Your search keyword '"Bosman, Michel"' showing total 6 results

1. Highly Luminescent Heterostructured Copper-Doped Zinc Sulfide Nanocrystals for Application in Cancer Cell Labeling.

Author

Ang H, Bosman M, Thamankar R, Zulkifli MF, Yen SK, Hariharan A, Sudhaharan T, and Selvan ST

Subjects

Animals, CHO Cells, Cell Survival drug effects, Copper chemistry, Cricetulus, Dose-Response Relationship, Drug, HeLa Cells, Humans, Molecular Structure, Neoplasms pathology, Particle Size, Silicon Dioxide chemistry, Sulfides chemistry, Surface Properties, Zinc Compounds chemistry, Copper pharmacology, Luminescence, Nanoparticles chemistry, Neoplasms diagnosis, Silicon Dioxide pharmacology, Sulfides pharmacology, Zinc Compounds pharmacology

Abstract

The structural characteristics of the seed-mediated synthesis of heterostructured CuS-ZnS nanocrystals (NCs) and Cu-doped ZnS (ZnS:Cu) NCs synthesized by two different protocols are compared and analyzed. At high Cu dopant concentrations, segregated subclusters of ZnS and CuS are observed. The photoluminescence quantum yield of ZnS:Cu NCs is about 50-80 %; a value much higher than that of ZnS NCs (6 %). Finally, these NCs are coated with a thin silica shell by using (3-mercaptopropyl)triethoxysilane in a reverse microemulsion to make them water soluble. Cytotoxicity experiments show that these silica-coated NCs have greatly reduced toxicity on both cancerous HeLa and noncancerous Chinese hamster ovary cells. The labeling of cancerous HeLa cells is also demonstrated., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

2. Electron-energy loss study of nonlocal effects in connected plasmonic nanoprisms.

Author

Wiener A, Duan H, Bosman M, Horsfield AP, Pendry JB, Yang JK, Maier SA, and Fernández-Domínguez AI

Subjects

Computer Simulation, Electron Transport, Light, Nanoparticles radiation effects, Scattering, Radiation, Energy Transfer, Models, Theoretical, Nanoparticles chemistry, Nanoparticles ultrastructure, Refractometry methods, Surface Plasmon Resonance methods

Abstract

We investigate the emergence of nonlocal effects in plasmonic nanostructures through electron-energy loss spectroscopy. To theoretically describe the spatial dispersion in the metal permittivity, we develop a full three-dimensional nonlocal hydrodynamic solution of Maxwell's equations in frequency domain that implements the electron beam as a line current source. We use our numerical approach to perform an exhaustive analysis of the impact of nonlocality in the plasmonic response of single triangular prisms and connected bowtie dimers. Our results demonstrate the complexity of the interplay between nonlocal and geometric effects taking place in these structures. We show the different sensitivities to both effects of the various plasmonic modes supported by these systems. Finally, we present an experimental electron-energy loss study on gold nanoprisms connected by bridges as narrow as 1.6 nm. The comparison with our theoretical predictions enables us to reveal in a phenomenological fashion the enhancement of absorption damping that occurs in these atomistic junctions due to quantum confinement and grain boundary electron scattering.

Published

2013

3. Colloidal nanocrystals of wurtzite-type Cu2ZnSnS4: facile noninjection synthesis and formation mechanism.

Author

Regulacio MD, Ye C, Lim SH, Bosman M, Ye E, Chen S, Xu QH, and Han MY

Subjects

Colloids chemistry, Microscopy, Electron, Transmission methods, Nanoparticles ultrastructure, Semiconductors, Sulfides chemical synthesis, X-Ray Diffraction methods, Copper chemistry, Nanoparticles chemistry, Sulfides chemistry, Tin chemistry, Zinc chemistry

Published

2012

4. Quantum Plasmon Resonances Controlled by Molecular Tunnel Junctions

Author

Tan, Shu Fen, Wu, Lin, Yang, Joel K.W., Bai, Ping, Bosman, Michel, and Nijhuis, Christian A.

Published

2014

5. Particle simulation of plasmons.

Author

Ding, Wen Jun, Lim, Jeremy Zhen Jie, Do, Hue Thi Bich, Xiong, Xiao, Mahfoud, Zackaria, Png, Ching Eng, Bosman, Michel, Ang, Lay Kee, and Wu, Lin

Subjects

MAXWELL equations, FARADAY'S law, ELECTROMAGNETIC fields, NANOPARTICLES, PLASMONS (Physics)

Abstract

Particle simulation has been widely used in studying plasmas. The technique follows the motion of a large assembly of charged particles in their self-consistent electric and magnetic fields. Plasmons, collective oscillations of the free electrons in conducting media such as metals, are connected to plasmas by very similar physics, in particular, the notion of collective charge oscillations. In many cases of interest, plasmons are theoretically characterized by solving the classical Maxwell's equations, where the electromagnetic responses can be described by bulk permittivity. That approach pays more attention to fields rather than motion of electrons. In this work, however, we apply the particle simulation method to model the kinetics of plasmons, by updating both particle position and momentum (Newton–Lorentz equation) and electromagnetic fields (Ampere and Faraday laws) that are connected by current. Particle simulation of plasmons can offer insights and information that supplement those gained by traditional experimental and theoretical approaches. Specifically, we present two case studies to show its capabilities of modeling single-electron excitation of plasmons, tracing instantaneous movements of electrons to elucidate the physical dynamics of plasmons, and revealing electron spill-out effects of ultrasmall nanoparticles approaching the quantum limit. These preliminary demonstrations open the door to realistic particle simulations of plasmons. [ABSTRACT FROM AUTHOR]

Published

2020

6. Encapsulated Annealing: Enhancing the Plasmon Quality Factor in Lithographically–Defined Nanostructures.

Author

Bosman, Michel, Lei Zhang, Huigao Duan, Shu Fen Tan, Nijhuis, Christian A., Cheng–Wei Qiu, and Yang, Joel K. W.

Subjects

*LITHOGRAPHY, *SURFACE plasmon resonance, *NANOPARTICLES, *ELECTRON energy loss spectroscopy, *NUMERICAL analysis, *ANNEALING of metals

Abstract

Lithography provides the precision to pattern large arrays of metallic nanostructures with varying geometries, enabling systematic studies and discoveries of new phenomena in plasmonics. However, surface plasmon resonances experience more damping in lithographically–defined structures than in chemically–synthesized nanoparticles of comparable geometries. Grain boundaries, surface roughness, substrate effects, and adhesion layers have been reported as causes of plasmon damping, but it is difficult to isolate these effects. Using monochromated electron energy–loss spectroscopy (EELS) and numerical analysis, we demonstrate an experimental technique that allows the study of these effects individually, to significantly reduce the plasmon damping in lithographically–defined structures. We introduce a method of encapsulated annealing that preserves the shape of polycrystalline gold nanostructures, while their grain-boundary density is reduced. We demonstrate enhanced Q–factors in lithographically–defined nanostructures, with intrinsic damping that matches the theoretical Drude damping limit. [ABSTRACT FROM AUTHOR]

Published

2014