Colloidal Synthesis of Semiconductor Quantum Dots toward Large-Scale Production: A Review

Pu, Yuan; Cai, Fuhong; Wang, Dan; Wang, Jie‐Xin; Chen, Jianfeng

doi:10.1021/acs.iecr.7b04836

Cited by 270 publications

(183 citation statements)

References 163 publications

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“…Over the past decade, microfluidic technology has been widely applied to nanocrystal synthesis and reaction optimization, characterization of reaction kinetics, purification and surface modification . Compared to traditional batch‐based processes, flow‐based configurations can improve mass and heat transfer and precisely control reaction parameters, which is ideal for large‐scale nanomanufacturing . Despite extensive research on the synthesis of nanocrystals with a homogeneous structure, few studies have focused on the preparation of nanocrystals with heterostructures (like core/shell morphologies) in flow .…”

Section: Figurementioning

confidence: 99%

Multistage Microfluidic Platform for the Continuous Synthesis of III–V Core/Shell Quantum Dots

et al. 2018

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We present a fully continuous chip microreactor-based multistage platform for the synthesis of quantum dots with heterostructures. The use of custom-designed chip reactors enables precise control of heating profiles and flow distribution across the microfluidic channels while conducting multistep reactions. The platform can be easily reconfigured by reconnecting the differently designed chip reactors allowing for screening of various reaction parameters during the synthesis of nanocrystals. III-V core/shell quantum dots are chosen as model reaction systems, including InP/ZnS, InP/ZnSe, InP/CdS and InAs/InP, which are prepared in flow using a maximum of six chip reactors in series.

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Section: Figurementioning

confidence: 99%

Multistage Microfluidic Platform for the Continuous Synthesis of III–V Core/Shell Quantum Dots

et al. 2018

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“…Cuanto más comparable sea el radio de Borh y el diámetro de la nanopartícula, mayor será el ensanchamiento. El resultado neto de este fenómeno es la capacidad de sintonizar la emisión de un QD controlando su tamaño (figura 1), (Bera et al, 2010;Pu et al, 2018). Los QDs son altamente brillantes, sin embargo presentan defectos de superficie que promueven relajaciones no radiativas reduciendo su eficiencia de emisión; esto se resuelve agregando una capa sobre la superficie de un material con una banda prohibida mayor formando una nanopartícula tipo núcleo/coraza con la que se han reportado eficiencias cuánticas del 90% (Pu et al, 2018;Yang et al, 2015).…”

Section: Fundamentosunclassified

“…En este caso, se excita con luz en el cercano infrarrojo (NIR) y se obtiene luz visible. A este fenómeno se le conoce como conversión ascendente (UC, por sus siglas en inglés); es un fenómeno cooperativo pues requiere la absorción de al menos dos fotones de baja energía FIGURA 1. a) Diagrama esquemático que muestra la discretización de las bandas de energía y el ensanchamiento de la banda prohibida para un punto cuántico, λ 1 se refiere al fotón que excita el electrón de la banda de valencia a la banda de conducción y λ 2 se refiere al fotón (fluorescencia) que resulta de la recombinación del par electrón-hueco; b) diagrama esquemático que muestra el radio de Bohr del excitón (R Bexc ) y un punto cuántico de radio r; c) fotografía de puntos cuánticos de CdSe con diámetros entre 3 y 6 nm, obtenidos en nuestro laboratorio por el método de inyección caliente ampliamente reportado en la literatura, ver, por ejemplo (Bera et al, 2010;Pu et al, 2018;Yang et al, 2015). Fuente: Elaboración de los autores.…”

Section: Fundamentosunclassified

Algunas aplicaciones de la nanofotónica en la biomedicina

Rosa

Ramírez

Panikar³

et al. 2019

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In this work, the optical and electronic properties of nanomaterials are discussed, its fundamental characteristics and its application in the design of devices and techniques for detection, imaging and therapy, especially in cancer problems, are analyzed. Some recent results obtained in our laboratory where we have been able to measure concentrations of the order of 10 -22 moles of complexes of interest are discussed. We report the detection of residues in blood of medications of the order of 10 -8 and 10 -9 molar (M), which opens the way for drug monitoring with a focus on the implementation of a personalized medicine. We discuss results of therapy techniques with the use of nanomaterials that have allowed us to reduce cell viability below 10%. These results show that nanotechnology is changing the health paradigm to preventive medicine, personalized and available to everyone. RESUMEN:En este trabajo se discuten las propiedades ópticas y electrónicas de nanomateriales, se analizan sus características fundamentales y su aplicación en el diseño de dispositivos y técnicas para la detección, imagen y terapia, especialmente en problemas de cáncer. Se discuten algunos resultados recientes obtenidos en nuestro laboratorio donde hemos podido medir concentraciones del orden de 10 -22 moles de complejos de interés. Reportamos la detección de residuos en sangre de medicamentos del orden de 10 -8 y 10 -9 molar (M), lo que abre el camino para el monitoreo de fármacos con un enfoque a la implementación de una medicina persona-dewww.mundonano.unam.mx | Mundo Nano http://dx.doi.org/10.22201/ceiich.24485691e.2020.24.69618 | 13(24), 1e-24e, enero-junio 2020 Algunas aplicaciones de la nanofotónica en la biomedicina ◊ Some applications of nanophotonics in biomedicine 2eMundo Nano | artículos de investigación | www.mundonano.unam.mx 13(24), 1e-24e, enero-junio 2020 | http://dx.

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“…Advances in fabrication technologies have enabled the nanostructuring of three-dimensional (3D) bulk materials into lower-dimensional objects such as films [two-dimensional (2D)], wires [one-dimensional (1D)], and dots [zero-dimensional (0D)] [4][5][6]. Changes in the material dimensionality also affect the dimensionality of the BZ, thereby limiting the allowed wave vectors.…”

Section: Introductionmentioning

confidence: 99%

Mapping phonon modes from reduced-dimensional to bulk systems

Kim

Parrish

McGaughey

2019

Journal of Applied Physics

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An algorithm for mapping the true phonon modes of a film, which are defined by a twodimensional (2D) Brillouin zone, to the modes of the corresponding bulk material, which are defined by a three-dimensional (3D) Brillouin zone, is proposed. The algorithm is based on normal mode decomposition and is inspired by the observation that the atomic motions generated by the 2D eigenvectors lead to standing-wave-like behaviors in the cross-plane direction. It is applied to films between two and ten unit cells thick built from Lennard-Jones (LJ) argon, whose bulk is isotropic, and graphene, whose bulk (graphite) is anisotropic. For LJ argon, the density of states deviates from that of the bulk as the film gets thinner due to phonon frequencies that shift to lower values. This shift is a result of transverse branch splitting due to the film's anisotropy and the emergence of a quadratic acoustic branch. As such, while the mapping algorithm works well for the thicker LJ argon films, it does not perform as well for the thinner films as there is a weaker correspondence between the 2D and 3D modes. For graphene, the density of states of even the thinnest films closely matches that of graphite due to the inherent anisotropy, except for a small shift at low frequency. As a result, the mapping algorithm works well for all thicknesses of the graphene films, indicating a strong correspondence between the 2D and 3D modes. * mcgaughey@cmu.edu 1 arXiv:1907.02183v1 [cond-mat.mes-hall]

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Colloidal Synthesis of Semiconductor Quantum Dots toward Large-Scale Production: A Review

Cited by 270 publications

References 163 publications

Multistage Microfluidic Platform for the Continuous Synthesis of III–V Core/Shell Quantum Dots

Multistage Microfluidic Platform for the Continuous Synthesis of III–V Core/Shell Quantum Dots

Algunas aplicaciones de la nanofotónica en la biomedicina

Mapping phonon modes from reduced-dimensional to bulk systems

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