Size and Band-Gap Dependences of the First Hyperpolarizability of CdxZn1-xS Nanocrystals

Petrov, Dmitri; Santos, Beate S.; Pereira, Giovannia A. L.; Donegá, Celso de Mello

doi:10.1021/jp010617i

Cited by 119 publications

(95 citation statements)

References 49 publications

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“…[1][2][3][4][5][6] For devices in nanoelectronics and nanophotonics, it is very important to fabricate materials with continuous tunable physical properties. Recent advances in ternary semiconductor nanocrystals or films have shown that their band gaps and then their optical emissions can be tuned by changing their constituent stoichiometries, [7][8][9][10][11][12] while such study is few for the ternary semiconductors with 1D nanostructures.…”

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confidence: 99%

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.

et al. 2006

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mentioning

confidence: 99%

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.

et al. 2006

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“…The remarkably high sensitivity that we observe in these nanostructures is inherited from the intrinsically large electro-optic tunability of graphene, which offers an extra degree of control to optimize the sensing capability. For comparison, nanographenes present a much higher SHG response than nanoparticles [47] or quantum dots [57,58] of similar size (see SM [56]). As a practical realization, nanographene structures could be passivated with thin insulating layers, which would protect them from undesired chemical interactions (e.g., charge transfer) in the complex environment of the analyte.…”

Section: (B)mentioning

confidence: 99%

Nonlinear plasmonic sensing with nanographene

Cox

Abajo

2017

2017 Conference on Lasers and Electro-Optics Europe &Amp; European Quantum Electronics Conference (CLEO/Europe-EQEC)

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Plasmons provide excellent sensitivity to detect analyte molecules through their strong interaction with the dielectric environment. Plasmonic sensors based on noble metals are, however, limited by the spectral broadening of these excitations. Here we identify a new mechanism that reveals the presence of individual molecules through the radical changes that they produce in the plasmons of graphene nanoislands. An elementary charge or a weak permanent dipole carried by the molecule are shown to be sufficient to trigger observable modifications in the linear absorption spectra and the nonlinear response of the nanoislands. In particular, a strong second-harmonic signal, forbidden by symmetry in the unexposed graphene nanostructure, emerges due to a redistribution of conduction electrons produced by interaction with the molecule. These results pave the way toward ultrasensitive nonlinear detection of dipolar molecules and molecular radicals that is made possible by the extraordinary optoelectronic properties of graphene. DOI: 10.1103/PhysRevLett.117.123904 Localized surface plasmons (LSPs) have attracted considerable attention in the nanophotonics community due to their pivotal role in optical sensing applications such as antibody-antigen [1-3], gas [4,5], and pH [6,7] sensors. These excitations also enable the detection and chemical identification of single molecules through their enhancement of molecule-specific Raman scattering intensities [8][9][10][11][12][13]. LSPs are routinely observed in noble metal nanostructures, appearing as pronounced spectral features in their optical absorption and scattering spectra. Plasmonbased sensing heavily relies on the ability of these collective modes to confine and strongly amplify the optical near field. These properties are equally responsible for the large nonlinear optical response observed in metal nanoparticles [14][15][16][17][18][19], which has inspired alternative mechanisms for nonlinear plasmonic sensing. For instance, the aggregation of gold nanoparticles caused by targeted heavy metal ions [20], Escherichia coli bacteria [21], or Alzheimer's disease biomarkers [22] can be detected through an increase in second-harmonic generation (SHG). Additionally, third-harmonic generation has been recently claimed to offer large sensitivity to the dielectric environment compared to the linear response [23].Doped graphene is widely recognized as a promising material platform for plasmonics, capable of supporting electrically tunable plasmons with higher quality factors and spatial confinement than those of metal nanoparticles [24][25][26][27][28][29][30][31][32][33][34][35][36][37]. Moreover, tunable graphene plasmons, so far observed at midinfrared (IR) and THz frequencies, provide the strong near-electric-field confinement needed for sensing [38][39][40][41]. In particular, graphene plasmons have been demonstrated to reveal vibrational fingerprints of biomolecules [38]. Additionally, the anharmonic electron motion associated with the Dirac cones of this material [42,43]...

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“…Moreover, core/shell hetero-NCs with a gradient alloy heterointerface have been shown to possess unique properties, such as reduced Auger recombination rates and lower threshold for amplified spontaneous emission [84]. Alloy QDs and graded interface core/shell hetero-NCs can also be directly synthesized and have attracted increasing interest in the last few years, leading to the investigation of several II-VI and IV-VI compositions [viz., Cd(Te,Se), Cd(S,Se), Pb(S,Se), (Cd,Zn)Se, (Cd,Zn)S, (Cd,Zn)(S,Se)] [80][81][82][83][84][85][86][87][88][89].…”

Section: Composition Effects: Tailoring the Property Gamutmentioning

confidence: 99%

Excited-State Dynamics in Colloidal Semiconductor Nanocrystals

Rabouw

Donegá

2016

Topics in Current Chemistry Collections

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Colloidal semiconductor nanocrystals have attracted continuous worldwide interest over the last three decades owing to their remarkable and unique sizeand shape-, dependent properties. The colloidal nature of these nanomaterials allows one to take full advantage of nanoscale effects to tailor their optoelectronic and physical-chemical properties, yielding materials that combine size-, shape-, and composition-dependent properties with easy surface manipulation and solution processing. These features have turned the study of colloidal semiconductor nanocrystals into a dynamic and multidisciplinary research field, with fascinating fundamental challenges and dazzling application prospects. This review focuses on the excited-state dynamics in these intriguing nanomaterials, covering a range of different relaxation mechanisms that span over 15 orders of magnitude, from a few femtoseconds to a few seconds after photoexcitation. In addition to reviewing the state of the art and highlighting the essential concepts in the field, we also discuss

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Size and Band-Gap Dependences of the First Hyperpolarizability of Cd_xZn₁_-_xS Nanocrystals

Cited by 119 publications

References 49 publications

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.

Nonlinear plasmonic sensing with nanographene

Excited-State Dynamics in Colloidal Semiconductor Nanocrystals

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Size and Band-Gap Dependences of the First Hyperpolarizability of CdxZn1-xS Nanocrystals

Cited by 119 publications

References 49 publications

Color‐Tunable Photoluminescence of Alloyed CdSxSe1‐x Nanobelts.

Color‐Tunable Photoluminescence of Alloyed CdSxSe1‐x Nanobelts.

Nonlinear plasmonic sensing with nanographene

Excited-State Dynamics in Colloidal Semiconductor Nanocrystals

Contact Info

Product

Resources

About

Size and Band-Gap Dependences of the First Hyperpolarizability of Cd_xZn₁_-_xS Nanocrystals

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.

Color‐Tunable Photoluminescence of Alloyed CdS_xSe_1‐x Nanobelts.