Metal ion dopant-induced famatinite to chalcostibite phase transformation of copper antimony sulphide colloidal nanostructures: effect on photophysical and pseudocapacitance properties.

IF 3.3 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Dalton Transactions Pub Date : 2025-10-21 DOI:10.1039/d5dt01602a

Kimberly Weston,Richard A Taylor,Kim Kisslinger,Shobha Mantripragada

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引用次数: 0

Abstract

The strategic doping of transition metal ions into copper antimony sulphide (CAS) semiconducting nanostructures can significantly influence their photophysical and pseudocapacitive properties, for which there are few reports and therefore is the focus of this study. Accordingly, highly crystalline metal ion (Mn2+, Fe2+, Co2+, Ni2+ and Zn2+) doped off-stoichiometric copper rich/poor, antimony-rich/poor, and sulphur-poor CAS nanostructures (10-23 nm) were grown via colloidal (hot-injection) synthesis using metal diethyldithiocarbamate precursors. Importantly, metal ion doping significantly influences the structure and composition of the off-stoichiometric CAS nanostructures. Data from powder X-ray diffraction, Raman spectroscopy, high-resolution scanning/transmission electron microscopy, and energy dispersive X-ray spectroscopy confirm that the heavier metal ion dopants induce a novel phase transformation from famatinite (fCAS) to chalcostibite (cCAS) nanostructures. The influence of the metal ion dopants is also observed in the optical properties of as-synthesized nanostructures. This involves blue-shifted ultraviolet-visible absorption, reduced Urbach tailing, and tunable bandgaps between 2.17 and 2.38 eV. Also, the doped nanostructures display broad visible-near infrared photoluminescence via a triple radiative pathway with relatively short decay lifetimes between 0.2 and 6.1 ns. This is mediated by electronic transitions involving intrinsic (copper/antimony/sulphur interstitial) and extrinsic (metal ion interstitial) defect states. Additionally, electrodes prepared from Mn2+-doped fCAS nanostructures show enhanced pseudocapacitance via Na+ surface adsorption and intercalation relative to undoped fCAS electrodes, while Zn2+-doped cCAS electrodes exhibit pseudocapacitance via a combination of Na+ surface adsorption, intercalation, and redox reactions. These electrodes exhibit reduced charge transfer resistance, improved electronic conductivity and notably enhanced specific capacitance (∼222 F g-1), and charge transport, as measured in 1 M Na2SO4 electrolyte via cyclic voltammetry and electrochemical impedance spectroscopy. To this end, the discovery of the metal ion-induced phase transformation presents a new avenue for optimizing the functional properties of fCAS and cCAS nanostructures, highlighting the critical role of metal ion-related defects in controlling the optical and electrochemical properties, towards potential solar absorption and energy storage applications.

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金属离子掺杂诱导的硫化铜锑胶体纳米结构的黄铁矿到辉铜矿相变：对光物理和赝电容性能的影响。

过渡金属离子在硫化铜锑（CAS）半导体纳米结构中的战略性掺杂会显著影响其光物理和赝电容性能，这方面的报道很少，因此是本研究的重点。以金属二乙基二硫代氨基甲酸酯为前驱体，通过胶体（热注射）法制备了高结晶金属离子（Mn2+、Fe2+、Co2+、Ni2+和Zn2+）掺杂非化学量富贫铜、富贫锑和贫硫CAS纳米结构（10-23 nm）。重要的是，金属离子掺杂显著影响非化学计量CAS纳米结构的结构和组成。来自粉末x射线衍射、拉曼光谱、高分辨率扫描/透射电子显微镜和能量色散x射线光谱的数据证实，较重的金属离子掺杂诱导了从黄铁矿（fCAS）到辉铜矿（cCAS）纳米结构的新型相变。金属离子掺杂剂对合成纳米结构的光学性质也有影响。这包括蓝移的紫外可见吸收，减少乌尔巴赫尾光，以及2.17和2.38 eV之间的可调谐带隙。此外，掺杂纳米结构通过三重辐射途径显示出广泛的可见光-近红外光致发光，衰变寿命相对较短，在0.2 ~ 6.1 ns之间。这是由涉及内在（铜/锑/硫间隙）和外在（金属离子间隙）缺陷态的电子跃迁介导的。此外，相对于未掺杂的fCAS电极，掺杂Mn2+的fCAS纳米结构通过Na+表面吸附和插层表现出增强的伪电容，而掺杂Zn2+的cCAS电极通过Na+表面吸附、插层和氧化还原反应的组合表现出伪电容。通过循环伏安法和电化学阻抗谱在1 M Na2SO4电解质中测量，这些电极表现出降低的电荷转移电阻，改善的电子导电性，显著增强的比电容（~ 222 F -1）和电荷输运。为此，金属离子诱导相变的发现为优化fCAS和cCAS纳米结构的功能特性提供了新的途径，突出了金属离子相关缺陷在控制光学和电化学性能方面的关键作用，以及潜在的太阳能吸收和储能应用。

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来源期刊

Dalton Transactions 化学-无机化学与核化学

CiteScore

6.60

自引率

7.50%

发文量

1832

审稿时长

1.5 months

期刊介绍： Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.