Your search keyword '"Jia, Qianru"' showing total 3 results

1. Structural and Synthetic Modification of Graphitic Foams and Dendritic Graphitic Foams for Thermal Management.

Author

Jia, Qianru, Liu, Yifei, Fan, Donglei Emma, and Shi, Li

Subjects

*FOAM, *CHEMICAL vapor deposition, *THERMAL conductivity, *PHASE change materials, *FILLER materials

Abstract

The performances of porous graphitic foams in flexible electronic, electrochemical, and thermal management devices can be enhanced by increasing the interfacial charge or heat transport between the 3D graphitic network and the functional materials filled into the pore space. Herein, an investigation of the effects of chemical vapor deposition (CVD) conditions on the structure and thermal conductivities of both graphitic foams grown from reticular Ni foams and dendritic graphitic foams (DGFs) synthesized from electrodeposited dendritic Ni foams is reported. A room‐temperature solid thermal conductivity (κs) up to 800 W m−1 K−1 is obtained from the graphitic foams (GF) with less than 1% volume fraction. In comparison, the DGFs, which provide a large increase of the specific surface area for enhanced interfacial heat transfer, achieve an effective thermal conductivity of 2.5 ± 0.2 W m−1 K−1 because of an enhanced volume fraction to about 5% despite a compromised κs around 200 W m−1 K−1 due to the increased defect density. Through systematical variations of the catalyst template morphology and CVD conditions, this work reveals the distinct roles of catalyst surface curvature and graphitic strut thickness in controlling the properties of GFs and DGFs for thermal management. [ABSTRACT FROM AUTHOR]

Published

2022

2. Synthesis and Magnon Thermal Transport Properties of Spin Ladder Sr14Cu24O41 Microstructures.

Author

Chen, Xi, Kim, Jaehyun, Jia, Qianru, Sullivan, Sean E., Xu, Youming, Jarvis, Karalee, Zhou, Jianshi, and Shi, Li

Subjects

MAGNONS, THERMAL properties, SURFACE scattering, THERMAL conductivity, MICROSTRUCTURE, SINGLE crystals, ALKALINE earth metals, CALCIUM compounds

Abstract

The spin ladder compound (Sr,Ca,La)14Cu24O41 exhibits an incommensurate layered structure with strong antiferromagnetic coupling. Besides intriguing superconducting behavior, recent experiments on bulk Sr14Cu24O41 single crystals have revealed a remarkable magnon thermal conductivity, which is the largest above 100 K among all known quantum magnets. Although bulk (Sr,Ca,La)14Cu24O41 crystals have been synthesized and studied extensively, there have been few reports on the synthesis and magnon thermal transport investigation of their microstructures. Here, the synthesis and thermal transport properties of Sr14Cu24O41 microrods are reported. Electron microscopy studies indicate that these microrods synthesized by a coprecipitation method are single crystals grown preferentially along the ladder axis. Based on a four‐probe thermal transport measurement, the thermal conductivity of the microrods reveals appreciable magnon transport in the microstructures. According to a kinetic model analysis, magnon transport in the microrods is suppressed mainly by increased point defect scattering compared to the bulk crystals, whereas surface scattering is negligible for anisotropic 1D magnon transport along the ladder. Moreover, the thermal conductivity is enhanced after annealing as a result of reduced oxygen vacancies. These results help to build the foundation for future heterogeneous integration of magnetic microstructures in microscale devices for the transport of energy and quantum information. [ABSTRACT FROM AUTHOR]

Published

2020

3. Phospholipase Dδ negatively regulates plant thermotolerance by destabilizing cortical microtubules in Arabidopsis.

Author

Zhang, Qun, Song, Ping, Qu, Yana, Wang, Peipei, Jia, Qianru, Guo, Liang, Zhang, Chuanpeng, Mao, Tonglin, Yuan, Ming, Wang, Xuemin, and Zhang, Wenhua

Subjects

ARABIDOPSIS, PHOSPHOLIPASE D, MICROTUBULES, PLANT adaptation, HEAT shock proteins of plants

Abstract

The pattern of cortical microtubule arrays plays an important role in plant growth and adaptation in response to hormonal and environmental changes. Cortical microtubules are connected with the plasma membrane (PM); however, how the membrane affects cortical microtubule organization is not well understood. Here, we showed that phospholipase Dδ (PLDδ) was associated with the PM and co-localized with microtubules in cells. In vitro analysis revealed that PLDδ bound to microtubules, resulting in microtubule disorganization. Site-specific mutations that decreased PLDδ enzymatic activity impaired its effects on destabilizing microtubule organization. Heat shock transiently activated PLDδ, without any change of its PM localization, triggering microtubule dissociation from PM and depolymerization and seedling death in Arabidopsis, but these effects were alleviated in pldδ knockout mutants. Complementation of pldδ with wild-type PLDδ, but not mutated PLDδ, restored the phenotypes of microtubules and seedling survival to those of wild-type Arabidopsis. Thus, we conclude that the PM-associated PLDδ negatively regulates plant thermotolerance via destabilizing cortical microtubules, in an activity-dependent manner, rather than its subcellular translocation. [ABSTRACT FROM AUTHOR]

Published

2017