Colloidal semiconductor nanocrystals: the aqueous approach
about
Ultrasensitive quantum dot fluorescence quenching assay for selective detection of mercury ions in drinking water.Nano-imaging enabled via self-assembly.Spectra Library: An Assumption-Free In Situ Method to Access the Kinetics of Catechols Binding to Colloidal ZnO Quantum Dots.Co-doping of Ag into Mn:ZnSe Quantum Dots: Giving Optical Filtering effect with Improved MonochromaticityBiocompatible Fluorescent Core-Shell Nanoconjugates Based on Chitosan/Bi2S3 Quantum Dots.Dye-doped silica nanoparticles as luminescent organized systems for nanomedicine.Magnetically engineered semiconductor quantum dots as multimodal imaging probes.Luminescent sensors based on quantum dot-molecule conjugates.A sustainable future for photonic colloidal nanocrystals.Nanoparticles and DNA - a powerful and growing functional combination in bionanotechnology.Interfacing Luminescent Quantum Dots with Functional Molecules for Optical Sensing Applications.Highly efficient and recyclable triple-shelled Ag@Fe3O4@SiO2@TiO2 photocatalysts for degradation of organic pollutants and reduction of hexavalent chromium ions.Water-soluble, luminescent ZnTe quantum dots: supersaturation-controlled synthesis and self-assembly into nanoballs, nanonecklaces and nanowires.Probing Absolute Electronic Energy Levels in Hg-Doped CdTe Semiconductor Nanocrystals by Electrochemistry and Density Functional Theory.Absolute photoluminescence quantum yields of IR26 and IR-emissive Cd(1-x)Hg(x)Te and PbS quantum dots--method- and material-inherent challenges.Hydrogen production on a hybrid photocatalytic system composed of ultrathin CdS nanosheets and a molecular nickel complex.A new insight into the thermodynamical criterion for the preparation of semiconductor and metal nanocrystals using a polymerized complexing method.Biomimetic Inspired Core-Canopy Quantum Dots: Ions Trapped in Voids Induce Kinetic Fluorescence Switching.5-(2-Mercaptoethyl)-1H-tetrazole: Facile Synthesis and Application for the Preparation of Water Soluble Nanocrystals and Their Gels.The relationship between photoluminescence (PL) decay and crystal growth kinetics in thioglycolic acid (TGA) capped CdTe quantum dots (QDs).Nucleation temperature-controlled synthesis and in vitro toxicity evaluation of L-cysteine-capped Mn:ZnS quantum dots for intracellular imaging.A facile and universal top-down method for preparation of monodisperse transition-metal dichalcogenide nanodots.Flexible and fragmentable tandem photosensitive nanocrystal skins.Stable and conductive lead halide perovskites facilitated by X-type ligands.Monolayer Silane-Coated, Water-Soluble Quantum Dots.Methods to Characterize the Oligonucleotide Functionalization of Quantum Dots.Modulation of the solubility of luminescent semiconductor nanocrystals through facile surface functionalizationIn Situ Construction of Nanoscale CdTe-CdS Bulk Heterojunctions for Inorganic Nanocrystal Solar CellsLight Harvesting and Photoemission by Nanoparticles for Photodynamic TherapyGrowth kinetics study revealing the role of the MPA capping ligand on adjusting the growth modes and PL properties of CdTe QDsExperimental and theoretical investigations of the ligand structure of water-soluble CdTe nanocrystalsResonance energy transfer in self-organized organic/inorganic dendrite structuresInfluence of the stabilizing ligand on the quality, signal-relevant optical properties, and stability of near-infrared emitting Cd1−xHgxTe nanocrystalsThe structure-dependent quantum yield of ZnCdS nanocrystalsEfficient inorganic solar cells from aqueous nanocrystals: the impact of composition on carrier dynamicsRNA-mediated fluorescent colloidal CdSe nanostructures in aqueous medium – analysis of Cd2+ induced folding of RNA associated with morphological transformation (0D to 1D), change in photophysics and selective Hg2+ sensingEFFECT OF THE STRUCTURE OF ISOMERS OF MERCAPTOVALERIC ACID ON OPTICAL PROPERTIES OF CdTe QUANTUM DOTSOn-the-Spot Immobilization of Quantum Dots, Graphene Oxide, and Proteins via HydrophobinsTemperature Sensitivity of Water-Soluble CdTe and CdSe/ZnS Quantum Dots Incorporated into Biopolymer Submicron Particles
P2860
Q33868226-4D05F8A9-745B-4448-B544-F757F12027B5Q34665544-766B3F62-E186-4F29-B584-A9FB126A6C6CQ35860906-2E28806F-ECD8-4FA4-AFF5-AE95B13C876FQ36134320-EB8D3554-7022-45D1-AF45-A7E1E98BB3D0Q36788889-177FCEEF-360B-415B-8489-8A6E0D16AA4FQ38197082-328EBB0F-8860-4C01-90CA-B0DE004B3567Q38245271-96D750AC-64CD-4A8D-9637-581381BEED5AQ38442272-E1B44C7B-E0CC-4F2F-BDB5-FDF782A08FC8Q38530512-D3CF5E60-EB43-4BB9-996F-5302712DD30BQ38808906-54E42FA3-6D2A-4B9C-8FF0-748D3B106E00Q38942609-56A9EAFD-2EEF-401B-8F5A-61237B44F584Q39214042-FC3450A6-A517-4ACD-B1F5-9461822FAE38Q40037269-FD006F33-246F-4172-AB00-DDE54B8C5B1AQ40073560-7E62F59C-096F-41FC-8A43-7223D7B7C9DCQ44846570-81772068-C707-41FC-95EA-72856A98AF45Q46775289-769111CD-49B1-404C-BDD1-A820A3EFAD9DQ47729641-979AF5EA-36E5-4059-BDCB-75A1E8BBEC32Q48051347-CFA58079-776F-4E56-ABCE-7D89D921F237Q48098955-1C025879-BBA8-4597-A78D-F4658510520EQ50471909-274DFAF1-C694-4F1A-8122-F499D4C38A5FQ50577585-438A034D-F7C4-4359-8016-E4237F03BCFAQ50747340-30BD0268-04EF-4ED1-BEF6-967730B5A487Q50786519-A47EA4F9-1812-4345-8B9A-10B7A2ABBD22Q50870804-E389A485-22C9-40CA-B423-D6763C2804D9Q51682109-C80F749C-937C-45C2-9199-EF408C903A8AQ54075575-8483A415-3A59-48B0-8D1E-787403B051FEQ56972898-B9D52BC6-F935-4888-8C88-48B6ADF98738Q57344247-17CD2F99-891C-40EE-9574-007F0D130B99Q57345360-467E63A9-6CFA-43E0-983E-10ADA00E7F30Q57351389-26158848-AB84-438F-8463-5CF2941B6F49Q57351399-62A65247-22AF-4B58-B9D2-B050FBA1AD87Q57351419-103682C8-F461-461B-AF7F-FBCAF9651431Q57351803-EC035D0A-28BC-4000-8478-8BA7E67E13CBQ57351880-FB78AF23-B1E6-49DE-BBD3-B6622CA49B01Q57351989-45E1A466-FA4C-46BA-8CDE-24BA7092570DQ57352285-36081C27-01C1-4DF9-9F2F-E8E0CDEB61D6Q57353944-7A081B04-EE6B-4659-A9F0-B2BD21B87EE0Q57630988-784806A9-B56F-44D7-A941-5B1C73BFC8BDQ58855631-0C34552F-5A22-4819-AF24-D5F9804D2D97
P2860
Colloidal semiconductor nanocrystals: the aqueous approach
description
im Januar 2013 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2013
@uk
name
Colloidal semiconductor nanocrystals: the aqueous approach
@en
Colloidal semiconductor nanocrystals: the aqueous approach
@nl
type
label
Colloidal semiconductor nanocrystals: the aqueous approach
@en
Colloidal semiconductor nanocrystals: the aqueous approach
@nl
prefLabel
Colloidal semiconductor nanocrystals: the aqueous approach
@en
Colloidal semiconductor nanocrystals: the aqueous approach
@nl
P2860
P50
P356
P1476
Colloidal semiconductor nanocrystals: the aqueous approach
@en
P2860
P304
P356
10.1039/C2CS35285K
P577
2013-01-01T00:00:00Z