Negative thermal expansion materials: technological key for control of thermal expansion.
about
Area negative thermal expansion in a beryllium borate LiBeBO3 with edge sharing tetrahedra.Ba(1-x)Sr(x)Zn2Si2O7--A new family of materials with negative and very high thermal expansionTunable thermal expansion in framework materials through redox intercalationPhase-Transformation-Induced Extra Thermal Expansion Behavior of (SrxBa1-x)TiO3/Cu CompositeColossal negative thermal expansion in reduced layered ruthenateNegative thermal expansion in functional materials: controllable thermal expansion by chemical modifications.An updated roadmap for the integration of metal-organic frameworks with electronic devices and chemical sensors.Negative thermal expansion induced by intermetallic charge transfer.Magnetovolume effects in manganese nitrides with antiperovskite structure.Low Temperature Synthesis and Characterization of AlScMo₃O12.Negative thermal expansion in LnCo(CN)6 (Ln=La, Pr, Sm, Ho, Lu, Y): mechanisms and compositional trends.Fabrication of Zr2WP2O12/ZrV0.6P1.4O7 composite with a nearly zero-thermal-expansion property.Solid-state dynamics and single-crystal to single-crystal structural transformations in octakis(3-chloropropyl)octasilsesquioxane and octavinyloctasilsesquioxane.Switching Between Giant Positive and Negative Thermal Expansions of a YFe(CN)6 -based Prussian Blue Analogue Induced by Guest Species.Systematic charge distribution changes in Bi- and Pb-3d transition metal perovskites.Origami Metamaterials for Tunable Thermal Expansion.Local vibrations and negative thermal expansion in ZrW2O8.Adjusting Local Molecular Environment for Giant Ambient Thermal Contraction.Large negative thermal expansion in non-perovskite lead-free ferroelectric Sn2P2S6.A copper-formate framework showing a simple to helical antiferroelectric transition with prominent dielectric anomalies and anisotropic thermal expansion, and antiferromagnetism.Phase transitions, prominent dielectric anomalies, and negative thermal expansion in three high thermally stable ammonium magnesium-formate frameworks.On flexible force fields for metal-organic frameworks: Recent developments and future prospectsTuning negative thermal expansion in Bi1−xLnxNiO3 (Ln = La, Nd, Eu, Dy)Spin frustration in antiperovskite systems: (TTF˙+ or TSF˙+)3[(Mo6X14)2−Y−]High Pressure Behavior of Chromium and Yttrium Molybdate (CrMoO, YMoO)Mechanisms and Materials for NTEUnusually Small Thermal Expansion of Ordered Perovskite Oxide CaCu₃Ru₄O with High ConductivityFramework flexibility and the negative thermal expansion mechanism of copper(I) oxideCu2O
P2860
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P2860
Negative thermal expansion materials: technological key for control of thermal expansion.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Negative thermal expansion materials: technological key for control of thermal expansion.
@en
Negative thermal expansion materials: technological key for control of thermal expansion.
@nl
type
label
Negative thermal expansion materials: technological key for control of thermal expansion.
@en
Negative thermal expansion materials: technological key for control of thermal expansion.
@nl
prefLabel
Negative thermal expansion materials: technological key for control of thermal expansion.
@en
Negative thermal expansion materials: technological key for control of thermal expansion.
@nl
P2860
P356
P1476
Negative thermal expansion materials: technological key for control of thermal expansion
@en
P2093
Koshi Takenaka
P2860
P304
P356
10.1088/1468-6996/13/1/013001
P577
2012-02-02T00:00:00Z