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3 article(s) from Zhang, Qian

Co-intercalated layered double hydroxides as thermal and photo-oxidation stabilizers for polypropylene

Qian Zhang,
Qiyu Gu,
Fabrice Leroux,
Pinggui Tang,
Dianqing Li and
Yongjun Feng

Beilstein J. Nanotechnol. 2018, 9, 2980–2988, doi:10.3762/bjnano.9.277

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Figure 1: Molecular structures of Irganox 1425 (MP-Ca) and hindered amine light stabilizer (HALS).

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Figure 2: Powder X-ray diffraction patterns of different H_nM_n_′-Ca₂Al-LDH samples.

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Figure 3: FTIR spectra of different H_nM_n_′-Ca₂Al-LDH samples.

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Figure 4: SEM images of (a) HALS-Ca₂Al, (b) MP-Ca₂Al and (c) H₂M₁-Ca₂Al, (d) H₁M₁-Ca₂Al, (e) H₁M₂-Ca₂Al, (f) H...

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Figure 5: (a) TG and (b) DTA curves of Ca₂Al-LDHs: HALS-Ca₂Al, MP-Ca₂Al, H₂M₁-Ca₂Al, H₁M₁-Ca₂Al, H₁M₂-Ca₂Al, ...

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Figure 6: Powder X-ray diffraction pattern of H_nM_n_′-Ca₂Al/PP composites. LDH reflection peaks were marked wit...

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Figure 7: (a) FTIR spectra and (b) visible-light transmittance spectra of Ca₂Al/PP composites. (c) SEM image ...

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Figure 8: (a) TGA curves of H_nM_n_′-Ca₂Al/PP composites. (b) FTIR spectra of PP after different periods of ther...

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Full Research Paper

Published 05 Dec 2018

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Modeling of the growth of GaAs–AlGaAs core–shell nanowires

Qian Zhang,
Peter W. Voorhees and
Stephen H. Davis

Beilstein J. Nanotechnol. 2017, 8, 506–513, doi:10.3762/bjnano.8.54

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Figure 1: Schematic of a core–shell nanowire (left) with possible configurations of the cross section (right)...

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Figure 2: Schematic of cross section of a core of a nanowire that is a six-fold symmetric structure with {112...

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Figure 3: Evolution of a dodecagonal crystal (bounded by red lines) to a hexagonal crystal (bounded by black ...

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Figure 4: (a) Evolution of a dodecagonal shell to its kinetic Wulff shape due to surface diffusion and deposi...

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Figure 5: (a) Cross section of the core–shell nanowire with six {112} facets (blue color) along the corners o...

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Figure 6: (a) Cross section of the core–shell nanowire with six {112} facets (blue color) along the corners o...

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Figure 7: (a) This is partial view of a cross section of the shell of core–shell nanowire with one {112} face...

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Figure 8: (a) Evolution of the difference of the average chemical potentials of the facets with the thickness...

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Figure 9: (a) Distribution of the concentration of Al in the shell of the nanowire. (b) Evolution of the aver...

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Figure 10: (a) Distribution of the concentration of Al in the shell of the nanowire. (b) Evolution of the aver...

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Figure 11: Influence of the ratio between the mobilities of different atoms and deposition rates on the surfac...

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Letter

Published 24 Feb 2017

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In vitro interaction of colloidal nanoparticles with mammalian cells: What have we learned thus far?

Moritz Nazarenus,
Qian Zhang,
Mahmoud G. Soliman,
Pablo del Pino,
Beatriz Pelaz,
Susana Carregal-Romero,
Joanna Rejman,
Barbara Rothen-Rutishauser,
Martin J. D. Clift,
Reinhard Zellner,
G. Ulrich Nienhaus,
James B. Delehanty,
Igor L. Medintz and
Wolfgang J. Parak

Beilstein J. Nanotechnol. 2014, 5, 1477–1490, doi:10.3762/bjnano.5.161

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Figure 1: An overview of the “zoo” of different NPs concerning their composition, functionality, and fields o...

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Figure 2: Hybrid nature of typical NPs, comprising different structural compartments. Reproduced with permiss...

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Figure 3: Scheme depicting the different mechanisms of cellular endocytosis. Reproduced with permission from [41]...

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Figure 4: Fluorescence microscopy image showing the granular structure of internalized NPs inside A549 lung c...

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Figure 5: a) A microparticle has been internalized by an A549 lung cancer cell into an intracellular vesicle ...

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Figure 6: Intracellular compartments after internalization of PEG-coated gold NPs as visualized with TEM. The...

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Figure 7: TEM images of a) dispersed and b) agglomerated Au NPs. The scale bars correspond to 100 nm. Adopted...

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Review

Published 09 Sep 2014

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