ライフサイエンスコーパス: quantum dot

1 the electron of a metal-oxide-semiconductor quantum dot.

2 states of an electron confined in a silicon quantum dot.

3 one-dimensional spin-orbit-coupled nanowire quantum dot.

4 a quadrupole charge qubit formed in a triple quantum dot.

5 mes reported to date in Si/SiGe gate-defined quantum dots.

6 has been limited to 50-65% for the nuclei in quantum dots.

7 tudy of single, isolated self-assembled InAs quantum dots.

8 two-component ligand shells passivating CdSe quantum dots.

9 widely used probes, including Alexa dyes and quantum dots.

10 e entanglement of electrons in semiconductor quantum dots.

11 g and selective etching of excess untargeted quantum dots.

12 of ever more complex many-body states using quantum dots.

13 advantages over traditional organic dyes and quantum dots.

14 hed carboxylates on the (100) facets of CdSe quantum dots.

15 onal (single or colloidal) dye molecules and quantum dots.

16 erent active materials such as semiconductor quantum dots.

17 well as other biotinylated molecules such as quantum dots.

18 fullerene derivative incorporating inorganic quantum dots.

19 a complex, which prevents aggregation of the quantum dots.

20 ntermediates in the synthesis of group III-V quantum dots.

21 on toxicity studies concerning all types of quantum dots.

22 reted as originating from single nanocrystal quantum dots.

23 the high-quality optical properties of II-VI quantum dots.

24 the electronic Coulomb blockade observed for quantum dots.

25 which are signatures of the Kondo effect in quantum dots.

26 and 30-fold narrower, respectively, than for quantum dots.

27 al clearance of metal ions released from the quantum dots.

28 ghest reported so far for optical cooling in quantum dots.

29 s and GaAs nanophotonic geometries with InAs quantum dots.

30 employing not neutral but negatively charged quantum dots.

31 monstrated through self-assembly of graphene quantum dots.

32 les as small as 50 nm in diameter and single quantum-dots.

33 over a serial connection of a single pair of quantum-dots.

34 ar force probes including mechanophores(10), quantum dots(11), fluorescent pairs(12,13) and molecular

35 A single-sized CdSe quantum dot (3.0 +/- 0.2 nm) can replace several differe

36 cavities containing self-assembled InAs/GaAs quantum dots-a mature class of solid-state quantum emitt

37 nanoparticles/thiol functionalized graphene quantum dot (AgNPs/thiol-GQD) nanocomposite for the meas

38 luding defects in diamond and self-assembled quantum dots, albeit often with compromised coherence an

39 sts ranging from classical dyes to drugs and quantum dots, allowing changes in the photochemical beha

40 , and 60 s, the silver was deposited only on quantum dots, allowing the generation of localized nanos

41 Immobilization on CdS quantum dots allows these catalysts to be active in pure

42 TAs based on two-dimensional (2D) antimonene quantum dots (AMQDs) was developed by a novel liquid exf

43 The system uses near-infrared quantum dots and a membrane-impermeable etchant, which s

44 erials, reliability in fabricating arrays of quantum dots and accurate qubit operations.

45 f a nanocomposite of functionalized graphene quantum dots and imprinted polymer at the surface of scr

46 ide further optimization of high quality InP quantum dots and might lead to the extension of syntheti

47 re obtained under UV excitation at 325nm for quantum dots and NIR excitation at 980nm for upconvertin

48 ections provide an introduction to colloidal quantum dots, and a theoretical basis to be able to unde

49 integrated with proteins, fluorescent dyes, quantum dots, and magnetic nanoparticles can be further

50 ts, luminescent carbon dots, nanocrystals as quantum dots, and photon up-converting particles.

51 or photochemical reduction of colloidal CdSe quantum dots, and we establish that these reactions proc

52 tistics and k.p theory with consideration of quantum dot anisotropy allows us to elucidate the origin

53 tly pumped emission spectra in comparison to quantum dots appearing in defect-free regions, and this

54 pening the possibility of polarisation-based quantum dot applications in on-chip conditions.

55 Colloidal semiconductor quantum dots are attractive materials for the realizatio

56 Here, double quantum dots are defined by gate voltages in indium anti

57 a detriment to applications in which single quantum dots are embedded within nanofabricated photonic

58 Qubits based on silicon quantum dots are emerging as leading candidates for the

59 The quantum dots are intravenously delivered into orthotopic

60 ectric device where electron hopping between quantum-dots are driven by hot phonons.

61 neighbour tunnel coupling in a semiconductor quantum dot array so as to simulate a Fermi-Hubbard syst

62 t-free, top-down method to create large-area quantum dot arrays with nanometer-scale spatial density

63 n monolayer molybdenum disulfide (MoS2), and quantum dot arrays with nanometer-scale spatial density

64 ine an approach that allows to assess single quantum dots as candidates for quantum nanophotonic devi

65 ic cysteamine-stabilized CdTe/ZnS core/shell quantum dots, as a result fluorescence quenching was acc

66 ess comparable to that of wavelength-matched quantum dots at both the ensemble and single-molecule le

67 ation control can be achieved in solid-state quantum dots at thermoelectrically cooled temperatures,

68 superlattices (HNC-SLs) self-assembled from quantum-dot-Au (QD-Au) satellite-type HNCs.

69 A boron-doped graphene quantum dot (B-GQD) as a metal-free multimodal contrast

70 ht also be useful to improve the fidelity of quantum dot based logic gates.

71 stripping signal at functionalized graphene quantum dots based imprinted sensor was realized to be a

72 cator of microbiological water quality, by a quantum dot-based MB.

73 The latest quantum dot-based single-photon sources are edging close

74 Here, a Mn-doped ZnS quantum dots-based immunoassay platform is presented for

75 d scheme should be regarded as a new type of quantum-dot-based interferometry.

76 the same attention as Group II-VI and III-V quantum dots, because of their lower emission quantum yi

77 Additionally, we show that these quantum dot bolometers demonstrate good performance at t

78 length (limited by the polydispersity of the quantum dot building blocks), but missing a fraction (20

79 processes are usually quenched in colloidal quantum dots by Auger and other nonradiative decay chann

80 ant nanoscale systems, including nanocrystal quantum dots, carbon nanotubes and graphene.

81 interaction between strong laser pulses and quantum dot-cavity polaritons.

82 e of the atomically precise cadmium selenide quantum dots Cd35Se20X30L30, Cd56Se35X42L42, and Cd84Se5

83 or Eu(3+) singly-doped borate glasses or CdS-quantum dot (CdS-QD) coated lenses efficiently convert U

84 s paper describes the use of cadmium sulfide quantum dots (CdS QDs) as visible-light photocatalysts f

85 he growth of CSH-stabilized cadmium sulphide quantum dots (CdS QDs).

86 We synthesized cadmium telluride quantum dots (CdTe QDs) capped with thioglycolic acid (T

87 to determine the impact of cadmium telluride quantum dots (CdTe QDs).

88 In particular, quantum dot circuits represent model systems for the stu

89 Here, we use quantum-dot-coated nanopipette electrodes (tip diameters

90 based on parametric downconversion sources, quantum dots, colour centres or atoms are fundamentally

91 compared to many Group II-VI and III-V based quantum dots, compatibility with the existing semiconduc

92 tion and device fabrication of semiconductor quantum dots continue to improve, the ideas presented he

93 A promising device is a superconductor-two quantum dots Cooper pair splitter.

94 Chains of quantum dots coupled to superconductors are promising fo

95 Carbon quantum dots (CQDs) are new-generation light absorbers f

96 Colloidal quantum dots (CQDs) feature a low degeneracy of electron

97 Recently, doped colloidal quantum dots (CQDs) have been demonstrated to be promisi

98 Carbon quantum dots (CQDs) obtained from natural organics attra

99 f magnitude shorter than small PbS colloidal quantum dots (CQDs), and a quantum yield of approximatel

100 s, such as Ti-Si molecular sieves and carbon quantum dots (CQDs), are also briefly appraised in view

101 Carbon quantum dots (CQDs), with an average size around 3.2 nm,

102 f magnitude shorter than small PbS colloidal quantum dots (CQDs).

103 we report that cesium lead iodide perovskite quantum dots (CsPbI3 QDs) can be used as catalysts to pr

104 Therefore, the Microbead Quantum-dots Detection System (MQDS) was developed to id

105 Our quantum dot device architecture enables multi-qubit algo

106 g in a nominally perfectly-fabricated single quantum dot device failing to behave in accordance with

107 multiple charge configurations of the double quantum dot device.

108 of fluorescence emission down to 0.28 nM for quantum dot dispersions and 32 ng/mL for near-infrared d

109 Double quantum dots (DQDs) are a versatile platform for solid-s

110 anic fluorescent dyes ( approximately 4 nm), quantum dots, either small ( approximately 10 nm diamete

111 unlock a route for further progress towards quantum dot electron spin qubits where deep cooling of t

112 Strong coupling of a quantum dot electron to a cavity photon would allow for

113 les (Ag-NPs) of different sizes and graphene quantum dot embedded IML.

114 s in a semiconductor device: a chain of InAs quantum dots embedded in an InP nanowire.

115 Graphene quantum dots embedded silica molecular imprinted polymer

116 g the number and energy configuration of the quantum-dots embedded in parallel nanowires.

117 ity modes designed to resonantly enhance the quantum dot emission, thereby resulting in a nominally p

118 We used lattice light-sheet and quantum dot-enabled synaptic contact mapping microscopy

119 iew the work on other types of semiconductor quantum dots, especially on Si and Ge nanocrystals.

120 lication of a new magnetic chitosan-graphene quantum dots (Fe3O4@Chi-GQDs) nanocomposite as an adsorb

121 e a very attractive feature of semiconductor quantum dots for optoelectronics applications.

122 brations to bulk phonons in cadmium selenide quantum dots for the first time.

123 Here we report that iron (Fe) quantum dots functionalized boron nitride nanotubes (QDs

124 Despite this, the quantum dots generally do not exhibit significant differ

125 Quantum dots-Gold nanoparticle (QDs-GNP) based FRET prob

126 tively produce either GQDs or graphene oxide quantum dots (GOQDs) by simply changing the organic solv

127 lver nanoparticle (AgNPs) and thiol graphene quantum dots (GQD-SH) as the nanomaterial for ultrasensi

128 Biofunctional magnetic graphene quantum dots (GQDs) combined with two biofunctional quan

129 Graphene quantum dots (GQDs) have attractive properties and poten

130 rough light-matter interaction with graphene quantum dots (GQDs).

131 nd mass characterization of indium phosphide quantum dot growth mixtures.

132 Magnetically N-doped Carbon quantum dots has been synthesized via a simple chemical

133 rious potential applications, InAs colloidal quantum dots have attracted considerably less attention

134 While individual superconducting quantum dots have been explored, control of longer chain

135 ed energy levels of individual semiconductor quantum dots have been measured by means of scanning tun

136 patibility, single-strand DNA-functionalized quantum dots have been widely applied in biosensing and

137 These quantum dots have benzoate (X) and n-butylamine (L) liga

138 However, III-V quantum dots have historically struggled to match the hi

139 ible light illumination while preserving the quantum dot in the desirable cubic crystal phase.

140 By designing the quantum dots in a 2D superlattice, we show that new ener

141 scribe the biosynthesis of infrared emitting quantum dots in a living plant via a mutual antagonistic

142 re found in agreement with a numerical model.Quantum dots in a nanowire are one possible approach to

143 eraged to deterministically couple donors to quantum dots in arrays of qubits.

144 ue to single-electron charging of individual quantum dots in carbon nanotubes.

145 nterface between Si3N4 waveguides and single-quantum dots in GaAs geometries, with performance approa

146 ble, site and size controlled fabrication of quantum dots in monolayer molybdenum disulfide (MoS2), a

147 Herein, graphene quantum dots in nanocomposite practically induced the el

148 e positively charged functionalized graphene quantum dots in the film and the target analyte toward t

149 By controlled positioning of individual quantum dots in the near field of gold nanocone antennas

150 n be controlled by the size and pitch of the quantum dots in the superlattice.

151 larisation control by growth, in solid-state quantum dots in the thermoelectrically cooled temperatur

152 Ordered arrays of quantum dots in two-dimensional (2D) materials would mak

153 Epitaxial attachment of quantum dots into ordered superlattices enables the synt

154 rk shows that an electron spin in an Si/SiGe quantum dot is a good candidate for quantum information

155 t outcoupling (100x) from PHCs embedded with quantum dots is observed.

156 t DA based on l-cysteine capped Mn doped ZnS quantum dots (l-cys ZnS:Mn QDs).

157 site of uniform-size semiconducting graphene quantum dots laterally integrated within a larger-bandga

158 Subsequent etching quenches excess quantum dots, leaving a highly tumor-specific signal pro

159 Here, we present quantum dot light emitting diodes (QDLEDs) with a metasu

160 Here transparent quantum dot light-emitting diodes (Tr-QLEDs) are reporte

161 ecularly imprinted silica layers appended to quantum dots (MIP-QDs) with customized selective artific

162 d predictably tuned through variation of the quantum dot-molecule energy gap, temperature and the tri

163 f 3-mercaptopropionic acid (MPA)-capped CdSe quantum dot (MPA-CdSe QD) and visible light.

164 sisting of N-acetyl-L-cysteine capped CdAgTe quantum dots (NAC-CdAgTe QDs) and dodecahedral gold nano

165 synthesized a unique series of 42 different quantum dot nanocrystals, composed of two chemical domai

166 andwich assay that implements functionalized quantum dots (NanoEnhancers) as signal amplifiers to ach

167 be necessary to improve the yield of single quantum dot nanophotonic devices.

168 miconductors as well, including perovskites, quantum dots, nanotubes and two-dimensional materials.

169 Highly fluorescent nitrogen doped carbon quantum dots (NCQDs) were synthesized using microwave as

170 report that nanometre-size N-doped graphene quantum dots (NGQDs) catalyse the electrochemical reduct

171 We anticipate that the approach of screening quantum dots not only based on their optical properties,

172 superparamagnetic iron oxide, or fluorescent quantum dot NPs after they have been administrated to a

173 gy transfer (NRET) from adjacent nanocrystal quantum dot (NQD) films.

174 acterization techniques, we find that single quantum dots often appear in the vicinity of comparative

175 From this, it is determined that ZnO quantum dots on bulk n-InGaN with low In content x is th

176 by uniformly decorating semiconducting CdSe quantum dots on Si channel (Si-QD).

177 The emerging generation of quantum dot optoelectronic devices offers an appealing p

178 , TMR-D; microperoxidase-11, MP-11; CdSe/ZnS quantum dots; or doxorubicin-modified dextran, DOX-D) is

179 -NCs) are emerging as an attractive class of quantum dots owing to the natural abundance of silicon i

180 125 (CA 125) using polyamidoamine dendrimer-quantum dots (PAMAM-QDs) and PAMAM-sulfanilic acid-Ru(bp

181 e demonstrate complete coherent control of a quantum dot-photonic crystal cavity based quantum-bit.

182 t to non-invasively characterise these donor quantum dots post fabrication and extract the number of

183 Compared to the batch of CdS quantum dots prepared by capping with only mercaptoaceti

184 l to probe with conventional methods.Silicon quantum dots provide a promising platform for quantum co

185 Electron spins in gate-defined quantum dots provide a promising platform for quantum co

186 ectron and the nuclei of an optically active quantum dot provides a uniquely rich manifestation of th

187 we demonstrate an ultrathin freestanding ZnO quantum dot (QD) active layer with nanocellulose structu

188 ercaptohexanoate (MHA) ligand shell of a PbS quantum dot (QD) and water.

189 The physical properties of a doped quantum dot (QD) are strongly influenced by the dopant s

190 the mixed-PFDT/oleate ligand shell of a PbS quantum dot (QD) dramatically reduces the permeability o

191 Controlling the thickness of quantum dot (QD) films is difficult using existing film

192 a total of 12 molecular and 6 semiconductor quantum dot (QD) fluorophores.

193 important growth intermediates during III-V quantum dot (QD) formation.

194 escence, via oriented attachment directed by quantum dot (QD) surface chemistry.

195 Toward a truly photostable PbSe quantum dot (QD), we apply the thick-shell or "giant" QD

196 resent study reports the fabrication of CdSe quantum dot (QD)-sensitized photocathodes on NiO-coated

197 Fluorescent nanoparticles such as quantum dots (QD) offer superior optical characteristics

198 oped a microfluidic system integrated with a quantum dots (Qdots) aptamer functionalized graphene oxi

199 ed light emission by colloidal semiconductor quantum dots (qdots).

200 luorescence cross sections for semiconductor quantum dots (Qdots).

201 resonance energy transfer (FRET) between CdS quantum dot (QDs) as a donor and polypyrrole (Ppy) as an

202 ce that is structured by stacking a layer of quantum dots (QDs) and a layer of piezoelectric material

203 Aptamer-conjugated Quantum dots (QDs) are adsorbed to Au nanoparticles (AuN

204 -exchange reactions with as-synthesized CdSe quantum dots (QDs) are chosen as two model reactions.

205 CdTe/CdS quantum dots (QDs) are encapsulated in the pores of the

206 Quantum dots (QDs) are extremely bright, photostable, na

207 Luminescent semiconductor quantum dots (QDs) are one of the more popular nanomater

208 The key to utilizing quantum dots (QDs) as lasing media is to effectively red

209 ess, we demonstrate the patterning of single quantum dots (QDs) at predefined locations on silicon an

210 Chemically synthesized semiconductor quantum dots (QDs) can potentially enable solution-proce

211 Here we show that colloidal nanocrystal quantum dots (QDs) can serve as efficient and robust, pr

212 Mn-doped ZnS quantum dots (QDs) coated with a molecularly imprinted p

213 Quantum dots (QDs) derived from the atomically-thin two-

214 ld nanorods as model plasmonic systems, InAs quantum dots (QDs) embedded in an InGaAs quantum well as

215 The dye rhodamine and two InP/ZnS quantum dots (QDs) emitting in the green and in the red

216 A sub-monolayer CdS shell on PbS quantum dots (QDs) enhances triplet energy transfer (TET

217 c acid (TGA)-capped cadmium-telluride (CdTe) quantum dots (QDs) exposing green emission were directly

218 active index material and colloidal CdSe/CdS quantum dots (QDs) for applications in the visible regio

219 dering of arrays of self-assembled InAs-GaAs quantum dots (QDs) has been quantified as a function of

220 istry of colloidal semiconductor nanocrystal quantum dots (QDs) have been central to the field for ov

221 Quantum dots (QDs) have been widely used in chemical and

222 (NCs) and, more specifically, semiconductor quantum dots (QDs) have emerged as crucial materials for

223 chirality on electron-transfer rates between quantum dots (QDs) in chiral QD assemblies.

224 The use of semiconductor nanocrystal quantum dots (QDs) in optoelectronic devices typically r

225 We report optical positioning of single quantum dots (QDs) in planar distributed Bragg reflector

226 tion, sedimentation, and dissolution of CdSe quantum dots (QDs) in seawater were investigated.

227 Emission control of colloidal quantum dots (QDs) is a cornerstone of modern high-quali

228 An emerging trend with semiconductor quantum dots (QDs) is their use as scaffolds to assemble

229 s) of size 2.8, 4.6, 7.2, or 9.0 nm and CdSe quantum dots (QDs) of size approximately 3.3 nm.

230 -, and charge transfer in multilayer CdS/ZnS quantum dots (QDs) on silver plasmonic resonators using

231 Zero-dimensional MoS2 quantum dots (QDs) possess distinct physical and chemica

232 acid) (PLGA) with bright, spectrally defined quantum dots (QDs) to enable direct, fluorescent detecti

233 show nanoscale phase stabilization of CsPbI3 quantum dots (QDs) to low temperatures that can be used

234 st by colloidal, heavy metal-free CuInS2/ZnS quantum dots (QDs) to reduce CO2 to CO using 450 nm ligh

235 electronic impurity doping of colloidal PbSe quantum dots (QDs) using a postsynthetic cation exchange

236 A secondary antibody labeled with dyes/quantum dots (QDs) was used to visualize the presence of

237 ol in food and feed, CdSe/CdS/ZnS core-shell quantum dots (QDs) were encapsulated in silica nanoparti

238 PbS quantum dots (QDs) were grown on mesoporous TiO2 film us

239 dots (GQDs) combined with two biofunctional quantum dots (QDs) were used for simultaneously detectin

240 e a novel photopolymerization method to coat quantum dots (QDs) with polymer shells, in particular, m

241 ned FRET pair, including the donor, CdSe/ZnS quantum dots (QDs), and the acceptor, dextran-binding ma

242 dal semiconductor nanocrystals, specifically quantum dots (QDs), can be tuned over 2.0 eV through sur

243 nomaterials cover gold nanoparticles (GNPs), quantum dots (QDs), carbon nanotubes (CNTs), and graphen

244 articles (MNPs), carbon based nanomaterials, quantum dots (QDs), magnetic nanoparticles and polymeric

245 esting nanomaterials, such as semiconducting quantum dots (QDs), metal nanoparticles, semiconductor-m

246 ith streptavidin-conjugated Pb- and Cd-based quantum dots (QDs), respectively, the QD labels are diss

247 one by visible-light-absorbing colloidal CdS quantum dots (QDs), without a sacrificial oxidant or red

248 tamer on water soluble l-cysteine capped ZnS quantum dots (QDs).

249 aneous detection of three gene targets using quantum dots (QDs).

250 ganic dyes, metal chelates and semiconductor quantum dots (QDs).

251 he synthesis of copper iron sulfide (CuFeS2) quantum dots (QDs).

252 nal response in the fluorescence of CdTe@CdS quantum dots (QDs).

253 ctron transport layers (ETLs) and engineered quantum dots (QDs).

254 the 15-2b antibody had high sensitivity for quantum dot quantification down to 7 pM.

255 Quantum dot qubits, in contrast, are highly adjustable u

256 This includes quantum dot radiative rate enhancement in microcavities,

257 Here we fabricated superlattices with the quantum dots registered to within a single atomic bond l

258 tumor-specific signal provided by the intact quantum dots remaining in the extravascular tumor cells

259 immunolabeling of the apoptotic cells using quantum dot reporters.

260 vegetable oils, based on CdSe/ZnS core-shell quantum dots sensitized with lithium tetracyanoethylenid

261 ment for solar energy applications in dye or quantum dot-sensitized solar cells, polymer-fullerene po

262 This work reports a PbS-quantum-dot-sensitized solar cell (QDSC) with power conv

263 ion/post-transition metal dichalcogenides or quantum dots sensitizers, obtaining fast photoresponse s

264 Here we present a quantum dot signalling-based cell assay carried out in a

265 (0.33, 0.33) is fabricated using perovskite quantum dot/silica composites.

266 ious materials, for example, NaBr, collagen, quantum dots, silver and polystyrene colloids.

267 es, including down-conversion nanoparticles, quantum dots, single-walled carbon nanotubes, and organi

268 how that toxicity is closely correlated with quantum dot surface properties (including shell, ligand

269 Here, the authors develop a tumor-specific quantum dot system that permits in vivo cation exchange

270 hotons, controlled by a single semiconductor quantum dot that is weakly coupled to a monolithic cavit

271 internal control probes were conjugated with Quantum dots that fluoresce at different emission wavele

272 lly available organic dyes and semiconductor quantum dots, the CD aggregates provided a 10-7000-fold

273 Similarly for a fixed number of quantum-dots there is an optimal energy-step for the out

274 Here we show that for gate-defined quantum dots this disorder can be suppressed in a contro

275 The etchant rapidly quenches the quantum dots through cation exchange (ionic etching), an

276 e evolution of clusters and the formation of quantum dots throughout the synthesis.

277 Specifically, we couple a quantum dot to a high-quality-factor microwave cavity to

278 transfer from the biexcitonic state of a CdS quantum dot to an adsorbed tetracationic compound cyclob

279 he coupling of electronic states in a double quantum dot to form Andreev molecule states; a potential

280 ing of a single electron in a silicon double quantum dot to the photonic field of a microwave cavity,

281 We use semiconductor quantum dots to deterministically generate long strings

282 dimensional confinement allows semiconductor quantum dots to exhibit size-tunable electronic and opti

283 oof of concept, we use downshifting CdSe/CdS quantum dots to improve the performance of a silicon sol

284 nometer-scale spatial density that allow the quantum dots to interfere with each other and create art

285 y, we first show that exposing oleate-capped quantum dots to primary carboxylic acids results in a on

286 l of LSPC-synthesized materials ranging from quantum dots to submicrometer spheres and recent upscali

287 in the presence and the absence of graphene quantum dots (un-functionalized), respectively.

288 1-pyrenecarboxylic acid-functionalized CdSe quantum dots undergo thermally activated delayed photolu

289 s, carbon nanoparticles, gold nanoparticles, quantum dots, upconversion nanoparticles, and polymeric

290 dditionally, the combination of graphene and quantum dots was also included to explore the fluorescen

291 Thus, the fluorescence intensity of the quantum dots was enhanced upon the de-aggregation, which

292 topropionic acid (3-MPA) capped lead sulfide quantum dots were prepared in a variety of organic solve

293 In 2000, semiconductor quantum dots were shown to emit single photons, opening

294 sure the nuclear polarization in GaAs/AlGaAs quantum dots with high accuracy using a new approach ena

295 applying photodoping to specially engineered quantum dots with impeded Auger decay, we demonstrate a

296 In fact, the covalent attachment of graphene quantum dots with N-acryloyl-4-aminobenzamide molecules

297 design a synthesis of large indium arsenide quantum dots with narrow emission linewidths.

298 This results in state-of-the-art InAs quantum dots with respect to the size dispersion and ban

299 meanwhile, novel nanocarriers such as carbon quantum dots with their recent applications in drug deli

300 he photophysical properties of semiconductor quantum dots with those of well-understood and inexpensi