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Abstract

Topological materials have attracted much attention due to their novel physical properties. These materials can not only serve as a platform for studying the fundamental physics, but also demonstrate a significant potential application in electronics, and they are studied usually in two ways. One is to constantly explore new experimental phenomena and physical problems in existing topological materials, and the other is to predict and discover new topological material systems and carry out synthesis for further studies. In a word, high-quality crystals are very important for studying quantum oscillations, angle resolved photoemission spectra or scanning tunneling microscopy. In this work, the classifications and developments of topological materials, including topological insulators, topological semimetals, and magnetic topological materials, are introduced. As usually employed growth methods in growing topological materials, flux and vapour transport methods are introduced in detail. Other growth methods, such as Bridgman, float-zone, vapour deposition and molecular beam epitaxy methods, are also briefly mentioned. Then the details about the crystal growth of some typical topological materials, including topological insulators/semimetals, high Chern number chiral topological semimetals and magnetic topological materials, are elaborated. Meanwhile, the identification of crystal quality is also briefly introduced, including the analysis of crystal composition and structure, which are greatly important.

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Authors and contacts

Corresponding author:Xia Tian-Long,tlxia@ruc.edu.cn

Funds:Project supported by the National Key R&D Program of China (Grant No. 2019YFA0308602), the National Natural Science Foundation of China (Grant Nos. 12074425, 11874422), the Fundamental Research Fund for the Central Universities, China (Grant Nos. 18XNLG14, 19XNLG18), and the Outstanding Innovative Talents Cultivation Funded Programs 2020 of Renmin University of China

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Cited By

DownLoad: Full-Size Img PowerPoint

	熔点/℃	沸点/℃	可溶于酸或碱溶液	密度/(g·cm^-3)	毒性
Al	660.3	2327	硫酸/硝酸/盐酸/氢氧化钠/氢氧化钾	2.70	无
Ga	29.8	2400	盐酸/硫酸	5.90	无
In	156.6	2000	硝酸/盐酸/硫酸	7.31	无
Sn	231.9	2270	盐酸/硝酸/碱溶液	7.28	无
Pb	327.5	1740	硫酸/硝酸/有机酸溶液/碱溶液	11.34	有
Sb	630.6	1635	硫酸	6.69	无
Bi	271.3	1500	硝酸	9.78	无
Te	449.5	989.8	硝酸/盐酸/氢氧化钾	6.24	无
Cd	321.2	765	盐酸	8.65	有

DownLoad: CSV

	熔点/℃	沸点/℃	稳定性	可溶于溶液	形貌	储存
I₂	113	184	易挥发/易升华	乙醇	紫红色颗粒	密封干燥
TeCl₄	224	380	易潮解	水/盐酸	白色粉末	密封干燥
BiCl₃	230	447	易潮解	水/盐酸	白色粉末	密封干燥
BiBr₃	218	441	易潮解	水/稀盐酸/丙酮	黄色粉末	密封干燥
TeBr₄	380	420	易潮解	水/氢氧化钠	黄色粉末	避光/密封
SnI₄	144.5	364	/	乙醇	橘黄色粉末	密封干燥
TeI₄	280	118 (升华点)	灼热易分解	乙醇/丙酮	灰色粉末	密封干燥

DownLoad: CSV

	优点	缺点	适用范围
熔融重结晶法	1. 不需要加入其他试剂如助溶剂或输运剂, 损耗少且不引入杂质; 2. 不需要额外处理其他溶剂的分离或回收, 操作简单.	适用性不强	适合生长具有低熔点的目标材料
助溶剂法	1. 适用性强, 几乎对于所有材料只要找到合适的助溶剂都可以将其以单晶形式生长出来; 2. 生长温度低, 适合熔点很高的化合物; 3. 生长出的晶体均匀完整.	1. 生长周期长; 2. 许多助溶剂都有不同程度的毒性处理后的助溶剂或含有助溶剂的溶液具有腐蚀性还会产生污染, 要做好分类并小心处理; 3. 使用坩埚, 可能会影响品体成核与生长取向.	适合生长本身熔点较高的化合物
气相输运法	1. 可以实现常压下难以合成的化合物; 2. 可以合成难以通过固-固, 固-液反应合成的化合物; 3. 温度调节灵活, 可以直接调控晶体生长时所需的应力, 饱和度等参量, 进而影响晶体的生长速度.	1. 产量较低; 2. 需要精准掌控输运剂的浓度和低沸点反应物的总量, 否则容易因为管内压强过大造成爆管; 3. 有些气相输运法需要通惰性气体或氢气, 操作复杂, 有一定的危险; 4. 管壁会限制晶体生长方向, 与管壁接触的晶面呈曲面.	适合生长反应物中沸点较低的化合物或其它难以通过固-固、固-液合成的化合物

DownLoad: CSV

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Vol. 72, Issue 3 - 2023-02-05

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