Mu Sen Li
Shandong University
10 Papers
221 Citations
Mu Sen Li is an academic researcher from Shandong University. The author has contributed to research in topics: Wurtzite crystal structure & Nanowire. The author has an hindex of 8, co-authored 10 publications. Previous affiliations of Mu Sen Li include National Institute for Materials Science.
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Papers
Self‐Assembled Highly Faceted Wurtzite‐Type ZnS Single‐Crystalline Nanotubes with Hexagonal Cross‐Sections
TL;DR: In this article, the synthesis of self-assembled highly faceted wurtzite-type ZnS single crystalline nanotubes with hexagonal cross-section was studied.
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Single‐Crystalline AlN Nanotubes with Carbon‐Layer Coatings on the Outer and Inner Surfaces via a Multiwalled‐Carbon‐Nanotube‐Template‐Induced Route
TL;DR: In this paper, the synthesis of coaxial C-AlN-C composite nanotubes produced through a chemical substitution reaction in a controllable two-stage process using multiwalled carbon Nanotubes (MWCNT) as templates was presented.
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Porous BCN nanotubular fibers: growth and spatially resolved cathodoluminescence.
Long Wei Yin,Yoshio Bando,Dmitri Golberg,Alexandre Gloter,Mu Sen Li,Xiaoli Yuan,Takashi Sekiguchi +6 more
TL;DR: Porous boron carbonitride nanotubular fibers with BCN stoichiometry and homogeneous B, C, and N species distribution were fabricated via the CVD method, suggesting the characteristics of a semiconductor with a band gap of 3.89 eV.
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A Two‐Stage Route to Coaxial Cubic‐Aluminum‐Nitride–Boron‐ Nitride Composite Nanotubes
TL;DR: In this paper, the synthesis of coaxial cubic aluminum nitride-boron nitride (c-AlN-BN) composite nanotubes was carried out in a template-free catalyst-free two-stage route.
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Growth of semiconducting GaN hollow spheres and nanotubes with very thin shells via a controllable liquid gallium-gas interface chemical reaction.
TL;DR: An in situ liquid gallium-gas interface chemical reaction route has been developed to synthesize semiconducting hollow GaN nanospheres with very small shell size by carefully controlling the synthesis temperature and the ammonia reaction gas partial pressure.
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