Shiwei Xue, Huiling Ding, Zhenghao Xia, Hengbin Mao, Sibo Zhao, Hailong Wang, Bingbing Fan, Gang Shao, Hongliang Xu, Hongxia Lu
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引用次数: 0
摘要
发光二极管(LED)是新一代显示器的关键。新型半导体电子-空穴重组层是实现高性能 LED 的关键。全无机量子点(QD)材料虽然具有色域宽、发射峰窄等优点,但面临重金属离子毒性、QD稳定性等问题,合成方法污染大,难以实现工业化生产。因此,需要探索具有窄 FWHM 的无铅全无机荧光粉。需要研究一种新的合成方法。全无机溴化锰(Cs3MnBr5)易于合成,毒性低,发光性能优越。然而,大多数合成方法都依赖于液相反应体系,无法实现高效合成。高能球磨法是一种高效的方法,在工业生产中具有巨大的潜力。本文利用这种方法合成了 Cs3MnBr5,并对 Cs/Mn 比例、球磨时间和配体用量进行了研究。此外,还发现了全无机 Mn2+ 溴化物的一种新相变,并结合相变过程解释了高能球磨的机理。本文为无机溴化锰的合成提供了一种新方法,解释了球磨机理,拓展了无机溴化锰的相变过程。
High-Energy Ball Milling Synthesize All-Inorganic Lead-Free Green Emitting Cs3MnBr5 Crystals
Light Emitting Diodes (LEDs) are the key to new generation displays. New semiconductor electron–hole recombination layer is the key to high-performance LEDs. Although all-inorganic quantum dot (QD) materials have the advantages of wide color gamut and narrow emission peaks, they face issues of toxicity of heavy metal ions and stability of QDs, the synthesis method is highly polluting and difficult to achieve industrial production. Thereby, lead-free all-inorganic phosphor with narrow FWHM needs to be explored. A new synthesis method is required to be investigated. All-inorganic Mn2+ bromide (Cs3MnBr5) is easy to synthesize and has low toxicity and superior luminescent properties. However, most synthesis methods rely on liquid-phase reaction systems and cannot achieve highly efficient synthesis. High-energy ball milling is an efficient method and has enormous potential for industrial production. In this paper, this method is used to synthesize Cs3MnBr5, and then Cs/Mn ratio, ball milling time, and ligand usage are studied. Furthermore, a new phase transformation of all-inorganic Mn2+ bromide is discovered, and the mechanism of high-energy ball milling is interpreted combining with phase transformation process. This article brings a new method to synthesis of all-inorganic Mn2+ bromide, explains the mechanism of ball milling, and expands the phase transformation of all-inorganic Mn2+ bromide.
期刊介绍:
Particle & Particle Systems Characterization is an international, peer-reviewed, interdisciplinary journal focusing on all aspects of particle research. The journal joined the Advanced Materials family of journals in 2013. Particle has an impact factor of 4.194 (2018 Journal Impact Factor, Journal Citation Reports (Clarivate Analytics, 2019)).
Topics covered include the synthesis, characterization, and application of particles in a variety of systems and devices.
Particle covers nanotubes, fullerenes, micelles and alloy clusters, organic and inorganic materials, polymers, quantum dots, 2D materials, proteins, and other molecular biological systems.
Particle Systems include those in biomedicine, catalysis, energy-storage materials, environmental science, micro/nano-electromechanical systems, micro/nano-fluidics, molecular electronics, photonics, sensing, and others.
Characterization methods include microscopy, spectroscopy, electrochemical, diffraction, magnetic, and scattering techniques.
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