Unraveling the Impurity Location and Binding in Heavily Doped Semiconductor Nanocrystals: The Case of Cu in InAs Nanocrystals

Amit, Yorai; Eshet, Hagai; Faust, Adam; Patllola, Anitha; Rabani, Eran; Banin, Uri; Frenkel, Anatoly I.

doi:10.1021/jp4032749

Cited by 38 publications

(79 citation statements)

References 54 publications

(69 reference statements)

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“…38 Indeed, p-type behavior was observed by us for Ag in InAs, 31 consistent with substitutional doping. Additional support for this model is gained from the Ag K-edge EXAFS data behavior (Figure 6aÀc), dominated by the AgÀAs contribution, as also evidenced by the quantitative data analysis.…”

Section: Articlementioning

confidence: 76%

“…In a following work, we have reported on the detailed characterization of Cu doping of InAs NCs, using advanced X-ray absorption fine structure (XAFS) spectroscopy to establish the location of the impurity and its electronic state within the NC as a function of the impurity to NC ratio in the reaction solution. 38 We found that the diffusion of Cu impurities into the NC lattice is favored and results in an energetically stable system. Furthermore, we identified the impurity site, determining that the Cu impurities occupy only hexagonal-interstitial sites throughout the lattice for a very wide range of impurity concentrations.…”

mentioning

confidence: 79%

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From Impurity Doping to Metallic Growth in Diffusion Doping: Properties and Structure of Silver-Doped InAs Nanocrystals

Amit¹,

Frenkel

Banin³

2015

ACS Nano

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Tuning of the electronic properties of pre-synthesized colloidal semiconductor nanocrystals (NCs) by doping plays a key role in the prospect of implementing them in printed electronics devices such as transistors, and photodetectors. While such impurity doping reactions have already been introduced, the understanding of the doping process, the nature of interaction between the impurity and host atoms, and the conditions affecting the solubility limit of impurities in nanocrystals are still unclear. Here, we used a post-synthesis diffusion based doping reaction to introduce Ag impurities into InAs NCs. Optical absorption spectroscopy along with analytical inductively coupled plasma mass-spectroscopy (ICP-MS) were used to present a two stage doping model consisting of a "doping region" and a "growth region", depending on the concentration of the impurities in the reaction vessel. X-ray absorption fine-structure (XAFS) spectroscopy was employed to determine the impurity location and correlate between the structural and electronic properties for different sizes of InAs NCs and dopant concentrations.The resulting structural model describes a heterogeneous system where the impurities initially dope the NC, by substituting for In atoms near the surface of the NC, until the "solubility limit" is reached, after which the rapid growth and formation of metallic structures are identified.

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Section: Articlementioning

confidence: 76%

mentioning

confidence: 79%

From Impurity Doping to Metallic Growth in Diffusion Doping: Properties and Structure of Silver-Doped InAs Nanocrystals

Amit¹,

Frenkel

Banin³

2015

ACS Nano

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“…Breifely, the QDs were reacted with calculated volumes of a solution containing the appropriate surface ligands and the 8 plasma (ICP) measurements were used to correlate between the above solution values and the number of Cu atoms within the QD ( Figure S1 in the SIO). 2,11 Close investigation reveals a slight red-shift of the first exciton (~5meV) for Cu doping levels up to 125 Cu atoms/QD; this is related to the initial appearance of doped states situated slightly below the QD conduction band.…”

Section: Cu Doping Of Inas Quantum Dotsmentioning

confidence: 96%

Impurity Sub-Band in Heavily Cu-Doped InAs Nanocrystal Quantum Dots Detected by Ultrafast Transient Absorption

et al. 2016

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The effect of Cu impurities on the absorption cross section, the rate of hot exction thermalization, and on exciton recombination processes in InAs quantum dots was studied by femtosecond transient absorption. Our findings reveal dynamic spectral effects of an emergent impurity sub-band near the bottom of the conduction band. Previously hypothesized to explain static photophysical properties of this system, its presence is shown to shorten hot carrier relaxation. Partial redistribution of interband oscillator strength to sub-band levels reduces the band edge bleach per exciton progressively with the degree of doping, even though the total linear absorption cross section at the band edge remains unchanged. In contrast, no doping effects were detected on absorption cross sections high in the conduction band, as expected due to the relatively high density of sates of the undoped QDs.

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“…The interstitial location of Cu + impurities was later verified by X-ray absorption fine structure (XAFS) spectroscopy measurements and DFT calculations. 85 In contrast, Au 3+ acts as an isovalent substitution for In 3+ , perturbing the bandedge structure, but not appreciably doping the particles. While isovalent doping does not effect equilibrium carrier concentrations, the midgap states that it induces can sometimes be utilized as a charge transfer rely or optically active site, as in the case of Mn 2+ in CdS.…”

Section: Chemistry Of Materialsmentioning

confidence: 99%

Postsynthetic Doping Control of Nanocrystal Thin Films: Balancing Space Charge to Improve Photovoltaic Efficiency

Engel

Alivisatos

2013

Chem. Mater.

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A semiconductor nanocrystal film is a unique class of nanocomposite, whose collective properties are determined by those of its constituents. Colloidal synthetic methods offer precise size control and finely tuned optical properties via quantum confinement, while recent improvements in charge transport through films have led to a variety of optoelectronic applications. However, understanding the role of defects and impurities in doping, crucial for optimizing device performance, has remained more elusive. In this perspective, we review recent progress in understanding and controlling the doping of semiconductor nanocrystal thin films, with a special focus on its relevance to photovoltaic applications. We highlight an array of postsynthetic techniques based on stoichiometric control, metal impurity incorporation, and electrochemical charging. We conclude with a review of the state of the art for nanocrystal photovoltaics, and propose the use of controlled doping and charge balance as a pathway to higher device efficiencies.

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Unraveling the Impurity Location and Binding in Heavily Doped Semiconductor Nanocrystals: The Case of Cu in InAs Nanocrystals

Cited by 38 publications

References 54 publications

From Impurity Doping to Metallic Growth in Diffusion Doping: Properties and Structure of Silver-Doped InAs Nanocrystals

From Impurity Doping to Metallic Growth in Diffusion Doping: Properties and Structure of Silver-Doped InAs Nanocrystals

Impurity Sub-Band in Heavily Cu-Doped InAs Nanocrystal Quantum Dots Detected by Ultrafast Transient Absorption

Postsynthetic Doping Control of Nanocrystal Thin Films: Balancing Space Charge to Improve Photovoltaic Efficiency

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