C
Chao Zhang
Researcher at Beihang University
Publications - 4347
Citations - 118320
Chao Zhang is an academic researcher from Beihang University. The author has contributed to research in topics: Medicine & Computer science. The author has an hindex of 127, co-authored 3119 publications receiving 84711 citations. Previous affiliations of Chao Zhang include West Virginia University & University of Oklahoma.
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Journal ArticleDOI
Effect of Ball Milling of Feedstock Powder on Microstructure and Properties of TiN Particle-Reinforced Al Alloy-Based Composites Fabricated by Cold Spraying
TL;DR: In this paper, the micro-hardness of the composite with the BM blend was three times higher than that of pure Al5356 coating and the coefficient of frication and wear rate were measured using a ball-on-disc tribometer.
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Learning deep representation for trajectory clustering
TL;DR: This paper revisits the trajectory clustering problem by learning quality low‐dimensional representations of the trajectories and transforms each trajectory into a feature sequence to describe object movements and employs a sequence‐to‐sequence auto‐encoder to learn fixed‐length deep representations.
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Highly Active Hydrogen Evolution Electrodes via Co-Deposition of Platinum and Polyoxometalates.
TL;DR: A highly active hydrogen evolution reaction (HER) electrode with low Pt loading on glassy carbon (GC) prepared by anodic platinum dissolution and co-deposition of polyoxometalates has a HER activity comparable to that of the commercial Pt working electrode.
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Overcoming Hypoxia-Restrained Radiotherapy Using an Erythrocyte-Inspired and Glucose-Activatable Platform.
Huang Hao,Chao Zhang,Xiaolin Wang,Jinsong Shao,Chao Chen,Haoming Li,Chunmei Ju,Jian He,Haiying Gu,Dong-Lin Xia +9 more
TL;DR: This strategy is the initial attempt to overcome tumor hypoxia-limited RT through the normalization of tumor vasculature by using an erythrocyte-inspired and glucose-activatable platform and it visually casts a light on the clinical development.
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Experimental investigations on the effects of inclination angle and blowing ratio on the flat-plate film cooling enhancement using the vortex generator downstream
TL;DR: In this paper, the effects of inclination angle (α = 20 °, 30 °, 40 ° ) and blowing ratio (M ǫ = 0.5, 1.0,1.5) on the vortex generator (VG) to enhance the film cooling performance was investigated.