Tuning Electronic Properties of II–VI and III–V Narrow Band Gap Nanocrystals through Exposure to Alkali

IF 7 2区材料科学 Q2 CHEMISTRY, PHYSICAL

Chemistry of Materials Pub Date : 2024-11-26 DOI:10.1021/acs.chemmater.4c02795

Dario Mastrippolito, Mariarosa Cavallo, Houman Bahmani Jalali, Guncem Ozgun Eren, Erwan Bossavit, Huichen Zhang, Tommaso Gemo, Albin Colle, Adrien Khalili, Clément Gureghian, Yoann Prado, Mathieu G. Silly, Debora Pierucci, Francesco Di Stasio, Emmanuel Lhuillier

{"title":"Tuning Electronic Properties of II–VI and III–V Narrow Band Gap Nanocrystals through Exposure to Alkali","authors":"Dario Mastrippolito, Mariarosa Cavallo, Houman Bahmani Jalali, Guncem Ozgun Eren, Erwan Bossavit, Huichen Zhang, Tommaso Gemo, Albin Colle, Adrien Khalili, Clément Gureghian, Yoann Prado, Mathieu G. Silly, Debora Pierucci, Francesco Di Stasio, Emmanuel Lhuillier","doi":"10.1021/acs.chemmater.4c02795","DOIUrl":null,"url":null,"abstract":"The use of nanocrystals in optoelectronics strongly relies on the ability to design photodiodes, which requires advanced knowledge of their electronic structure and offers even greater potential when that structure can be finely tuned. For traditional semiconductors, this degree of freedom is achieved through doping, obtained mostly via the introduction of extrinsic impurities. When it comes to colloidal quantum dots, this capacity is mostly lost and carrier density control is best obtained thanks to surface ligand exchanges. Tuning the capping molecule enables the generation of a surface dipole and a consequent charge transfer, which shifts the relative position of the bands with respect to the Fermi and vacuum level. However, the most efficient ligands (<i>i.e</i>., the one associated with the largest dipole) are not necessarily compatible with charge conduction, which rather prefers short molecules; therefore, new strategies are needed. Here, we explore how such a surface dipole can be obtained through alkali deposition as an alternative approach. We apply this method to a broad range of nanocrystals relevant to infrared optoelectronics, which are HgTe (with two different sizes) and InAs, including a ZnSe shell. Potassium deposition leads to a significant shift of the material work function that can be as large as 1.3 eV. We also bring clear evidence that this dipole arises from the polarization of the adatoms with no charge transfer involved (<i>i.e</i>., no shift in the core levels is measured). This method appears to be quite general and is very promising as a path to shift the absolute energy of a band gap, which may ease future integration of colloidal materials in high-performance diodes.","PeriodicalId":33,"journal":{"name":"Chemistry of Materials","volume":"10 1","pages":""},"PeriodicalIF":7.0000,"publicationDate":"2024-11-26","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Chemistry of Materials","FirstCategoryId":"88","ListUrlMain":"https://doi.org/10.1021/acs.chemmater.4c02795","RegionNum":2,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"CHEMISTRY, PHYSICAL","Score":null,"Total":0}

引用次数: 0

Abstract

The use of nanocrystals in optoelectronics strongly relies on the ability to design photodiodes, which requires advanced knowledge of their electronic structure and offers even greater potential when that structure can be finely tuned. For traditional semiconductors, this degree of freedom is achieved through doping, obtained mostly via the introduction of extrinsic impurities. When it comes to colloidal quantum dots, this capacity is mostly lost and carrier density control is best obtained thanks to surface ligand exchanges. Tuning the capping molecule enables the generation of a surface dipole and a consequent charge transfer, which shifts the relative position of the bands with respect to the Fermi and vacuum level. However, the most efficient ligands (i.e., the one associated with the largest dipole) are not necessarily compatible with charge conduction, which rather prefers short molecules; therefore, new strategies are needed. Here, we explore how such a surface dipole can be obtained through alkali deposition as an alternative approach. We apply this method to a broad range of nanocrystals relevant to infrared optoelectronics, which are HgTe (with two different sizes) and InAs, including a ZnSe shell. Potassium deposition leads to a significant shift of the material work function that can be as large as 1.3 eV. We also bring clear evidence that this dipole arises from the polarization of the adatoms with no charge transfer involved (i.e., no shift in the core levels is measured). This method appears to be quite general and is very promising as a path to shift the absolute energy of a band gap, which may ease future integration of colloidal materials in high-performance diodes.

查看原文本刊更多论文

碱对II-VI和III-V窄带隙纳米晶体电子特性的调控

纳米晶体在光电子学中的应用很大程度上依赖于设计光电二极管的能力，这需要对其电子结构有先进的了解，并且当该结构可以精细调整时，它将提供更大的潜力。对于传统的半导体，这种自由度是通过掺杂来实现的，主要是通过引入外部杂质来获得的。当涉及到胶体量子点时，这种容量大部分丢失，并且由于表面配体交换而最好地获得载流子密度控制。调节封盖分子可以产生表面偶极子和随之而来的电荷转移，从而改变带相对于费米能级和真空能级的相对位置。然而，最有效的配体（即与最大偶极子相关的配体）不一定与电荷传导相容，而电荷传导更倾向于短分子；因此，需要新的策略。在这里，我们探索如何通过碱沉积作为一种替代方法获得这样的表面偶极子。我们将这种方法应用于与红外光电子学相关的各种纳米晶体，这些纳米晶体是HgTe（具有两种不同的尺寸）和InAs，包括ZnSe外壳。钾沉积导致材料功函数的显著位移，可达1.3 eV。我们还提供了明确的证据，表明这种偶极子是由没有电荷转移的原子的极化引起的（即，没有测量到核心能级的位移）。这种方法似乎是相当普遍的，并且非常有希望作为一种转移带隙绝对能量的途径，这可能有助于未来在高性能二极管中集成胶体材料。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Chemistry of Materials 工程技术-材料科学：综合

CiteScore

14.10

自引率

5.80%

发文量

929

审稿时长

1.5 months

期刊介绍： The journal Chemistry of Materials focuses on publishing original research at the intersection of materials science and chemistry. The studies published in the journal involve chemistry as a prominent component and explore topics such as the design, synthesis, characterization, processing, understanding, and application of functional or potentially functional materials. The journal covers various areas of interest, including inorganic and organic solid-state chemistry, nanomaterials, biomaterials, thin films and polymers, and composite/hybrid materials. The journal particularly seeks papers that highlight the creation or development of innovative materials with novel optical, electrical, magnetic, catalytic, or mechanical properties. It is essential that manuscripts on these topics have a primary focus on the chemistry of materials and represent a significant advancement compared to prior research. Before external reviews are sought, submitted manuscripts undergo a review process by a minimum of two editors to ensure their appropriateness for the journal and the presence of sufficient evidence of a significant advance that will be of broad interest to the materials chemistry community.