![]() ![]() Infrared switching electrochromic devices based on tungsten oxide. Electrochromic properties of nanocrystalline MoO 3 thin films. Optical and photoelectric properties and colour centres in thin films of tungsten oxide. Nanostructured electrochromic smart windows: traditional materials and NIR-selective plasmonic nanocrystals. Electrochromics for smart windows: Oxide-based thin films and devices. Opportunities and challenges in science and technology of WO 3 for electrochromic and related applications. Electrochromic systems and the prospects for devices. A review on buildings energy consumption information. LBNL-54966 (Lawrence Berkeley National Laboratory, 2004). The Energy-Savings Potential of Electrochromic Windows in the US Commercial Buildings Sector. Beyond electrostatic modification: design and discovery of functional oxide phases via ionic-electronic doping. ![]() Electrochemical and chemical insertion for energy transformation and switching. Understanding Molecular Simulation: From Algorithms to Applications (Academic Press, 2002). Physical Chemistry of Ionic Materials: Ions and Electrons in Solids (Wiley, 2004).įrenkel, D. ![]() Electrons and Phonons: The Theory of Transport Phenomena in Solids (Oxford Univ. Resistive Switching: From Fundamentals of Nanoionic Redox Processes to Memristive Device Applications (Wiley, 2016). Large tunable photoeffect on ion conduction in halide perovskites and implications for photodecomposition. Pseudocapacitance: from fundamental understanding to high power energy storage materials. Semiconductor Device Fundamentals (Addison-Wesley, 1996).įleischmann, S. Ab initio study of lithium intercalation in metal oxides and metal dichalcogenides. Advanced Batteries (Springer, 2009).Īydinol, M. Chimie douce: from shake-and-bake processing to wet chemistry. Solid state electrodes for high energy batteries. Chimie douce approaches to the synthesis of metastable oxide materials. The Li-ion rechargeable battery: A perspective. We illustrate similarities in the operating principles of various ion-insertion devices, ranging from batteries and electrocatalysts to electrochromics and thermal transistors, with the goal of unifying research across disciplinary boundaries. Using graphite, transition metal dichalcogenides, layered oxides, oxyhydroxides and olivines as examples, we explore commonalities in these materials in terms of point defects, interfacial reactions and phase transformations. In this Review, we present a unified framework for understanding insertion compounds across timescales and length scales ranging from atomic to device levels. Recent developments in operando, ultrafast and high-resolution characterization methods, as well as accurate theoretical simulation methods, have led to a renaissance in the understanding of ion-insertion compounds. These insertion compounds have traditionally been studied in the context of energy storage but also find extensive applications in electrocatalysis, optoelectronics and computing. The hosts are typically anisotropic solids with 2D conduction planes but can also be materials with 1D or isotropic transport pathways. Electrochemical ion insertion involves coupled ion–electron transfer reactions, transport of guest species and redox of the host. ![]()
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