Xinping Mao scite author profile

Dielectric composites boost the family of energy storage and conversion materials as they can take full advantage of both the matrix and filler. This review aims at summarizing the recent progress in developing high‐performance polymer‐ and ceramic‐based dielectric composites, and emphases are placed on capacitive energy storage and harvesting, solid‐state cooling, temperature stability, electromechanical energy interconversion, and high‐power applications. Emerging fabrication techniques of dielectric composites such as 3D printing, electrospinning, and cold sintering are addressed, following by highlighted challenges and future research opportunities. The advantages and limitations of the typical theoretical calculation methods, such as finite‐element, phase‐field model, and machine learning methods, for designing high‐performance dielectric composites are discussed. This review is concluded by providing a brief perspective on the future development of composite dielectrics toward energy and electronic devices.

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Strengthening mechanisms of a new 700MPa hot rolled Ti-microalloyed steel produced by compact strip production

Mao

Huo

Sun

et al. 2010

Journal of Materials Processing Technology

157

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Strain-induced precipitation in a Ti micro-alloyed HSLA steel

Wang

Mao

Yang

et al. 2011

Materials Science and Engineering: A

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Nanoscale Cementite Precipitates and Comprehensive Strengthening Mechanism of Steel

Mao

et al. 2011

Metall Mater Trans A

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This article summarizes the state of the art of the comprehensive strengthening mechanism of steel. By using chemical phase analysis, X-ray small-angle scattering (XSAS), room temperature organic (RTO) solution electrolysis and metal embedded sections micron-nano-meter characterization method, and high-resolution transmission electron microscopy (TEM) observation, the properties of nanoscale cementite precipitates in Ti microalloyed high-strength weathering steels produced by the thin slab continuous casting and rolling process were analyzed. Except nanoscale TiC, cementite precipitates with size less than 36 nm and high volume fraction were also found in Ti microalloyed high-strength weathering steels. The volume fraction of cementite with size less than 36 nm is 4.4 times as much as that of TiC of the same size. Cementite with high volume fraction has a stronger precipitation strengthening effect than that of nanoscale TiC, which cannot be ignored. The precipitation strengthening contributions of nanoscale precipitates of different types and sizes should be calculated, respectively, according to the mechanisms of shearing and dislocation bypass, and then be added with the contributions of solid solution strengthening and grain refinement strengthening. A formula for calculating the yield strength of low-carbon steel was proposed; the calculated yield strength considering the precipitation strengthening contributions of nanoscale precipitates and the comprehensive strengthening mechanism of steels matches the experimental results well. The calculated r s = 630 to 676 MPa, while the examined r s = 630 to 680 MPa. The reason that ''ultrafine grain strengthening can not be directly added with dislocation strengthening or precipitation strengthening'' and the influence of the phase transformation on steel strength were discussed. The applications for comprehensive strengthening theory were summarized, and several scientific questions for further study were pointed out.

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Xinping Mao

V2C MXene synergistically coupling FeNi LDH nanosheets for boosting oxygen evolution reaction

Polymer‐/Ceramic‐based Dielectric Composites for Energy Storage and Conversion

Strengthening mechanisms of a new 700MPa hot rolled Ti-microalloyed steel produced by compact strip production

Strain-induced precipitation in a Ti micro-alloyed HSLA steel

Nanoscale Cementite Precipitates and Comprehensive Strengthening Mechanism of Steel

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