijhydene.2017.07.062
Li-Ping, S., Qiang, L., Li-Hua, H., Hui, Z., Guo-Ying, Z., Nan, L., … Pijolat, C. (2011). Synthesis and performance of Sr1.5LaxMnO4 as cathode materials for intermediate temperature solid oxide fuel cell. Journal of Power Sources, 196(14), 5835-5839. doi:10.1016/j.jpowsour.2011.03.016
Shen, J., Yang, G., Zhang, Z., Zhou, W., Wang, W., & Shao, Z. (2016). Tuning layer-structured La0.6Sr1.4MnO4+δ into a promising electrode for intermediate-temperature symmetrical solid oxide fuel cells through surface modification. Journal of Materials Chemistry A, 4(27), 10641-10649. doi:10.1039/c6ta02986h
Thommy, L., Joubert, O., Hamon, J., & Caldes, M.-T. (2016). Impregnation versus exsolution: Using metal catalysts to improve electrocatalytic properties of LSCM-based anodes operating at 600 °C. International Journal of Hydrogen Energy, 41(32), 14207-14216. doi:10.1016/j.ijhydene.2016.06.088
Irvine, J. T. S., Neagu, D., Verbraeken, M. C., Chatzichristodoulou, C., Graves, C., & Mogensen, M. B. (2016). Evolution of the electrochemical interface in high-temperature fuel cells and electrolysers. Nature Energy, 1(1). doi:10.1038/nenergy.2015.14
Zhou, J., Shin, T.-H., Ni, C., Chen, G., Wu, K., Cheng, Y., & Irvine, J. T. S. (2016). In Situ Growth of Nanoparticles in Layered Perovskite La0.8Sr1.2Fe0.9Co0.1O4−δ as an Active and Stable Electrode for Symmetrical Solid Oxide Fuel Cells. Chemistry of Materials, 28(9), 2981-2993. doi:10.1021/acs.chemmater.6b00071
Hua, B., Li, M., Sun, Y.-F., Li, J.-H., & Luo, J.-L. (2017). Enhancing Perovskite Electrocatalysis of Solid Oxide Cells Through Controlled Exsolution of Nanoparticles. ChemSusChem, 10(17), 3333-3341. doi:10.1002/cssc.201700936
Yang, C., Li, J., Lin, Y., Liu, J., Chen, F., & Liu, M. (2015). In situ fabrication of CoFe alloy nanoparticles structured (Pr0.4Sr0.6)3(Fe0.85Nb0.15)2O7 ceramic anode for direct hydrocarbon solid oxide fuel cells. Nano Energy, 11, 704-710. doi:10.1016/j.nanoen.2014.12.001
Zhang, W., & Zheng, W. (2014). Exsolution-Mimic Heterogeneous Surfaces: Towards Unlimited Catalyst Design. ChemCatChem, 7(1), 48-50. doi:10.1002/cctc.201402757
Liu, S., Zhang, W., Deng, T., Wang, D., Wang, X., Zhang, X., … Zheng, W. (2017). Mechanistic Origin of Enhanced CO Catalytic Oxidation over Co3
O4
/LaCoO3
at Lower Temperature. ChemCatChem, 9(16), 3102-3106. doi:10.1002/cctc.201700937
Arrivé, C., Delahaye, T., Joubert, O., & Gauthier, G. (2013). Exsolution of nickel nanoparticles at the surface of a conducting titanate as potential hydrogen electrode material for solid oxide electrochemical cells. Journal of Power Sources, 223, 341-348. doi:10.1016/j.jpowsour.2012.09.062
Gao, Y., Chen, D., Saccoccio, M., Lu, Z., & Ciucci, F. (2016). From material design to mechanism study: Nanoscale Ni exsolution on a highly active A-site deficient anode material for solid oxide fuel cells. Nano Energy, 27, 499-508. doi:10.1016/j.nanoen.2016.07.013
Sun, Y.-F., Zhang, Y.-Q., Chen, J., Li, J.-H., Zhu, Y.-T., Zeng, Y.-M., … Luo, J.-L. (2016). New Opportunity for in Situ Exsolution of Metallic Nanoparticles on Perovskite Parent. Nano Letters, 16(8), 5303-5309. doi:10.1021/acs.nanolett.6b02757
Ouellette, R. J., & Rawn, J. D. (2014). Organometallic Chemistry of Transition Metal Elements and Introduction to Retrosynthesis. Organic Chemistry, 567-593. doi:10.1016/b978-0-12-800780-8.00017-6
Yaremchenko, A. A., Bannikov, D. O., Kovalevsky, A. V., Cherepanov, V. A., & Kharton, V. V. (2008). High-temperature transport properties, thermal expansion and cathodic performance of Ni-substituted LaSr2Mn2O7−δ. Journal of Solid State Chemistry, 181(11), 3024-3032. doi:10.1016/j.jssc.2008.07.038
Chupakhina, T. I., Bazuev, G. V., & Zabolotskaya, E. V. (2010). Synthesis and magnetic properties of a new layered oxide La1.5Sr1.5Mn1.25Ni0.75O6.67. Russian Journal of Inorganic Chemistry, 55(2), 247-253. doi:10.1134/s0036023610020178
Jardiel, T., Caldes, M. T., Moser, F., Hamon, J., Gauthier, G., & Joubert, O. (2010). New SOFC electrode materials: The Ni-substituted LSCM-based compounds (La0.75Sr0.25)(Cr0.5Mn0.5−xNix)O3−δ and (La0.75Sr0.25)(Cr0.5−xNixMn0.5)O3−δ. Solid State Ionics, 181(19-20), 894-901. doi:10.1016/j.ssi.2010.05.012
Svoboda, K., Siewiorek, A., Baxter, D., Rogut, J., & Pohořelý, M. (2008). Thermodynamic possibilities and constraints for pure hydrogen production by a nickel and cobalt-based chemical looping process at lower temperatures. Energy Conversion and Management, 49(2), 221-231. doi:10.1016/j.enconman.2007.06.036
Bhardwaj, A., Kaur, J., Wuest, M., & Wuest, F. (2017). In situ click chemistry generation of cyclooxygenase-2 inhibitors. Nature Communications, 8(1). doi:10.1038/s41467-016-0009-6
Zhu, J., Li, H., Zhong, L., Xiao, P., Xu, X., Yang, X., … Li, J. (2014). Perovskite Oxides: Preparation, Characterizations, and Applications in Heterogeneous Catalysis. ACS Catalysis, 4(9), 2917-2940. doi:10.1021/cs500606g
Broux, T., Prestipino, C., Bahout, M., Hernandez, O., Swain, D., Paofai, S., … Greaves, C. (2013). Unprecedented High Solubility of Oxygen Interstitial Defects in La1.2Sr0.8MnO4+δ up to δ ∼ 0.42 Revealed by In Situ High Temperature Neutron Powder Diffraction in Flowing O2. Chemistry of Materials, 25(20), 4053-4063. doi:10.1021/cm402194q
MUNNINGS, C., SKINNER, S., AMOW, G., WHITFIELD, P., & DAVIDSON, I. (2006). Structure, stability and electrical properties of the La(2−x)SrxMnO4±δ solid solution series. Solid State Ionics, 177(19-25), 1849-1853. doi:10.1016/j.ssi.2006.01.009
Li, R. K., & Greaves, C. (2000). Synthesis and Characterization of the Electron-Doped Single-Layer Manganite La1.2Sr0.8MnO4−δ and Its Oxidized Phase La1.2Sr0.8MnO4+δ. Journal of Solid State Chemistry, 153(1), 34-40. doi:10.1006/jssc.2000.8735
Wang, Y., Shih, K., & Jiang, X. (2012). Phase transformation during the sintering of γ-alumina and the simulated Ni-laden waste sludge. Ceramics International, 38(3), 1879-1886. doi:10.1016/j.ceramint.2011.10.015
Senff, D., Reutler, P., Braden, M., Friedt, O., Bruns, D., Cousson, A., … Revcolevschi, A. (2005). Crystal and magnetic structure ofLa1−xSr1+xMnO4: Role of the orbital degree of freedom. Physical Review B, 71(2). doi:10.1103/physrevb.71.024425
Larochelle, S., Mehta, A., Lu, L., Mang, P. K., Vajk, O. P., Kaneko, N., … Greven, M. (2005). Structural and magnetic properties of the single-layer manganese oxideLa1−xSr1+xMnO4. Physical Review B, 71(2). doi:10.1103/physrevb.71.024435
Bieringer, M., & Greedan, J. E. (2002). Structure and magnetism in BaLaMnO4 +/– δ (δ = 0.00, 0.10) and BaxSr1 – xLaMnO4. Disappearance of magnetic order for x > 0.30. Journal of Materials Chemistry, 12(2), 279-287. doi:10.1039/b104405m
Kitchen, H. J., Saratovsky, I., & Hayward, M. A. (2010). Topotactic reduction as a synthetic route for the preparation of low-dimensional Mn(II) oxide phases: The structure and magnetism of LaAMnO4-x (A = Sr, Ba). Dalton Transactions, 39(26), 6098. doi:10.1039/b923966a
Bandyopadhyay, J., & Gupta, K. P. (1977). Low temperature lattice parameter of nickel and some nickel-cobalt alloys and Grüneisen parameter of nickel. Cryogenics, 17(6), 345-347. doi:10.1016/0011-2275(77)90130-8
Lai, K.-Y., & Manthiram, A. (2018). Evolution of Exsolved Nanoparticles on a Perovskite Oxide Surface during a Redox Process. Chemistry of Materials, 30(8), 2838-2847. doi:10.1021/acs.chemmater.8b01029
Blasse, G. (1965). New compositions with K2NiF4 structure. Journal of Inorganic and Nuclear Chemistry, 27(12), 2683-2684. doi:10.1016/0022-1902(65)80178-6
Moritomo, Y., Tomioka, Y., Asamitsu, A., Tokura, Y., & Matsui, Y. (1995). Magnetic and electronic properties in hole-doped manganese oxides with layered structures:La1−xSr1+xMnO4. Physical Review B, 51(5), 3297-3300. doi:10.1103/physrevb.51.3297
Ganguly, P., & Rao, C. N. R. (1984). Crystal chemistry and magnetic properties of layered metal oxides possessing the K2NiF4 or related structures. Journal of Solid State Chemistry, 53(2), 193-216. doi:10.1016/0022-4596(84)90094-x
Benabad, A., Daoudi, A., Salmon, R., & Le Flem, G. (1977). Les phases SrLnMnO4 (Ln = La, Nd, Sm, Gd), BaLnMnO4 (Ln = La, Nd) et M1+xLa1−xMnO4 (M = Sr, Ba). Journal of Solid State Chemistry, 22(2), 121-126. doi:10.1016/0022-4596(77)90028-7
Wu, W. B., Huang, D. J., Guo, G. Y., Lin, H.-J., Hou, T. Y., Chang, C. F., … Jo, T. (2004). Orbital polarization of LaSrMnO4 studied by soft X-ray linear dichroism. Journal of Electron Spectroscopy and Related Phenomena, 137-140, 641-645. doi:10.1016/j.elspec.2004.02.072
GONZALEZDELACRUZ, V., HOLGADO, J., PERENIGUEZ, R., & CABALLERO, A. (2008). Morphology changes induced by strong metal–support interaction on a Ni–ceria catalytic system. Journal of Catalysis, 257(2), 307-314. doi:10.1016/j.jcat.2008.05.009
Dulub, O., Hebenstreit, W., & Diebold, U. (2000). Imaging Cluster Surfaces with Atomic Resolution: The Strong Metal-Support Interaction State of Pt Supported onTiO2(110). Physical Review Letters, 84(16), 3646-3649. doi:10.1103/physrevlett.84.3646
Wei, T., Jia, L., Zheng, H., Chi, B., Pu, J., & Li, J. (2018). LaMnO3-based perovskite with in-situ exsolved Ni nanoparticles: a highly active, performance stable and coking resistant catalyst for CO2 dry reforming of CH4. Applied Catalysis A: General, 564, 199-207. doi:10.1016/j.apcata.2018.07.031
A. Adamson A. Gat Physical Chemistry of Surfaces John Wiley & Sons Inc. New York 1997.
Oh, T.-S., Rahani, E. K., Neagu, D., Irvine, J. T. S., Shenoy, V. B., Gorte, R. J., & Vohs, J. M. (2015). Evidence and Model for Strain-Driven Release of Metal Nanocatalysts from Perovskites during Exsolution. The Journal of Physical Chemistry Letters, 6(24), 5106-5110. doi:10.1021/acs.jpclett.5b02292
Blander, M., & Katz, J. L. (1975). Bubble nucleation in liquids. AIChE Journal, 21(5), 833-848. doi:10.1002/aic.690210502
Kelchner, C. L., Plimpton, S. J., & Hamilton, J. C. (1998). Dislocation nucleation and defect structure during surface indentation. Physical Review B, 58(17), 11085-11088. doi:10.1103/physrevb.58.11085
Neagu, D., Tsekouras, G., Miller, D. N., Ménard, H., & Irvine, J. T. S. (2013). In situ growth of nanoparticles through control of non-stoichiometry. Nature Chemistry, 5(11), 916-923. doi:10.1038/nchem.1773
Raabe, O. G. (1971). Particle size analysis utilizing grouped data and the log-normal distribution. Journal of Aerosol Science, 2(3), 289-303. doi:10.1016/0021-8502(71)90054-1
Pauw, B. R., Kästner, C., & Thünemann, A. F. (2017). Nanoparticle size distribution quantification: results of a small-angle X-ray scattering inter-laboratory comparison. Journal of Applied Crystallography, 50(5), 1280-1288. doi:10.1107/s160057671701010x
Neagu, D., Oh, T.-S., Miller, D. N., Ménard, H., Bukhari, S. M., Gamble, S. R., … Irvine, J. T. S. (2015). Nano-socketed nickel particles with enhanced coking resistance grown in situ by redox exsolution. Nature Communications, 6(1). doi:10.1038/ncomms9120
Hansen, T. W., DeLaRiva, A. T., Challa, S. R., & Datye, A. K. (2013). Sintering of Catalytic Nanoparticles: Particle Migration or Ostwald Ripening? Accounts of Chemical Research, 46(8), 1720-1730. doi:10.1021/ar3002427
Lif, J., Skoglundh, M., & Löwendahl, L. (2002). Sintering of nickel particles supported on γ-alumina in ammonia. Applied Catalysis A: General, 228(1-2), 145-154. doi:10.1016/s0926-860x(01)00957-7
Agüero, F. N., Beltrán, A. M., Fernández, M. A., & Cadús, L. E. (2019). Surface nickel particles generated by exsolution from a perovskite structure. Journal of Solid State Chemistry, 273, 75-80. doi:10.1016/j.jssc.2019.02.036
Asoro, M. A., Ferreira, P. J., & Kovar, D. (2014). In situ transmission electron microscopy and scanning transmission electron microscopy studies of sintering of Ag and Pt nanoparticles. Acta Materialia, 81, 173-183. doi:10.1016/j.actamat.2014.08.028
Girona, K., Sailler, S., Gélin, P., Bailly, N., Georges, S., & Bultel, Y. (2014). Modelling of gradual internal reforming process over Ni-YSZ SOFC anode with a catalytic layer. The Canadian Journal of Chemical Engineering, 93(2), 285-296. doi:10.1002/cjce.22113
W. K. B. W. Ramli Exsolved Base Metal Catalyst Systems with Anchored Nanoparticles for Carbon Monoxide (CO) and Nitric Oxides (NO Oxidation Newcastle University 2017.
Sadykov, V., Mezentseva, N., Alikina, G., Bunina, R., Pelipenko, V., Lukashevich, A., … Rietveld, B. (2009). Nanocomposite catalysts for internal steam reforming of methane and biofuels in solid oxide fuel cells: Design and performance. Catalysis Today, 146(1-2), 132-140. doi:10.1016/j.cattod.2009.02.035
Atkinson, A., Barnett, S., Gorte, R. J., Irvine, J. T. S., McEvoy, A. J., Mogensen, M., … Vohs, J. (2004). Advanced anodes for high-temperature fuel cells. Nature Materials, 3(1), 17-27. doi:10.1038/nmat1040
Dicks, A. . (1998). Advances in catalysts for internal reforming in high temperature fuel cells. Journal of Power Sources, 71(1-2), 111-122. doi:10.1016/s0378-7753(97)02753-5
Roy, P. S., Park, N.-K., & Kim, K. (2014). Metal foam-supported Pd–Rh catalyst for steam methane reforming and its application to SOFC fuel processing. International Journal of Hydrogen Energy, 39(9), 4299-4310. doi:10.1016/j.ijhydene.2014.01.004
Postole, G., Bosselet, F., Bergeret, G., Prakash, S., & Gélin, P. (2014). On the promoting effect of H2S on the catalytic H2 production over Gd-doped ceria from CH4/H2O mixtures for solid oxide fuel cell applications. Journal of Catalysis, 316, 149-163. doi:10.1016/j.jcat.2014.05.011
Cheah, S. K., Massin, L., Aouine, M., Steil, M. C., Fouletier, J., & Gélin, P. (2018). Methane steam reforming in water deficient conditions on Ir/Ce0.9Gd0.1O2-x catalyst: Metal-support interactions and catalytic activity enhancement. Applied Catalysis B: Environmental, 234, 279-289. doi:10.1016/j.apcatb.2018.04.048
Bartholomew, C. H. (1982). Carbon Deposition in Steam Reforming and Methanation. Catalysis Reviews, 24(1), 67-112. doi:10.1080/03602458208079650
M. P. Pechini Method of Preparing Lead and Alkaline Earth Titanates and Niobates and Coating Method Using the Same to Form a Capacitor 1967 US3330697 A.
Petříček, V., Dušek, M., & Palatinus, L. (2014). Crystallographic Computing System JANA2006: General features. Zeitschrift für Kristallographie - Crystalline Materials, 229(5). doi:10.1515/zkri-2014-1737
[-]