Advanced thermal management for extreme environments urgently demands materials that combine robust environmental stability with adaptive thermal conductivity(κ),specifically the highly desirable but rare positive te...Advanced thermal management for extreme environments urgently demands materials that combine robust environmental stability with adaptive thermal conductivity(κ),specifically the highly desirable but rare positive temperature(T)dependence ofκ.Ceramics typically exhibit phonon-dominated heat transfer with decreasing thermal conductivity at elevated temperatures,and achieving an alloy-like positiveκ-T relationship in ceramics is a significant scientific and technological challenge with immense application value.To address this,we fabricated fully dense(>98%)multicomponent nitride bulks via hot-press sintering using aluminum nitride(AlN)as the matrix.Notably,the TiAlN system achieved a high room-temperature(κ)of 48.38 W·m^(−1)·K^(−1).Counterintuitively,increased diversity of metallic elements induces severe lattice distortion that suppresses phonon thermal conduction while simultaneously forming metallic nitride conductive networks that significantly increase electronic thermal conductivity.This synergistic electron-phonon regulation successfully transforms theκ-T dependence from negative to positive.Remarkably,TiZrVCrAlN demonstrates a linear 112% κincrease from 8.65 W·m^(−1)·K^(−1) at−60℃ to 18.34 W·m^(−1)·K^(−1) at 900℃,outperforming all known positive-κceramics in both the operating temperature range and conductivity values.Moreover,it maintains robust mechanical integrity(24.5 GPa hardness,273 MPa bending strength).This work elucidates the fundamental mechanism for achieving anomalous positiveκ-T dependence in ceramics through electron-phonon synergistic regulation.These multicomponent nitrides,combining unprecedented positiveκ-T behavior with excellent mechanical properties,present a breakthrough solution for intelligent thermal management,specifically enabling the development of structural-functional integrated components operating under extreme and varying thermal conditions.展开更多
基金supported by the National Natural Science Foundation of China(Nos.52472068 and 23020062)the Chongqing Technology Innovation and Application Development Special Key Project(No.CSTB2022TIAD-KPX0030).
文摘Advanced thermal management for extreme environments urgently demands materials that combine robust environmental stability with adaptive thermal conductivity(κ),specifically the highly desirable but rare positive temperature(T)dependence ofκ.Ceramics typically exhibit phonon-dominated heat transfer with decreasing thermal conductivity at elevated temperatures,and achieving an alloy-like positiveκ-T relationship in ceramics is a significant scientific and technological challenge with immense application value.To address this,we fabricated fully dense(>98%)multicomponent nitride bulks via hot-press sintering using aluminum nitride(AlN)as the matrix.Notably,the TiAlN system achieved a high room-temperature(κ)of 48.38 W·m^(−1)·K^(−1).Counterintuitively,increased diversity of metallic elements induces severe lattice distortion that suppresses phonon thermal conduction while simultaneously forming metallic nitride conductive networks that significantly increase electronic thermal conductivity.This synergistic electron-phonon regulation successfully transforms theκ-T dependence from negative to positive.Remarkably,TiZrVCrAlN demonstrates a linear 112% κincrease from 8.65 W·m^(−1)·K^(−1) at−60℃ to 18.34 W·m^(−1)·K^(−1) at 900℃,outperforming all known positive-κceramics in both the operating temperature range and conductivity values.Moreover,it maintains robust mechanical integrity(24.5 GPa hardness,273 MPa bending strength).This work elucidates the fundamental mechanism for achieving anomalous positiveκ-T dependence in ceramics through electron-phonon synergistic regulation.These multicomponent nitrides,combining unprecedented positiveκ-T behavior with excellent mechanical properties,present a breakthrough solution for intelligent thermal management,specifically enabling the development of structural-functional integrated components operating under extreme and varying thermal conditions.
