All Stories

  1. Facile synthesis and electrochemical performance of the nanoscaled FeP anode
  2. Towards understanding the rate capability of layered transition metal oxides LiNiyMnyCo1−2yO2
  3. A β-VOPO4/ε-VOPO4 composite Li-ion battery cathode
  4. Understanding the stability of MnPO4
  5. ChemInform Abstract: Layered Molybdenum (Oxy)pyrophosphate a Cathode for Lithium‐Ion Batteries.
  6. An Organic Coprecipitation Route to Synthesize High Voltage LiNi0.5Mn1.5O4
  7. The nanostructure of the Si–Al eutectic and its use in lithium batteries
  8. Layered Molybdenum (Oxy)Pyrophosphate as Cathode for Lithium-Ion Batteries
  9. ChemInform Abstract: The Structural and Electrochemical Impact of Li and Fe Site Substitution in LiFePO4.
  10. Study of the Transition Metal Ordering in Layered NaxNix/2Mn1–x/2O2 (2/3 ≤ x ≤ 1) and Consequences of Na/Li Exchange
  11. The Structural and Electrochemical Impact of Li and Fe Site Substitution in LiFePO4
  12. Introduction and Foreword to Focus Issue on Intercalation Compounds for Rechargeable Batteries
  13. Elucidating the Nature of Pseudo Jahn–Teller Distortions in LixMnPO4: Combining Density Functional Theory with Soft and Hard X-ray Spectroscopy
  14. Formation processes of high-dimensional MoO frameworks in tetrakis(2-hydroxypropane-1,3-diaminium) hexatriacontamolybdate hydrate (C3H12N2O)4[Mo36O112(H2O)16-m]·nH2O crystals: Solid-phase structural conversions under restricted dehydration conditions
  15. Preparation of Nanoribbons of Blue Potassium Molybdenum Bronze
  16. Electrochemical Behavior of Nanostructured  -VOPO4 over Two Redox Plateaus
  17. Why Substitution Enhances the Reactivity of LiFePO4
  18. The tortoise and the hare
  19. Spin-Transfer Pathways in Paramagnetic Lithium Transition-Metal Phosphates from Combined Broadband Isotropic Solid-State MAS NMR Spectroscopy and DFT Calculations
  20. The 18th International Conference on Solid State Ionics (SSI-18)
  21. Structure and Electrochemistry of Vanadium-Modified LiFePO4
  22. Composition-Structure Relationships in the Li-Ion Battery Electrode Material LiNi0.5Mn1.5O4
  23. Nanoscale alloying effect of gold–platinum nanoparticles as cathode catalysts on the performance of a rechargeable lithium–oxygen battery
  24. History, Evolution, and Future Status of Energy Storage
  25. High‐Performance LiNi0.5Mn1.5O4 Spinel Controlled by Mn3+ Concentration and Site Disorder
  26. Enhanced Li+ ion transport in LiNi0.5Mn1.5O4 through control of site disorder
  27. Structure, defects and thermal stability of delithiated olivine phosphates
  28. Stability and Rate Capability of Al Substituted Lithium-Rich High-Manganese Content Oxide Materials for Li-Ion Batteries
  29. Oxygen and transition metal involvement in the charge compensation mechanism of LiNi1/3Mn1/3Co1/3O2 cathodes
  30. Crystal Structure, Physical Properties, and Electrochemistry of Copper Substituted LiFePO4 Single Crystals
  31. Can Vanadium Be Substituted into LiFePO4?
  32. High performance Si/MgO/graphite composite as the anode for lithium-ion batteries
  33. ChemInform Abstract: What Can We Learn About Battery Materials from Their Magnetic Properties?
  34. Conversion Reaction Mechanisms in Lithium Ion Batteries: Study of the Binary Metal Fluoride Electrodes
  35. A novel lithium copper iron phosphate with idealized formula Li5Cu22+Fe3+(PO4)4: crystal structure and distribution of defects
  36. ChemInform Abstract: Iron and Manganese Pyrophosphates as Cathodes for Lithium‐Ion Batteries.
  37. Electrochemical performance of Al–Si–graphite composite as anode for lithium–ion batteries
  38. Electrochemical performances of LiMnPO4 synthesized from non-stoichiometric Li/Mn ratio
  39. Structure and Stability of Olivine Phase FePO4
  40. Tin-Iron Based Nano-Materials as Anodes for Li-Ion Batteries
  41. What can we learn about battery materials from their magnetic properties?
  42. Comparative Study of the Capacity and Rate Capability of LiNiyMnyCo1–2yO2 (y = 0.5, 0.45, 0.4, 0.33)
  43. Iron and Manganese Pyrophosphates as Cathodes for Lithium-Ion Batteries
  44. Extremely Durable High‐Rate Capability of a LiNi0.4Mn0.4Co0.2O2 Cathode Enabled with Single‐Walled Carbon Nanotubes
  45. ChemInform Abstract: Synthesis, Crystal Structure, and Structural Conversion of Ni Molybdate Hydrate NiMoO4·nH2O.
  46. Introduction
  47. Synthesis, crystal structure, and structural conversion of Ni molybdate hydrate NiMoO4·nH2O
  48. Cytotoxicity of nanostructured vanadium oxide on human cells in vitro
  49. Electrochemical Behavior of the Amorphous Tin–Cobalt Anode
  50. Influence of Manganese Content on the Performance of LiNi0.9−yMnyCo0.1O2 (0.45 ≤ y ≤ 0.60) as a Cathode Material for Li-Ion Batteries
  51. Cobalt Complex as Building Blocks: Synthesis, Characterization, and Catalytic Applications of {Cd2+−Co3+−Cd2+} and {Hg2+−Co3+−Hg2+} Heterobimetallic Complexes
  52. ChemInform Abstract: Transition Metal Tetramolybdate Dihydrates MMo4O13×2H2O (M: Co, Ni) Having a Novel Pillared Layer Structure.
  53. Electrospun nano-vanadium pentoxide cathode
  54. Vanadium Modified LiFePO[sub 4] Cathode for Li-Ion Batteries
  55. Layered vanadium and molybdenum oxides: batteries and electrochromics
  56. Copper pyrazole directed crystallization of decavanadates: synthesis and characterization of {Cu(pz)}4[{Cu(pz)3}2V10O28] and (Hpz)2[{Cu(pz)4}2V10O28...
  57. Transition metal tetramolybdate dihydrates MMo4O13·2H2O (M=Co,Ni) having a novel pillared layer structure
  58. Layered Mixed Transition Metal Oxide Cathodes with Reduced Cobalt Content for Lithium Ion Batteries
  59. Nanoscale single-crystal vanadium oxides with layered structure by electrospinning and hydrothermal methods
  60. Structural study of ammonium metatungstate
  61. Synthesis and characterization of layered and scrolled amine-templated vanadium oxides
  62. Electrical Energy Storage Using Flywheels
  63. Materials Challenges Facing Electrical Energy Storage
  64. The hydrothermal synthesis and characterization of olivines and related compounds for electrochemical applications
  65. Inorganic nanomaterials for batteries
  66. Hydrothermal synthesis of cathode materials
  67. Pol Popovic Karic y Fidel Chávez Pérez, eds.José EmilioPacheco: Perspectivas críticas. México: Siglo XXI y ITESM, 2006. 332 pp.
  68. Layered LixNiyMnyCo1-2yO2 Cathodes for Lithium Ion Batteries:  Understanding Local Structure via Magnetic Properties
  69. Tungsten based electrocatalyst for fuel cell applications
  70. Pinned Low-Energy Electronic Excitation in Metal-Exchanged Vanadium Oxide Nanoscrolls
  71. Structural and electrochemical behavior of LiMn0.4Ni0.4Co0.2O2
  72. Formation of magnetic clusters in the strongly frustrated hollandite vanadium oxide V 7.22 O 8 ( O H ) 8 Cl 0.77 ( H 3 O ) 2.34
  73. Characterization of Amorphous and Crystalline Tin–Cobalt Anodes
  74. How Molecules Turn into Solids:  the Case of Self-Assembled Metal−Organic Frameworks
  75. Hydrothermal synthesis of copper coordination polymers based on molybdates: Chemistry issues
  76. Hydrothermal synthesis of lithium iron phosphate
  77. Structure-inheriting solid-state reactions under hydrothermal conditions
  78. Iron Phosphates as Cathodes of Lithium-Ion Batteries
  79. Nanosized Amorphous Materials as Anodes for Lithium Batteries
  80. The Hydrothermal Synthesis of Lithium Iron Phosphate
  81. Magnetic Studies of Layered Cathode Materials for Lithium Ion Batteries
  82. Influence of Lithium Content on Performance of Layered Li1+z[Ni0.45Mn0.45Co0.1]1-zO2 in Lithium Ion Batteries
  83. Transgresiones ecfrásticas: El texto y la imagen en Los herederos de Segismundo de Schmidhuber de la Mora
  84. Phosphoric acid imidazolium dihydrogenphosphate
  85. Crystal structure of cobalt molybdate hydrate CoMoO4·nH2O
  86. ε‐VOPO4: Electrochemical Synthesis and Enhanced Cathode Behavior.
  87. Synthesis, Crystal Structure, and Electrochemical and Magnetic Study of New Iron (III) Hydroxyl-Phosphates, Isostructural with Lipscombite
  88. Synthesis of vanadium oxide nanofibers and tubes using polylactide fibers as template
  89. ε-VOPO[sub 4]: Electrochemical Synthesis and Enhanced Cathode Behavior
  90. Some transition metal (oxy)phosphates and vanadium oxides for lithium batteries
  91. Hydrothermal synthesis of potassium molybdenum oxide bronzes: structure-inheriting solid-state route to blue bronze and dissolution/deposition route to red bronze
  92. Lithium Batteries and Cathode Materials
  93. Structural chemistry of new lithium bis(oxalato)borate solvates
  94. Solitary excitations and domain-wall movement in the two-dimensional canted antiferromagnet ( C 2 N 2 H 10 ) 1 ∕ 2 Fe P O 4 ( O H )
  95. Introduction:  Batteries and Fuel Cells
  96. Lithium Batteries and Cathode Materials
  97. Tetrakis(tetramethylammonium) di-μ-sulfato-bis[oxosulfatovanadate(V)]
  98. Hydrogen motion in oxides: from insulators to bronzes
  99. K2Mo4O13 phases prepared by hydrothermal synthesis
  100. Structure beyond Bragg: Study of V 2 O 5 nanotubes
  101. Synthesis and Characterization of a New Layered Ethylene‐Diammonium Manganese(II) Phosphate, (C2N2H10)Mn2 (PO4)2×2H2O.
  102. Synthesis and Characterization of New Iron and Zinc Phosphate Materials with Open Framework
  103. Effect of Sheet Distance on the Optical Properties of Vanadate Nanotubes
  104. Structural and Electrochemical Properties of LiMn0.4Ni0.4Co0.2O2
  105. Anode Hosts for Lithium Batteries: Revisiting Tin and Aluminum
  106. Magnetic Properties of a New One-Dimensional Vanadium Oxide with the Hollandite Structure.
  107. The synthesis, characterization and electrochemical behavior of the layered LiNi0.4Mn0.4Co0.2O2 compound
  108. Synthesis, crystal structures and magnetic properties of organically templated new layered vanadates: [C4H8NH2]V3O7, [(CH3)2NH2]V3O7, [C5H10NH2]V3O7 and [C2H5NH3]V3O7
  109. Structures of potassium, sodium and lithium bis(oxalato)borate salts from powder diffraction data
  110. Synthesis and Characterization of a New Layered Ethylene-Diammonium Manganese(II) Phosphate, (C2N2H10)Mn2(PO4)2·2H2O
  111. Comparison of one-, two-, and three-dimensional iron phosphates containing ethylenediamine
  112. Anodes for lithium batteries: tin revisited
  113. Performance of LiFePO4 as lithium battery cathode and comparison with manganese and vanadium oxides
  114. New Iron(III) Phosphate Phases: Crystal Structure and Electrochemical and Magnetic Properties.
  115. Solvothermal synthesis and characterization of a layered pyridinium vanadate, (C5H6N)V3O7
  116. Vanadium Oxide Nanofibers and Vanadium Oxide Polyaniline Nanocomposite: Preparation, Characterization and Electrochemical Behavior
  117. Two novel open-framework zinc phosphates: (CH3NH3)Zn4(PO4)3 and (CH3NH3)2Zn5(PO4)4Electronic supplementary information (ESI) available: tables for atomic coordinates and anisotropic parameters and full list of bond lengths and bond angles. See http://w...
  118. The one dimensional chain structures of vanadyl glycolate and vanadyl acetateElectronic supplementary information (ESI) available: difference plots and reflections lists for VO(CH3COO)2 and VO(OCH2CH2O). See http://www.rsc.org/suppdata/jm/b2/b208100h/
  119. New Iron(III) Phosphate Phases:  Crystal Structure and Electrochemical and Magnetic Properties
  120. Transition Metal Oxides: Stoichiometry and Hydrothermal Synthesis for Intercalation Reactions
  121. ChemInform Abstract: Vaporization Thermodynamics and Heat Capacities of Cr3Ge and Cr5Ge3.
  122. Temperature-dependent properties of FePO4 cathode materials
  123. The zinc–vanadium–oxygen–water system: hydrothermal synthesis and characterization
  124. Hydrothermal Synthesis of the Blue Potassium Molybdenum Bronze, K0.28MoO3
  125. Synthesis of Novel Vanadium Oxide Nanotubes and Nanofibers
  126. New Iron (III) Hydroxyl-Phosphate with Rod-packing Structure as Intercalation Materials
  127. Sn and SnBi Foil as Anode Materials for Secondary Lithium Battery
  128. The first example of a novel one-dimensional cyclic tetrameric metavanadate: [PPh4]2V4O11
  129. Synthesis and Characterization of New Iron and Zinc Phosphate Materials with Open Framework
  130. The Syntheses and Characterization of Layered LiNi1-y-zMnyCozO2 Compounds
  131. Control of the structure and properties of vanadium and manganese oxides through tailored soft synthesis
  132. Vaporization thermodynamics and heat capacities of Cr3Ge and Cr5Ge3
  133. Manganese Vanadium Oxide Nanotubes:  Synthesis, Characterization, and Electrochemistry
  134. Hydrothermal synthesis of lithium iron phosphate cathodes
  135. Superparamagnetic behavior in a Ni vermiculite intercalation compound
  136. ChemInform Abstract: Li2Sn(OH)6.
  137. Synthesis and properties of the polyanisidines
  138. The role of tetraethyl ammonium hydroxide on the phase determination and electrical properties of γ-MnOOH synthesized by hydrothermal
  139. Copolymers of aniline and nitroanilines
  140. Li2Sn(OH)6
  141. Nanocomposite Electrodes for Advanced Lithium Batteries: The LiFePO4 Cathode
  142. Vanadium Oxide Nanotubes: Characterization and Electrochemical Behavior
  143. Sodium trivanadium(III) bis(sulfate) hexahydroxide
  144. Insertion electrodes as SMART materials: the first 25 years and future promises
  145. Manganese dioxides as cathodes for lithium rechargeable cells: the stability challenge
  146. Solid Electrolytes: Advances in Science and Technology
  147. Science and Applications of Mixed Conductors for Lithium Batteries
  148. Vanadium Oxide Frameworks Modified with Transition Metals
  149. Manganese Vanadium Oxide Compounds as Cathodes for Lithium Batteries
  150. Hydrothermal synthesis and electrochemistry of a δ-type manganese vanadium oxide
  151. Crystal structure of layered bis(ethylenediamine)nickel hexavanadate as a new representative of the V6O14 series
  152. Hydrothermal synthesis and electrochemistry of a manganese vanadium oxide, γ-MnV2O5
  153. Structural chemistry of vanadium oxides with open frameworks
  154. ChemInform Abstract: Hydrothermal Synthesis of Vanadium Oxides
  155. Low-temperature Synthesis Routes of Alkali-metal Molybdenum Bronzes.
  156. Modified Sol-Gel Synthesis of Vanadium Oxide Nanocomposites Containing Surfactant Ions
  157. Synthesis and Characterization of Manganese Vanadium Oxides as Cathodes in Lithium Batteries
  158. Synthesis and characterization of a pipe-structure manganese vanadium oxide by hydrothermal reaction
  159. The stabilization of layered Manganese Oxides for use in Rechargeable Lithium Batteries
  160. The hydrothermal synthesis of the new manganese and vanadium oxides, NiMnO3H, MAV3O7 and MA0.75V4O10·0.67H2O (MA=CH3NH3)
  161. Tetrakis(tetramethylammonium) Dihydrogendecavanadate Acetic Acid 2.8-Hydrate, [N(CH3)4]4[H2V10O28].CH3COOH.2.8H2O
  162. The Inserting Host–Guest System in [N(CH3)4]8[(CH3COO)V22O54].4.25H2O
  163. ChemInform Abstract: Structure of Hydrated Tungsten Peroxides [WO2(O2)H2O]×nH2O.
  164. Hydrothermal Synthesis of Vanadium Oxides
  165. Layered Structure of Lithium Ethylene Glycolate, Li(OCH2CH2OH)
  166. Structure of Hydrated Tungsten Peroxides [WO2(O2)H2O]·nH2O
  167. The Relationship between Structure and Cell Properties of the Cathode for Lithium Batteries
  168. ChemInform Abstract: A New Zinc Pyrovanadate, Zn3 (OH)2V2O7×2H2O, from X‐Ray Powder Data.
  169. The Computer as a Materials Science Benchmark
  170. Materials Crystal Chemistry By Relva C. Buchanan and Taeun Park (University of Cincinnati). Marcel Dekker: New York. 1997. vii + 462 pp. $175.00. ISBN:  0-8247-9798-1.
  171. Synthesis and Characterization of Nickel and Manganese Vanadium Oxides
  172. The Hydrothermal Synthesis of KzMnO2 in the Presence of Citric Acid
  173. Sulfone Containing Clay Electrolytes and Their Potential for Li-Rechargeable Batteries
  174. MoV–MoVIcationic ordering in the layered molybdate (C2H10N2)[Mo4O12]
  175. A Study of The Li|LixV2O4 Cell
  176. Hydrothermal synthesis and characterization of a new aluminium vanadium oxide hydroxide Al2(OH)3(VO4)
  177. A New Zinc Pyrovanadate, Zn3(OH)2V2O7.2H2O, from X-ray Powder Data
  178. The Layered Methylammonium Molybdate (NH3CH3)2[Mo7O22] from X-ray Powder Data
  179. 25/100 25 years for the solid state ionics community the 100th volume of solid state ionics
  180. ChemInform Abstract: Cathodic Behavior of Alkali Manganese Oxides from Permanganate.
  181. Layered Tetramethylammonium Vanadium Oxide [N(CH3)4]V3O7by X-ray Rietveld Refinement
  182. Hydrothermal synthesis of iron and zinc double vanadium oxddes using the tetramethyl ammonium ion
  183. Evidence for Decavanadate Clusters in the Lamellar Surfactant Ion Phase
  184. A New Decavanadate with Mixed Cations, [Li(H2O)4]2[N(CH3)4]4[V10O28].4H2O
  185. The intercalation and hydrothermal chemistry of solid electrodes
  186. Hydrothermal Synthesis and Characterization of A Series of Novel Zinc Vanadium Oxides as Cathode Materials
  187. Synthesis and characterization of a new vanadium oxide, TMAV8 O20
  188. The Hydrothermal Synthesis and Characterization of New Organically Templated Layered Vanadium Oxides by Methylamine
  189. Crystal structure of tetrasodium bis(tetramethylammonium) decavanadate icosahydrate,Na4(N(CH3)4)2(V10O28)(H2O)20
  190. NMe4V3O7: critical role of pH in hydrothermal synthesis of vanadium oxides
  191. ChemInform Abstract: Hydrothermal Synthesis and Characterization of KxMnO2×yH2O.
  192. The hydrothermal synthesis of sodium manganese oxide and a lithium vanadium oxide
  193. Hydrothermal synthesis of transition metal oxides under mild conditions
  194. Keggin Cluster Formation by Hydrothermal Reaction of Tungsten Trioxide with Methyl Substituted Ammonium: The Crystal Structure of Two Novel Compounds, [NH2(CH3)2]6H2W12O40· ∼4H2O and [N(CH3)4]6H2W12O40· 2H2O
  195. Hydrothermal Synthesis of Vanadium Oxides
  196. Solid State Electrochemistry
  197. Hydrothermal Synthesis of Novel Vanadium Oxides
  198. New Manganese Oxides by Hydrothermal Reaction of Permanganates
  199. Fluorophlogopite and Taeniolite: Synthesis and Nanocomposite Formation
  200. Low Temperature Synthesis of Lamellar Transition Metal Oxides Containing Surfactant Ions
  201. Novel Tungsten, Molybdenum, and Vanadium Oxides Containing Surfactant Ions
  202. Crystal structure of tetramethylammonium tetravanadium decaoxide, N(CH3)4V4O10
  203. Metastable Hexagonal Molybdates: Hydrothermal Preparation, Structure, and Reactivity
  204. Hydrothermal synthesis of electrode materials pyrochlore tungsten trioxide film
  205. ChemInform Abstract: Preparation and Characterization of a MoO3 with Hexagonal Structure.
  206. Substituted β‐Aluminas
  207. The hydrothermal synthesis of new oxide materials
  208. ChemInform Abstract: Hydrothermal Synthesis of a New Molybdate with a Layered Structure, ( NMe4)Mo4‐δO12.
  209. ChemInform Abstract: Tungsten Oxides and Bronzes: Synthesis, Diffusion and Reactivity
  210. Hydrothermal Synthesis of a New Molybdate with a Layered Structure, (NMe4)Mo4-.delta.O12
  211. Hydrothermal Synthesis of New Oxide Materials Using the Tetramethyl Ammonium Ion
  212. TUNGSTEN OXIDES AND BRONZES: SYNTHESIS, DIFFUSION AND REACTIVITY
  213. Hydrothermal synthesis of new metastable phases: preparation and intercalation of a new layered titanium phosphate
  214. Variable-range-hopping conduction and the Poole-Frenkel effect in a copper polyaniline vermiculite intercalation compound
  215. Solid polymer electrolytesFundamentals and Technological Applications, Fiona M. Gray, VCH Publishers (1991), 245 pages. ISBN 0-89573-772-8, £44.00, DM 128.00.
  216. Solid state ionicsM. Balkanski, T. Takahashi and H.L. Tuller, Editors, North-Holland (1992), 669 pages. ISBN 0-444-89354-7. US $ 157.00, Dfl. 275.00.
  217. III–V microelectronicsJ.P. Norgier, editor, North-Holland, Elsevier Science Publishers (1991), 514 pages. ISBN 0-444-88990-6, US $ 141.00, Dfl. 275.00
  218. Microionics: Solid-state integrable batteriesM. Balkanski, Editor, North-Holland (1991), 512 pages. ISBN 0-444-88853-5. US $ 179.50, Dfl. 350.00.
  219. Intercalation Compounds
  220. Materials chemistry companion to general chemistry. An update
  221. ChemInform Abstract: Rietveld Analysis of NaxWO3+x/2×yH2O, Which Has the Hexagonal Tungsten Bronze Structure.
  222. Rietveld analysis of sodium tungstate hydrate NaxWO3+x/2.cntdot.yH2O, which has the hexagonal tungsten bronze structure
  223. ChemInform Abstract: The Ionic Conductivity of Hydrogen Vermiculite.
  224. Synthesis of novel compounds with the pyrochlore and hexagonal tungsten bronze structures
  225. Preparation and characterization of lithium, manganese, cobalt and copper vermiculites
  226. Low-temperature hydrothermal reduction of ammonium paratungstate
  227. Effect of tungsten substitution in the YBa2Cu3O7−x system
  228. Hydrothermal synthesis of sodium tungstates
  229. Inorganic phosphate materials Materials Science Monographs # 52. Edited by T. Kanazawa, Elsevier Science Publishers, Amsterdam (1989) 304 pages Dfl. 240.00 ($126.25)
  230. Computer-aided molecular design Edited by W. Graham Richards, IBC Technical Services Ltd, London (1989), 264 pages + 32 color plates £95.00; in North America published by VCH Publishers Inc. New York
  231. An introduction to solid state diffusion R.J. Borg and G.J. Dienes, Academic Press (1988) 360 pages $49.500.
  232. Ion Transport in Single Crystals of the Clay-Like Aluminosilicate, Vermiculite
  233. Surface‐to‐volume ratio, charge density, nuclear magnetic relaxation, and permeability in clay‐bearing sandstones
  234. Synthesis, Diffusion and Ion-Exchange in Open Structure Sodium Tungstates and Ybacu Tungstates
  235. Magnetic susceptibility of vermiculite intercalation compounds with magnetic ions as intercalants
  236. Basic solid state chemistry Anthony R. West, John Wiley & Sons, New York (1988), 415 pages £13.95 ($32.95)
  237. D. L. Nelson, M. S. whittingham, T. F. George (eds). Chemistry of high‐temperature superconductors. ACS Symposium Series 351. Proc. 194th Meeting of the American Chemical Society, New Orleans Aug. 30—Sept. 4, 1987. ACS Washington, DC 1987. Price $ 77.9...
  238. The ionic conductance of mono and divalent cations in single crystal layer structure aluminosilicates
  239. Electron microscopy in solid state physics (Volume 40 of Materials Science Monographs). Edited by H. Bethge and J. Heydenreich, Elsevier Science Publishers (1987) 596 pages $97.75 (Dfl 220)
  240. Sodium ion conduction in single crystal vermiculite
  241. Materials for solid state batteries Edited by B.V.R. Chowdari and S. Radhakrishna, World Scientific Publishing Co., Singapore (1986) 502 pages, $53.00
  242. Preface
  243. Research Opportunities and New Directions in High-Temperature Superconducting Materials
  244. Hydration states and phase transitions in vermiculite intercalation compounds
  245. Foreword
  246. Intercalation chemistry edited by M. S. Whittingham and A. J. Jacobsen
  247. Hexagonal tungsten trioxide and its intercalation chemistry
  248. Lithium incorporation in crystalline and amorphous chalcogenides: Thermodynamics, mechanism and structure
  249. Niobium Triselenide in a Lithium Dioxolane Cell
  250. Formation of stoichiometric titanium disulfide
  251. A Mixed Rate Cathode for Lithium Batteries
  252. Layered compounds and intercalation chemistry: An example of chemistry and diffusion in solids
  253. A welcome to the first issue
  254. Intercalation Chemistry
  255. Amorphous Cathodes for Lithium Batteries
  256. Amorphous molybdenum trisulfide: A new lithium battery cathode
  257. Introduction
  258. Intercalation chemistry and energy storage
  259. Applications of Intercalation Compounds
  260. Substituted β‐Aluminas
  261. Solid state chemistry of energy conversion and storage: Edited By John B. Goodenough and M. Stanley Whittingham, American Chemical Society, 1977. Price: $38£50
  262. The electrochemical characteristics of VSe2 in lithium cells
  263. Structure and bonding in the pyridine intercalates of tantalum disulfide
  264. Mixed One- and Two-Dimensional Conductors
  265. NMR Techniques for Studying Ionic Diffusion
  266. Chemistry of intercalation compounds: Metal guests in chalcogenide hosts
  267. Volcano plots and cyclohexane dehydrogenation
  268. Alkali intercalation compounds of vanadium and chromium sulfides: An NMR study
  269. Transition metal phosphorus trisulfides as battery cathodes
  270. Solid State Chemistry of Energy Conversion and Storage
  271. PREFACE
  272. n-Butyllithium—An Effective, General Cathode Screening Agent
  273. The Reactivity of Metal Oxides and Sulfides with Lithium at 25°C — the Critical Role of Topotaxy
  274. Discussion of “A New Niobium Selenide Cathode for Nonaqueous Lithium Batteries” [D. W. Murphy, F. A. Trumbore, and J. N. Carides (pp. 325–329, Vol. 124, No. 3)]
  275. Electrical Energy Storage and Intercalation Chemistry
  276. Diffusion in the Intercalation Compounds of the Layered Disulfides
  277. The Role of Ternary Phases in Cathode Reactions
  278. The physical properties of the NaxTiS2 intercalation compounds: A synthetic and NMR study
  279. Mechanism of fast ion transport in solids
  280. Structural studies of the intercalation complexes titanium sulfide-ammonia (TiS2.NH3) and tantalum sulfide-ammonia (TaS2.NH3)
  281. The lithium intercalates of the transition metal dichalcogenides
  282. Intercalation and lattice expansion in titanium disulfide
  283. Mechanism of Reduction of the Fluorographite Cathode
  284. Free Energy of Formation of Sodium Tungsten Bronzes, Na[sub x]WO[sub 3]
  285. The hydrated intercalation complexes of the layered disulfides
  286. Electrointercalation in transition-metal disulphides
  287. An NMR study of ionic motion in ammonium tungsten bronze
  288. An NMR study of ionic motion in ammonium ferrocyanide
  289. The iron cyanide bronzes
  290. Fuel Cells
  291. Molten Salts—Characterization and Analysis
  292. Transport Properties of Silver Beta Alumina
  293. Measurement of Sodium Ion Transport in Beta Alumina Using Reversible Solid Electrodes
  294. Preparation and characterization of a hexagonal ammonium tungsten bronze phase (NH4) x WO3
  295. Nuclear Magnetic Resonance Linewidth of Thallium Tungsten Bronze
  296. The reflectance spectra of the tungsten bronzes
  297. Recombination of oxygen atoms on oxide surfaces. Part 2.—Catalytic activities of the alkali metal tungsten bronzes
  298. Materials - The Technology Barrier to Advanced Batteries for Energy Storage
  299. Synthesis of Battery Materials
  300. Electrochemical energy storage: batteries and capacitors