高溫高壓光學浮區(qū)爐
| 德國SciDre公司推出的高溫高壓光學浮區(qū)法單晶爐能夠提供2200–3000℃以上的生長溫度,晶體生長腔壓力可達300bar��,甚至10-5mbar的高真空。適用于生長各種超導材料單晶,介電和磁性材料單晶��,氧化物及金屬間化合物單晶等��。 應用領域
適用于生長各種超導材料單晶��,介電和磁性材料單晶,氧化物及金屬間化合物單晶等��。 |
耐高溫��、耐高壓��、高真空、 高透光率��、拆裝簡便的樣品腔 | 由德國弗勞恩霍夫應用光 和精密工程研究所優(yōu)化設計的高反射率鏡面��, 鏡體位置可由高精度步進馬達控制調節(jié) |
光闌式光強控制器 更方便地調節(jié)熔區(qū)溫度��,延長燈泡壽命 | 仿真化觸屏控制軟件 界面友好,操作簡單 |
熔區(qū)測溫選件**測溫技術 可實時監(jiān)測加熱區(qū)溫度 | 多路獨立氣路控制選件 可控制N2��、O2��、Ar��、空氣等的流量和壓力��, 并可對氣體進行比例混合與熔區(qū)進行反應 |
氣體除雜選件 可使高壓氬氣中的氧含量達到10-12ppm | 退火選件 可對離開熔區(qū)的單晶棒提供 高達1100℃退火溫度和高壓氧環(huán)境 |
SciDre單晶爐特點
● 采用垂直式光路設計
● 采用高照度短弧氙燈��,多種功率規(guī)格可選
● 熔區(qū)溫度:>3000℃
● 熔區(qū)壓力:10bar/50bar/100bar/150bar/300bar等多種規(guī)格可選
● 氧氣/氬氣/氮氣/空氣/混合氣等多種氣路可選
● 采用光柵控制技術,加熱功率從0-100% 連續(xù)可調
● 樣品腔可實現(xiàn)低至10-5mbar真空環(huán)境
● 豐富的可升級選件
SciDre單晶爐技術參數(shù)
熔區(qū)溫度:高達2000 - 3000℃以上
熔區(qū)壓力:高至10��、50��、100��、150、300 bar可選
熔區(qū)真空:1*10-2 mbar或 1*10-5 mbar可選
熔區(qū)氣氛:Ar��、O2��、N2等可選
氣體流量:0.25 – 1 L/min流量可控
氙燈功率:3kW至15kW可選
料棒臺尺寸:6.8mm或9.8mm可選
拉伸速率:0.1-50mm/h
調節(jié)速率:0.6 mm/s
拉伸尺寸:130mm��,150mm,195mm可選
旋轉速率:0-70rpm
用電功率:400V三相 63A 50Hz
主機尺寸:330cm*163cm*92cm (不同規(guī)格略有差異)
發(fā)表文章
1. (2020)Single crystal growth and luminescent properties of YSH:Eu scintillator by optical floating zone method Chemical Physics Letters, Volume 738��, 136916
2. (2020)Anisotropic character of the metal-to-metal transition in Pr4Ni3O10 Phys. Rev. B 101��, 104104
3. (2020)Synthesis of a New Ruthenate Ba26Ru12O57 Crystals 2020��, 10(5), 355
4. (2020)Synthesis and characterization of bulk Nd1- SrxNiO2 and Nd1- xSrxNiO3 Phys. Rev. Materials 4, 084409
5. (2020)Magnetic phase diagram and magnetoelastic coupling of NiTiO3 Phys. Rev. B 101, 195122
6. (2019)High pO2 Floating Zone Crystal Growth of the Perovskite Nickelate PrNiO3 Crystals 2019��, 9(7)��, 324
7. (2019)Magnetic properties of high-pressure optical floating-zone grown LaNiO3 single crystals Journal of Crystal Growth Volume 524��, 15 October 2019, 125157
8. (2019)Bulk single-crystal growth of the theoretically predicted magnetic Weyl semimetals RAlGe (R = Pr, Ce) Phys. Rev. Materials 3��, 024204
9. (2019)Pushing boundaries: High pressure��, supercritical optical floating zone materials discovery Journal of Solid State Chemistry 270 (2019): 705-709
10. (2018). Antiferromagnetic correlations in the metallic strongly correlated transition metal oxide LaNiO3. Nature Communications 9:43
11. (2017). Single-crystal growth and physical properties of 50% electron-doped rhodate Sr 1.5 La 0.5 RhO 4 Physical Review Materials 1(4)��, 044005
12. (2017). Single crystal growth and structural evolution across the 1st order valence transition in (Pr1-yYy) 1- xCaxCoO3-δJournal of Solid State Chemistry 254, 69-74
13. (2017). Large orbital polarization in a metallic square-planar nickelate. Nature Physics 13��, 864–869
14. (2017). High-Pressure Floating-Zone Growth of Perovskite Nickelate LaNiO3 Single Crystals. Crystal Growth & Design 17(5)��, 2730-2735.
15. (2017). High-pressure optical floating-zone growth of Li(Mn��,F(xiàn)e)PO4 single crystals. Journal of Crystal Growth��, 462��, 50-59.
16. (2016). Evidence for a spinon Fermi surface in a triangular-lattice quantum-spin-liquid candidate. Nature 540, 559–562.
17. (2016). Stacked charge stripes in quasi-2D trilayer nickelate La4Ni3O8. PNAS 2016 113 (32) 8945-8950.
18. (2016). Single Crystal Growth of Pure Co3+ Oxidation State Material LaSrCoO4. Crystals��, 6(8)��, 98.
19. (2015). Floating zone growth of Ba-substituted ruthenate Sr2?xBaxRuO4. Journal of Crystal Growth��, 427, 94-98.
20. (2015). High pressure floating zone growth and structural properties of ferrimagnetic quantum paraelectric BaFe12O19. APL Materials 3��, 062512.
21. (2015). Impact of local order and stoichiometry on the ultrafast magnetization dynamics of Heusler compounds. Journal of Physics D: Applied Physics��, 48(16)��, 164016.
22. (2014). Brownmillerite Ca2Co2O5: Synthesis, Stability��, and Re-entrant Single Crystal to Single Crystal Structural Transitions. Chemistry of Materials��, 26(24)��, 7172-7182.
23. (2014). Low-temperature properties of single-crystal CrB2. Physical Review B��, 90(6), 064414.(Also on archiv.org.)
24. (2014). Effect of annealing on spinodally decomposed Co2CrAl grown via floating zone technique. Journal of Crystal Growth��, 401��, 617-621.(Also on arxiv.org.)
25. (2013). de Haas–van Alphen effect and Fermi surface properties of single-crystal CrB2. Physical Review B��, 88(15), 155138. (Also on arxiv.org.)
26. (2013). Phase Dynamics and Growth of Co2Cr1–xFexAl Heusler Compounds: A Key to Understand Their Anomalous Physical Properties. Crystal Growth & Design��, 13(9)��, 3925-3934.
27. (2011). Exploring the details of the martensite–austenite phase transition of the shape memory Heusler compound Mn2NiGa by hard x-ray photoelectron spectroscopy��, magnetic and transport measurements. Applied Physics Letters, 98(25)��, 252501.
28. (2011). Challenges in the crystal growth of Li2CuO2 and LiMnPO4. Journal of Crystal Growth��, 318(1), 995-999.
29. (2011). Self-flux growth of large EuCu 2 Si 2 single crystals. Journal of Crystal Growth��, 318(1)��, 1043-1047.
30. (2010). Influence of heat distribution and zone shape in the floating zone growt·h of selected oxide compounds. Journal of materials science��, 45(8), 2223-2227.
31. (2009). Highly ordered��, half-metallic Co2FeSi single crystals. Applied Physics Letters��, 95(16)��, 161903.
32. (2009). Single-crystal growth of LiMnPO4 by the floating-zone method. Journal of Crystal Growth, 311(5)��, 1273-1277(Also on uni-heidelberg.de.)
33. (2008). Crystal growth of rare earth-transition metal borocarbides and silicides. Journal of Crystal Growth��, 310(7)��, 2268-2276.
用戶單位
中國科學院物理研究所
中國科學院固體物理研究所
北京師范大學
中山大學
南昌大學
上海大學
