100 Years of Ferroelectricity 1921-2021

100 Years of Ferroelectricity 1921-2021

铁电百年1921-2021
电磁学

原价：

￥ 998.75

售价：

优惠

平台大促低至8折优惠

发货周期：预计3-5周发货

作者

Gonzalo, Julio A.(编辑);Jaque, Francisco(编辑);Lifante, Gines(编辑)

出版社

World Scientific Publishing

出版时间

2021年09月13日

装帧

精装

ＩＳＢＮ

9789811243097

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228 pp

语种

英文

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暂无评分

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图书简介

Since the discovery in 1921 of ferroelectric properties in Rochelle salt by Valasek, no new ferroelectric material was found until Busch and Scherrer in Switzerland in 1935 discovered ferroelectricity in Potassium dihydrogen phosphate (KDP). However, during the Second World War, researchers in the US in 1943 discovered ferroelectric materials such as BaTiO3 having ferroelectric properties well above room temperature, that led to an explosion of research after the war in Western and Central Europe, Russia, and Japan, because of their promising and potential applications. This book gives an overview of relevant experimental and theoretical work in ferroelectricity. It is organized into three Sections, corresponding to three time periods. The first (1921–1960) includes early work by Valasek, works by Busch and Scherrer, Mason and Mattias, Shirane and Takeda, ending with theoretical work by Cochran on crystal stability and the soft mode theory of ferroelectricity. The second one (1961–2002) includes a number of experimental and theoretical publications on ferroelectric materials and ferroelectric transitions. The number of international meetings began to increase, and the number of papers increased exponentially. New subfields at that time included ferroelectric liquid crystals, thin films, dipolar glasses and relaxors. The last and final section (2002–2021) includes more recent publications on fundamental structural studies, neutron diffraction work on PZT, quantum tunneling and zero-point energy in ferroelectrics, investigations on the anomalous temperature dependence behavior of liquid water and other recent developments. The book will be a useful compendium on ferroelectrics for materials scientists, and/or PhD graduate students on ferroelectrics all around the world.

Early Work 1921–1961: Piezoelectric Activity of Rochelle Salt Under Various Conditions (J Valasek); Rochelle Salt as a Dielectric (C B Sawyer, C H Tower); A New Seignette — Electric Substance (C Busch, P Scherrer); Theoretical Model for Explaining the Ferroelectric Effect in Barium Titanate (W P Mason, B T Matthias); Phase Transitions in Solid Solutions of PbZrO3 and PbTiO3(G Shirane, A Takeda); Ferroelectricity of Glycine Sulphate (B T Matthias, C E Muller, J P Remeika); Crystal Stability and the Theory of Ferroelectricity (W Cochran); Ferroelectrics 1961–2001: The Classification of Tilted Octahedra in Perovskites (A M Glazer); Simple Ways of Determining Perovskite Structures (A M Glazer); Equation of State for the Cooperative Transition of Triglycine Sulfate near Tc (J A Gonzalo); X-ray Structural Damage of Triglycine Sulphate (TGS) (C Alemany, J Mendiola, B Jimenez and E Maurer); Equation of State for the Pressure and Temperature Induced Transitions in Ferroelectric Telluric Acid and Ammonium Phosphate (J R Fernández del Castillo, J Przeslawski, and J A Gonzalo); Tetragonal-to-Monoclinic Phase Transition in a Ferroelectric Perovskite: The Structure of PbZr0.52Ti0.48O3 (B Noheda, J A Gonzalo, L.E Gross, R Guo, S E Park, D E Cox & G Shirane); Formation and Evolution of Charged Domain Walls in Congruent Lithium Niobate (V Ya Shur, E L Rumyantsev, E V Nikolaeva, and E I Shishkin); Nanoscale Backswitched Domain Patterning in Lithium Niobate (V Ya Shur, E L Rumyantsev, E V Nikolaeva, E I Shishkin, D V Fursov, R G Batchko, L A Eyres, M M Fejer, and R L Byer); First Order Phase Transition in Order–Disorder Ferroelectrics (C L Wang, Z K Qin, and D L Lin); Tilt and Pb/(Zr/Ti) Displacement Order Parameter in Zr Rich Pb Zr1-xTixO3 from 20 to 500 K (N Cereceda, B Noheda, T Iglesias, R Fernández del Castillo, J A Gonzalo, N Duang, Y L Wand, D E Cox and G Shirane); Difuse Phase Transitions and Random-Field-Induced Domain States of the \"Relaxor\" Ferroelectric PbMg1/3Nb2/3O3 (V Wesphals, W Kleemann, M D Glinchuk); Ferroelectrics 2001–2021: (SrMn)TiO3: A Magnetolectric Multiglass (V V Shvartsman, S Bedanta, P Borisov, and W Kleemann); Quantum Tunnelling Versus Zero Point Energy in Double Well Potential Model for Ferroelectric Phase Transitions (C L Wang, C Aragó, J García, and J A Gonzalo); Characteristic Temperatures of 1st Order Ferroelectric Phase Transitions: Effective Field Approach (C L Wang, C Aragó, and M I Marqués); Dielectric Anomalous Response of Water at 60°C (J C del Valle, E Camarillo, L Martínez Maeso, J A Gonzalo, C Aragó, M I Marqués, D Jaque, G Lifante, J García Solé, K Santa Cruz, R Carrillo Torres, and F Jaque); Transition Between the Ferroelectric and Relaxor States in 0.8Pb(PbMg1/3Nb2/3)O3-0.2PbTiO3 Ceramics (R Jiménez, B Jiménez, J Carraud, J M Kiat, B Dkhil, J Holc, M Kosec, and M Alguero); SrTiO3 — Glimpses of an Inexhaustible Source of Novel Solid State Phenomena (W Kleemann, J Dec, A Tkach, and P M Vilarinho);

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