ライフサイエンスコーパス: quantum dot

1 state to transfer a single electron to each quantum dot.

2 by triplet-triplet energy transfer from the quantum dot.

3 a single electron or a single hole into the quantum dot.

4 -exchange processes across the multielectron quantum dot.

5 onant exchange qubit hosted in a GaAs triple quantum dot.

6 trons, without the need for a self-assembled quantum dot.

7 uced by the photon flux interacting with the quantum dot.

8 coherence while moving the electron between quantum dots.

9 lenide/cadmium sulfide (CdSe/CdS) core-shell quantum dots.

10 nts, based on the molar concentration of the quantum dots.

11 fabricated from solution-processed colloidal quantum dots.

12 isiae and Debaryomyces spp.) by TC or by its quantum dots.

13 localised states along the perimeter of the quantum dots.

14 d polymer active materials and semiconductor quantum dots.

15 hores, rather than traditional semiconductor quantum dots.

16 ransfer individual electrons between distant quantum dots.

17 e on-axis Si (001) substrates by using III-V quantum dots.

18 s and GaAs nanophotonic geometries with InAs quantum dots.

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

20 ion of electron spin qubits in semiconductor quantum dots.

21 to study various aspects of the synthesized quantum dots.

22 ons or holes can be loaded one-by-one into a quantum dot(1,2).

23 charge sensors, capacitively coupled to the quantum dots(11).

24 rating electrically controllable nuclei with quantum dots(11,12) could pave the way to scalable, nucl

25 combined with the required proximity to the quantum dots(12).

26 f spin-dependent electron tunnelling between quantum dots(13-15).

27 s with a net spin in optically active WSe(2) quantum dots(13-17) and we initialize their spin-valley

28 detected by means of a surface-acoustic-wave quantum dot(14), this method does not allow for a time-r

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

30 of a four-electron-site square plaquette of quantum dots(4) to demonstrate Nagaoka ferromagnetism(5)

31 ined in gated, isotopically enhanced silicon quantum dots(6).

32 oscillating microwire and a single embedded quantum dot(9).

33 ary n- and p-channel transistors in a common quantum dot active layer.

34 he non-conducting configurations of a double quantum dot, allowing us to observe the theoretically pr

35 Cubic phase CsPbI(3) quantum dots (alpha-CsPbI(3) QDs) as a newly emerging ty

36 etect single electron tunnelling in a double quantum dot and demonstrate that gate-based sensing can

37 non-ergodic regime characterizes mesoscopic quantum dot and diamond defect systems, as we see no num

38 on of two powerful technologies is reported, quantum dot and signal amplification by exchange reactio

39 highlight the limitations of self-assembled quantum dots and advantages of strain-free dots, where o

40 mer-capped acrylated nitrogen doped graphene quantum dots and bimetallic Au/Ag core-shell was synthes

41 ssembly of acrylated nitrogen doped graphene quantum dots and bimetallic Au/Ag core-shell@imprinted p

42 th factors in single cells using fluorescent quantum dots and calibrated three-dimensional deconvolut

43 ent state-of-the-art nanomaterials including quantum dots and carbon nanotubes have demonstrated CM,

44 Solid-state emitters(5), such as quantum dots and defects in diamond or silicon carbide(6

45 essed nanomaterials, including semiconductor quantum dots and nanoplatelets, and metal plasmonic and

46 cal potential on the surfaces of illuminated quantum dots and near fluorescing molecules.

47 cs were assigned to structures of individual quantum dots and the excitation dipoles were visualized

48 cles of different compositions (e.g., Au and quantum dots) and shapes (e.g., spheres and rods).

49 ments of thermoelectric response of a single quantum dot, and demonstrate how it can be used to deduc

50 sitized release using molecular sensitizers, quantum dots, and upconversion and second-harmonic nanop

51 ether with the ground-state resonant peak of quantum dots appearing in the photoluminescence excitati

52 The quantum dots are crystalline, with hexagonal shape, and

53 Zero-dimensional PbSe quantum dots are heterogeneously nucleated and grown ont

54 In this regard, single semiconductor quantum dots are highly promising photon pair sources as

55 ted with the presence of toxic metals, these quantum dots are not well suited for applications in CMO

56 All quantum dots are simultaneous absorbers and scatterers i

57 These 2-D layered material derived quantum dots are synthesized via one-step liquid exfolia

58 tween electrons in a semiconductor quadruple quantum dot array, we generate a series of coherent SWAP

59 quantum dot arrays in omni-resolution scale; quantum dot arrays from single-particle resolution to th

60 ng, which enables patterning and printing of quantum dot arrays in omni-resolution scale; quantum dot

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

62 Red-green-blue quantum dot arrays with unprecedented resolutions up to

63 orting single electrons across large silicon quantum dot arrays.

64 an be increased by employing a multielectron quantum dot as a mediator, while preserving speed and co

65 Using calcite crystals containing quantum dots as a model system, we here use 3D stochasti

66 Our results establish nuclear spins in quantum dots as a powerful new resource for quantum proc

67 o be regarded as atomically precise graphene quantum dots, as a new class of fluorophores for super-r

68 culations provide additional support for the quantum dot behavior observed.

69 ed biosensor approach based on boron nitride quantum dots (BNQDs) was presented for cTnI detection in

70 e, we prepared a biomimetic black phosphorus quantum dot (BPQDs) formulation to induce breast cancer

71 Compared to common semiconducting quantum dots, C-Dots have good physicochemical, as well

72 ss rate ratio realized in magnetically doped quantum dots can enable effective schemes for capturing

73 In contrast, semiconductor quantum dots can generate triggered entangled photon pai

74 Here we show that silicon quantum dots can have sufficient thermal robustness to e

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

76 aces enables a new paradigm wherein molecule-quantum dot constructs are used to systematically genera

77 sisting of a transition metal dichalcogenide quantum dot coupled to a graphene contact through an ato

78 Considering the example of a driven quantum dot coupled to phonons, we demonstrate that it i

79 rticles (N-CNPs) and nitrogen-doped graphene quantum dots coupled to nanosheets (N-GQDs-NSs) by using

80 observe the stronger Purcell enhancement of quantum dots coupled to the aperiodic metal-dielectric m

81 emplate-assisted assembly of emissive carbon quantum dot (CQD) microcrystals on organized cellulose n

82 We report the discovery of a cationic carbon quantum dot (cQD) probe that emits spectrally distinguis

83 antum particles, especially spherical carbon quantum dots (CQDs) and nanosheets like graphene quantum

84 Colloidal quantum dots (CQDs) are of interest in light of their so

85 Colloidal quantum dots (CQDs) are structurally robust materials pr

86 of 3D nanophotonic structures with colloidal quantum dots (CQDs) faces several technological obstacle

87 Halide perovskite colloidal quantum dots (CQDs) have recently emerged as a promising

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

89 Ps) on fluorescence (FL) intensity of carbon quantum dots (CQDs).

90 rystals (HNCs), consisting of near-spherical quantum dots decorated with regular arrangements of smal

91 o silicon metal oxide semiconductor (Si-MOS) quantum dot devices on a printed circuit board (PCB).

92 electron transport features in gate-defined quantum dot devices with a gate voltage space of up to e

93 Remarkably, neutral quantum dots do not exhibit such spin-valley initializat

94 arge-scale W states of electrons in a double quantum dot (DQD).

95 So far, most research on quantum dot electronic devices has focused on materials

96 The emerging technology of colloidal quantum dot electronics provides an opportunity for comb

97 A composite nanolayer with zinc oxide quantum dots embedded in amorphous zinc oxide domains ge

98 multaneous imaging of ErNPs and lead sulfide quantum dots emitting in the same ~1,600 nm window.

99 le-exciton properties of CdSe/CdS core/shell quantum dots enable us to simultaneously study the two b

100 and geometrical features (from thin films to quantum dots) enable their adoption in biomedical applic

101 anic semiconductors and lead based colloidal quantum dots face certain fundamental challenges that li

102 and graphene oxide is very low and graphene quantum dot fluorescence emission was OFF.

103 nsor with use of graphene oxide and graphene quantum dot for detection Campylobacter jejuni whole cel

104 e energy transfer between graphene oxide and quantum dots for determination of E. coli O157:H7 in bee

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

106 o identify and isolate biosensing TFs, and a quantum-dot Forster Resonance Energy Transfer (FRET) str

107 the valley lifetime of a single charge in a quantum dot from the recombination time to be of the ord

108 , we show that intravenously injected carbon quantum dots, functionalized with multiple paired alpha-

109 liquid-exfoliation of ultra-small germanene quantum dots (GeQDs) is presented.

110 Here, a colloidal graphene quantum dot (GQD)-based nanosurfactant is reported to st

111 r nanoparticle composite, PEGylated graphene quantum dot (GQD)-decorated Silver Nanoprisms (pGAgNPs),

112 carbon electrode (GC) modified with graphene quantum dots (GQDs) and Nafion (NF) has been developed f

113 induced fluorescence fluctuation of graphene quantum dots (GQDs) and palladium nanoparticles (Pd NPs)

114 Graphene quantum dots (GQDs) are an allotrope of carbon with a pl

115 Graphene quantum dots (GQDs) are carbon-based, nanoscale particle

116 Here we show that graphene quantum dots (GQDs) can assemble into complex structures

117 r, the insertion of nanometer-scale graphene quantum dots (GQDs) is demonstrated as whole units into

118 Graphene quantum dots (GQDs), a novel type of zero-dimensional fl

119 tum dots (CQDs) and nanosheets like graphene quantum dots (GQDs), are an emerging class of quantum do

120 )O(2)/Cl(-) due to the formation of graphene quantum dots (GQDs).

121 Self-assembled quantum dots grown by molecular beam epitaxy have been a

122 spins, demonstrated in III-V semiconducting quantum dots, has fueled research aimed at realizing qua

123 Chemically made colloidal semiconductor quantum dots have long been proposed as scalable and col

124 Among them, InAs/GaAs quantum dots have shown great potential for applications

125 Unlike quantum dots, however, semiconducting transport has not

126 Nanostructured quantum well and quantum dot III-V solar cells provide a pathway to imple

127 gle-electron source that comprises a dynamic quantum dot in an effective time-resolved fashion with p

128 hability by deterministically embedding GaAs quantum dots in broadband photonic nanostructures that e

129 Also, charge sensing between quantum dots in closely spaced wires is observed, which

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

131 faster than that of negative trion for II-VI quantum dots in literature, our experiments find the two

132 that led to the integration of semiconductor quantum dots in thermally activated delayed photolumines

133 linear array of nine series-coupled silicon quantum dots in ~50 ns via a series of pairwise interdot

134 of a functionalized nitrogen doped graphene quantum dots iniferter.

135 We grow graphene quantum dots inside the matrix of hexagonal boron nitrid

136 Spin qubit in semiconductor quantum dots is a promising candidate for quantum inform

137 While hole injection into neutral quantum dots is generally considered to be inefficient,

138 , where detection sensitivity down to single Quantum Dots is obtained by combining the novel design w

139 ns with a performance comparable to Cd-based quantum dots is presented.

140 etry on a single gate electrode defining the quantum dot itself(15-19), significantly reducing the ga

141 y employed single particle tracking (SPT) of quantum dot labeled FLAG-tagged MORs to examine shifts i

142 uorescence intensities of individual compact quantum dots labeled with epidermal growth factor (EGF)

143 rk, we report observations of a 1D search by quantum dot-labeled EcoRI.

144 Confocal microscopy of quantum dot-labeled plasmid uptake in vivo reveals assoc

145 quency comb formation in quantum-cascade and quantum-dot lasers.

146 a stretchable organometal-halide-perovskite quantum-dot LED with both high efficiency and mechanical

147 Electroluminescent quantum dot light-emitting diodes are promising candidat

148 tu/operando spectroscopy on state-of-the-art quantum-dot light-emitting diodes demonstrates that exci

149 rapid spin relaxation observed in colloidal quantum dots limits their functionality.

150 Commercially available cadmium-sulfur quantum dots ("lumidots") show similar singlet oxygen qu

151 tunnel barriers as contacts to the graphene quantum dots make our transistors reproducible and not d

152 alization and high tumour selectivity of the quantum dots make them broadly suitable for tumour-speci

153 morphic devices and architectures enabled by quantum dots, metal nanoparticles, polymers, nanotubes,

154 a wide range of substrates based on carbon, quantum dots, metal oxide surfaces, and semiconductors.

155 We study this unexplored field by using quantum dot microlasers as optical oscillators.

156 g dynamics of an electrically driven bimodal quantum-dot micropillar laser when subject to delayed co

157 orescent nitrogen and sulfur co-doped carbon quantum dots (N,S-CQDs) using citric acid and thiosemica

158 s (NPs), CuO NPs, silica NPs, polymeric NPs, quantum dots, nanoscale metal-organic frameworks, etc, i

159 n aflatoxin B1 aptamer immobilized on Carbon quantum dots/octahedral Cu(2)O nanocomposite.

160 By tracking quantum dots of different dimensions for extended period

161 ed us to tag rock phosphate with fluorescing quantum dots of three different colours.

162 Contrary to previous works based on quantum dots or nitrogen-vacancy centers in diamond, our

163 on-entangled photons from a single InAs/GaAs quantum dot over a metropolitan network fiber.

164 s rise to emergent properties in lattices of quantum dots, p-block clusters, and fullerenes.

165 However, previously reported quantum dot patterning technologies have limitations in

166 lize core/shell lead sulfide/cadmium sulfide quantum dots (PbS/CdS QDs) emitting at ~1600 nm.

167 The optically pumped InAs/GaAs quantum-dot PC lasers exhibit single-mode operation with

168 Metal halide perovskite quantum dots (Pe-QDs) are of great interest in new-gener

169 lent optical properties (e.g., semiconductor quantum dots, perovskite nanocrystals, and rare earth do

170 sely controlled triplet energy levels of the quantum dot photocatalysts facilitate efficient and sele

171 cence quantum yields, lead halide perovskite quantum dots (PQDs) are regarded as a promising candidat

172 individual colloidal lead halide perovskite quantum dots (PQDs) display highly efficient single-phot

173 l growth of colloidal lead halide perovskite quantum dots (PQDs) has generated tremendous interest in

174 Lead-halide perovskite quantum dots (PQDs) or more broadly, nanocrystals posses

175 Electron spins in silicon quantum dots provide a promising route towards realizing

176 nce resonance energy transfer (FRET) between quantum dot (QD) as a donor and graphene oxide (GO) as a

177 noise can be detrimental to the operation of quantum dot (QD) based semiconductor qubits.

178 Quantum dot (QD) coupling in nanophotonics has been wide

179 ctronic excitonic dynamics in an ensemble of quantum dot (QD) dimers are presented.

180 Quantum dot (QD) fluorescence emission in a low backgrou

181 Here, a bright and photostable terbium-to-quantum dot (QD) Forster resonance energy transfer (FRET

182 metal-organic framework (MOF) and perovskite quantum dot (QD) hybrid single crystal ZJU-28 MAPbBr(3)

183 Precise patterning of quantum dot (QD) layers is an important prerequisite for

184 nable surface ligand properties of colloidal quantum dot (QD) perovskites now enable unprecedented de

185 Article describes the design of a colloidal quantum dot (QD) photosensitizer for the Pd-photocatalyz

186 Quantum dot (QD) photovoltaic devices are attractive for

187 The effect of inhomogeneous quantum dot (QD) size distribution on the electronic tra

188 s (MSCs) can be isolated as intermediates in quantum dot (QD) synthesis, and they provide pivotal clu

189 fy the initial reaction intermediates of CdS quantum dot (QD):MoFe protein nitrogenase complexes unde

190 aptamers were used to capture bacteria, and quantum dots (QD) bound to a second aptamer were utilize

191 ndirect fluorescent immunolabeling utilizing quantum dots (Qd) resulted in reproducible detection of

192 , we demonstrate the excitation by X-rays of quantum-dots (QD) emitting in the near-infrared (NIR), u

193 re, we use the unique spectral properties of quantum dots (Qdots) to optimize and dually quantify VEG

194 s and ethanol medium based on the ZnS:Mn(2+) quantum dot (QDs) and soluble N-methylpolypyrrole (NMPPy

195 rspective describes some ways that colloidal quantum dots (QDs) address the limitations of molecular

196 plasmon resonance (LSPR) between fluorescent quantum dots (QDs) and adjacent gold nanoparticles (AuNP

197 /functionalized tungsten disulfide (WS(2)-B) quantum dots (QDs) and its application for ferritin immu

198 Semiconducting quantum dots (QDs) and magnetic nanoparticles (MNPs) are

199 Semiconductor quantum dots (QDs) are a now well-established example of

200 The optical and electronic performance of quantum dots (QDs) are affected by their size distributi

201 Light-activated quantum dots (QDs) are alternative antimicrobials, with

202 mission wavelengths, colloidal semiconductor quantum dots (QDs) are attractive materials for attainin

203 Colloidal semiconductor quantum dots (QDs) are attractive materials for realizin

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

205 Colloidal quantum dots (QDs) are nanoscale semiconductor crystals

206 tor arrays based on all-inorganic perovskite quantum dots (QDs) are reported.

207 r system using CdSe/ZnS core/shell structure quantum dots (QDs) as donors and anthraquinone (AQ) mole

208 c perovskite cesium lead bromide (CsPbBr(3)) quantum dots (QDs) as highly efficient wavelength shifte

209 unication describes the use of CuInS(2) /ZnS quantum dots (QDs) as photocatalysts for the reductive d

210 port the growth of self-assembled Bi(2)Se(3) quantum dots (QDs) by molecular beam epitaxy on GaAs sub

211 ation of TiO(2) IOPCs was fulfilled with CdS quantum dots (QDs) by SILAR method to form ITO-TiO(2) IO

212 Semiconductor quantum dots (QDs) have attracted tremendous attention i

213 Indium phosphide quantum dots (QDs) have emerged as a new class of fluore

214 Novel materials such as quantum dots (QDs) have extraordinary light absorption p

215 Cesium lead halide perovskite quantum dots (QDs) have gained significant attention as

216 Epitaxial quantum dots (QDs) have long been identified as promisin

217 Colloidal quantum dots (QDs) have shown promise over the last few

218 Semiconductor quantum dots (QDs) have two-photon absorption cross-sect

219 hemist, made-to-measure inorganic perovskite quantum dots (QDs) in flow are autonomously synthesized,

220 ntial application of cadmium selenide (CdSe) quantum dots (QDs) in improving the microelectronic char

221 ocalization of excitons within semiconductor quantum dots (QDs) into states at the interface of the i

222 ion of the optical properties of fluorescent quantum dots (QDs) is critical for their photochemical,

223 lity, and rich spin physics of semiconductor quantum dots (QDs) make them promising candidates for qu

224 the surface of dual-emission amino-modified quantum dots (QDs) nanohybrid via a Michael's type adduc

225 L6 interacts with quantum dots (QDs) noncovalently to generate stable L6/Q

226 le-crystal X-ray crystallography, shows that quantum dots (QDs) of [Na(4) Cs(6) PbBr(4) ](8+) (not of

227 Quantum dots (QDs) of lead chalcogenides (e.g. PbS, PbSe

228 Quantum dots (QDs) present favorable photophysical prope

229 Driven by tensile strain, GaAs quantum dots (QDs) self-assemble on In(0.52)Al(0.48)As(1

230 Among these materials, colloidal InAs quantum dots (QDs) stand out as an infrared-active candi

231 Instability of perovskite quantum dots (QDs) toward humidity remains one of the ma

232 erference effects in metal halide perovskite quantum dots (QDs) using the mechanically controllable b

233 The beta-cyclodextrin (beta-CD) capped ZnO quantum dots (QDs) were decorated with the vitamin B(6)

234 Finally, quantum dots (QDs) were packaged with PKM2-null T cell E

235 extraction of the dark triplet excitons into quantum dots (QDs) where they can recombine radiatively,

236 Ultrabright PbS/CdS core/shell quantum dots (QDs) with dense polymer coating are used t

237 Here, we design and synthesize semiconductor quantum dots (QDs) with SWIR emission based on Hg(x)Cd(1

238 ethyl rhodamine-dextran (TMR-D) and CdSe/ZnS quantum dots (QDs), are loaded in the inner and outer aq

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

240 a of many brightly luminescent semiconductor quantum dots (QDs), where both the assemblies and their

241 Here we show that seven different core-shell quantum dots (QDs), with excitations ranging from ultrav

242 ronic coherences in the model system of CdSe quantum dots (QDs).

243 nalytical method was assessed in the case of quantum dots (QDs).

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

245 Quantum dots (QDs; 1 to 10 nm) were recently synthesized

246 et (UV) stability (using CdSe/ZnS core shell quantum dots [QDs]) in ambient with 45% relative humidit

247 nstitute a strategy to coherently encode the quantum dot quantum state onto a mechanical degree of fr

248 Silicon-based quantum dot qubits are also amenable to large-scale fabr

249 e low-field operation of metal-oxide-silicon quantum dot qubits by combining coherent single-spin con

250 nation of such ratios in CdSe/ZnS core-shell quantum dot:rat monoclonal IgG2a antibody (QD:Ab) conjug

251 minescent sulfur and nitrogen doped graphene quantum dots (S,N-GQDs) were prepared via simple hydroth

252 We resonantly drive the quantum dot's exciton using a laser modulated at the mec

253 The prototypical example is a semiconductor quantum dot separated from a gated contact by a tunnel b

254 l separation, while TF-labeled semiconductor quantum dots serve as bright fluorescent indicators of t

255 Here we show that colloidal quantum dots serve as visible-light chromophores, photoc

256 ive fluorescent probe (sulfur doped graphene quantum dots, SGQDs) was designed for real-time detectio

257 The integrated films composed of NWs and quantum dots showed good fluorescence polarization.

258 reas at low temperature, the pGNRs behave as quantum dots showing single-electron tunneling and Coulo

259 rinted polymer (MIP) coated on silica-carbon quantum dots (SiCQDs).

260 itutes an important step towards large-scale quantum dot simulators of correlated electron systems.

261 oelectronic property variations in colloidal quantum dot solar cells due to film defects, physical da

262 he optical nonlinear properties of InAs/GaAs quantum dots, specifically the associated two-photon abs

263 A fundamental challenge for quantum dot spin qubits is to extend the strength and ra

264 lding blocks of a dedicated local memory per quantum-dot spin qubit and promise a solid-state platfor

265 t states, but it has not been implemented in quantum-dot spin qubits.

266 , individual electron spins in semiconductor quantum dots stand out for their long coherence times an

267 serve hybrid excitons, composed of localized quantum dot states and delocalized continuum states, ari

268 e excitation dipole orientation of CdSSe/ZnS quantum dots suspended in vitreous ice.

269 pins with the flexibility and scalability of quantum dot systems.

270 combine fluorescent Cd-free Ag-In-S ternary quantum dots (t-QDs) with fluorescence lifetimes (LTs) o

271 In this study, titania-ceria-graphene quantum dot (TC-GQD) nanocomposite was synthesized by hy

272 ctrons between a pair of two-electron double quantum dots that can be operated and measured simultane

273 ectrons in silicon metal-oxide-semiconductor quantum dots the hyperfine interaction is sufficient to

274 Similar to quantum-confined, semiconducting quantum dots, the electrical coupling in films is depend

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

276 pic nuclear spin ensemble of a semiconductor quantum dot to the nuclear sideband-resolved regime.

277 Lanthanides are routinely incorporated into quantum dots to act as down-shifting and up-converting p

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

279 We developed a quantum-dot-tracking technique to quantify phosphorus-tr

280 the intermediate negatively charged state of quantum dots triggers confinement-enhanced Coulomb inter

281 Conversely, in lithographically defined quantum dots, tunable interdot electron tunnelling allow

282 ATMS are quite distinct from the platelet or quantum-dot versions of the same metal sulfides.

283 phorene nanobelts, as well as nanosheets and quantum dots, via an oxygen-driven mechanism.

284 g magnetically doped colloidal semiconductor quantum dots we can achieve extremely fast rates of spin

285 ate that by using heavy-metal-free CuInSe(2) quantum dots, we can address the problem of toxicity and

286 on the electron spin states of gate-defined quantum dots, we demonstrate Bell state tomography with

287 zing the same spin-coated layer of CuInSe(2) quantum dots, we realize both p- and n-channel transisto

288 Herein, nitrogen doped graphene quantum dots were prepared utilizing the degree of dehyd

289 e the photogenerated carrier dynamics in the quantum dot-wetting layer-GaAs system.

290 athway for multi-carrier states of colloidal quantum dots, which affects performance of most of their

291 conducting polymers based nanoparticles and quantum dots, which provide countless opportunities in t

292 The functionalized quantum dots, which structurally mimic large amino acids

293 usions, and pores), multidimensional design (quantum dots/wires, nanoparticles, nanowires, nano- or m

294 We do this by placing a large quantum dot with 50-100 electrons between a pair of two-

295 Specific binding of graphene quantum dot with Campylobacter jejuni membrane leads to

296 oly clonal antibody conjugated with graphene quantum dot with surface protein in Campylobacter jejuni

297 retical findings shed new light on designing quantum dots with necessary Auger recombination characte

298 uantum dots (GQDs), are an emerging class of quantum dots with unique properties owing to their quant

299 ent sources such as single-dye molecules and quantum dots, without bleaching or blinking.

300 The functionalized quantum dots (WS(2)-B QDs) were further explored for the

301 Experiments on neutral self-assembled quantum dots yield up to a five-fold increase in coheren