Understanding the effect of oxide components on proton mobility in phosphate glasses using a statical analysis approach
暂无分享,去创建一个
[1] J. Nishii,et al. Ultra-thin phosphate glass exhibiting high proton conductivity at intermediate temperatures , 2020 .
[2] Binghui Deng,et al. Machine learning on density and elastic property of oxide glasses driven by large dataset , 2020 .
[3] Yong-il Park,et al. Proton-conducting BaO-P2O5 and BaO-La2O3-Al2O3-P2O5 glass thin films , 2020 .
[4] J. Nishii,et al. Transport properties of proton conducting phosphate glass: An electrochemical hydrogen pump enabling the formation of dry hydrogen gas , 2019, International Journal of Hydrogen Energy.
[5] J. Nishii,et al. Proton transport properties of proton-conducting phosphate glasses at their glass transition temperatures. , 2019, Physical chemistry chemical physics : PCCP.
[6] Mathieu Bauchy,et al. Predicting Young's modulus of oxide glasses with sparse datasets using machine learning , 2019, Journal of Non-Crystalline Solids.
[7] J. Nishii,et al. Proton-conducting phosphate glass and its melt exhibiting high electrical conductivity at intermediate temperatures , 2018 .
[8] Y. Kimura,et al. Energy efficiency of ionic transport through proton conducting ceramic electrolytes for energy conversion applications , 2018 .
[9] J. Nishii,et al. The mobility of proton carriers in phosphate glasses depends on polymerization of the phosphate framework. , 2017, Physical chemistry chemical physics : PCCP.
[10] H. Sumi. Valency effects of cation dopant on ultraphosphate glass electrolytes for intermediate temperature fuel cells , 2017 .
[11] J. Nishii,et al. Effect of alkaline-earth species in phosphate glasses on the mobility of proton carriers , 2017 .
[12] Yunjie Huang,et al. Bismuth phosphates as intermediate temperature proton conductors: From polycrystalline powders to amorphous glasses , 2017 .
[13] A. Hayashi,et al. Development of Sulfide Solid Electrolytes and Interface Formation Processes for Bulk-Type All-Solid-State Li and Na Batteries , 2016, Front. Energy Res..
[14] J. Nishii,et al. Relationship between structure and mobility of proton carriers injected by electrochemical substitution of sodium ions with protons in 35NaO1/2-1 WO3-8NbO5/2-5LaO3/2-51PO5/2-based glasses , 2016 .
[15] C. Angell,et al. A flexible all-inorganic fuel cell membrane with conductivity above Nafion, and durable operation at 150 °C , 2016 .
[16] J. Nishii,et al. Phase separation and crystallization in sodium lanthanum phosphate glasses induced by electrochemical substitution of sodium ions with protons. , 2015, Physical chemistry chemical physics : PCCP.
[17] T. Kasuga,et al. Proton conduction of MO-P2O5 glasses (M = Zn, Ba) containing a large amount of water , 2015 .
[18] J. Nishii,et al. Improving thermal stability and its effects on proton mobility in proton-conducting phosphate glasses prepared by the electrochemical substitution of sodium ions with protons , 2015 .
[19] J. Nishii,et al. Proton conducting tungsten phosphate glass and its application in intermediate temperature fuel cells , 2014 .
[20] J. Nishii,et al. Electrochemical substitution of sodium ions with protons in phosphate glass to fabricate pure proton conducting glass at intermediate temperatures , 2014 .
[21] C. Angell,et al. A novel, easily synthesized, anhydrous derivative of phosphoric acid for use in electrolyte with phosphoric acid-based fuel cells , 2013 .
[22] T. Yazawa,et al. The state of POnb non-bridging oxygen and proton incorporation in binary MO·P2O5 (M = Ca, Mg) phosphate glasses , 2013 .
[23] Y. Daiko. Proton conduction in glasses prepared via sol–gel and melting techniques , 2013 .
[24] I. Moussaoui,et al. Thermodynamic and relative approach to compute glass-forming ability of oxides , 2013, Bulletin of Materials Science.
[25] Nerea Mascaraque,et al. Effect of alumina on the structure and properties of Li2O-B2O3-P2O5 glasses , 2011 .
[26] Steve W. Martin,et al. Three-dimensional structure of multicomponent (Na2O)0.35 [(P2O5)1 − x(B2O3)x]0.65 glasses by high-energy x-ray diffraction and constrained reverse Monte Carlo simulations , 2011, Journal of physics. Condensed matter : an Institute of Physics journal.
[27] David R. Tallant,et al. Structural design of sealing glasses , 1997 .
[28] M. Hanaya,et al. Glass structure and energetic environment around conducting Ag+ ion in AgI-based fast ion conducting glasses (AgI)x (AgPO3)1−x studied by calorimetry and dielectric measurement , 1994 .
[29] H. Hosono,et al. Protonic Conduction in Phosphate Glasses , 1994 .
[30] I. Kozhevnikov,et al. Homogeneous catalysts based on heteropoly acids (review) , 1983 .
[31] J. Mackenzie,et al. Direct calculation of Young's moidulus of glass , 1973 .
[32] J. Nishii,et al. Electrochemical Substitution of Sodium Ions in Tungsten Phosphate Glass with Protons , 2013 .
[33] Kentaro Takahashi. Applicaton of New Factors for Calculating Expansion Coefficients of Silicate and Borosilicate Glasses , 1955 .