Rujun Sun, Y. Ooi, A. Bhattacharyya, Muad Saleh, S. Krishnamoorthy, K. Lynn, M. Scarpulla
{"title":"重掺zr β-Ga2O3晶体的缺陷态及其电场增强电子热发射","authors":"Rujun Sun, Y. Ooi, A. Bhattacharyya, Muad Saleh, S. Krishnamoorthy, K. Lynn, M. Scarpulla","doi":"10.1063/5.0029442","DOIUrl":null,"url":null,"abstract":"Performing deep level transient spectroscopy (DLTS) on Schottky diodes, we investigated defect levels below the conduction band minima (Ec) in Czochralski (CZ) grown unintentionally-doped (UID) and vertical gradient freeze (VGF)-grown Zr-doped beta-Ga2O3 crystals. In UID crystals with an electron concentration of 10^17 cm-3, we observe levels at 0.18 eV and 0.46 eV in addition to the previously reported 0.86 (E2) and 1.03 eV (E3) levels. For 10^18 cm-3 Zr-doped Ga2O3, signatures at 0.30 eV (E15) and 0.71 eV (E16) are present. For the highest Zr doping of 5*10^18 cm-3, we observe only one signature at 0.59 eV. Electric field-enhanced emission rates are demonstrated via increasing the reverse bias during measurement. The 0.86 eV signature in the UID sample displays phonon-assisted tunneling enhanced thermal emission and is consistent with the widely reported E2 (FeGa) defect. The 0.71 eV (E16) signature in the lower-Zr-doped crystal also exhibits phonon-assisted tunneling emission enhancement. Taking into account that the high doping in the Zr-doped diodes also increases the electric field, we propose that the 0.59 eV signature in the highest Zr-doped sample likely corresponds to the 0.71 eV signature in lower-doped samples. Our analysis highlights the importance of testing for and reporting on field-enhanced emission especially the electric field present during DLTS and other characterization experiments on beta-Ga2O3 along with the standard emission energy, cross-section, and lambda-corrected trap density. This is important because of the intended use of beta-Ga2O3 in high-field devices and the many orders of magnitude of possible doping.","PeriodicalId":8467,"journal":{"name":"arXiv: Materials Science","volume":"133 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2020-11-07","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"8","resultStr":"{\"title\":\"Defect states and their electric field-enhanced electron thermal emission in heavily Zr-doped β-Ga2O3 crystals\",\"authors\":\"Rujun Sun, Y. Ooi, A. Bhattacharyya, Muad Saleh, S. Krishnamoorthy, K. Lynn, M. Scarpulla\",\"doi\":\"10.1063/5.0029442\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Performing deep level transient spectroscopy (DLTS) on Schottky diodes, we investigated defect levels below the conduction band minima (Ec) in Czochralski (CZ) grown unintentionally-doped (UID) and vertical gradient freeze (VGF)-grown Zr-doped beta-Ga2O3 crystals. In UID crystals with an electron concentration of 10^17 cm-3, we observe levels at 0.18 eV and 0.46 eV in addition to the previously reported 0.86 (E2) and 1.03 eV (E3) levels. For 10^18 cm-3 Zr-doped Ga2O3, signatures at 0.30 eV (E15) and 0.71 eV (E16) are present. For the highest Zr doping of 5*10^18 cm-3, we observe only one signature at 0.59 eV. Electric field-enhanced emission rates are demonstrated via increasing the reverse bias during measurement. The 0.86 eV signature in the UID sample displays phonon-assisted tunneling enhanced thermal emission and is consistent with the widely reported E2 (FeGa) defect. The 0.71 eV (E16) signature in the lower-Zr-doped crystal also exhibits phonon-assisted tunneling emission enhancement. Taking into account that the high doping in the Zr-doped diodes also increases the electric field, we propose that the 0.59 eV signature in the highest Zr-doped sample likely corresponds to the 0.71 eV signature in lower-doped samples. 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引用次数: 8
摘要
利用深能级瞬态光谱(DLTS)对肖特基二极管进行了研究,研究了CZ生长的无意掺杂(UID)和VGF生长的掺杂zr - ga2o3晶体中低于导带最小值(Ec)的缺陷水平。在电子浓度为10^17 cm-3的UID晶体中,除了先前报道的0.86 (E2)和1.03 eV (E3)水平外,我们还观察到0.18 eV和0.46 eV的水平。对于10^18 cm-3 zr掺杂的Ga2O3,存在0.30 eV (E15)和0.71 eV (E16)的特征。对于Zr掺杂最高的5*10^18 cm-3,我们只观察到一个0.59 eV的特征。通过在测量过程中增加反向偏置,证明了电场增强的发射率。UID样品的0.86 eV特征显示声子辅助隧穿增强的热发射,与广泛报道的E2 (FeGa)缺陷一致。低zr掺杂晶体的0.71 eV (E16)特征也表现出声子辅助隧穿发射增强。考虑到zr掺杂二极管的高掺杂也增加了电场,我们提出zr掺杂最高的样品中的0.59 eV特征可能对应于低掺杂样品中的0.71 eV特征。我们的分析强调了测试和报告场增强发射的重要性,特别是在DLTS和β - ga2o3的其他表征实验中存在的电场,以及标准发射能量、横截面和lambda校正的陷阱密度。这一点很重要,因为β - ga2o3在高场器件中的预期用途和可能掺杂的许多数量级。
Defect states and their electric field-enhanced electron thermal emission in heavily Zr-doped β-Ga2O3 crystals
Performing deep level transient spectroscopy (DLTS) on Schottky diodes, we investigated defect levels below the conduction band minima (Ec) in Czochralski (CZ) grown unintentionally-doped (UID) and vertical gradient freeze (VGF)-grown Zr-doped beta-Ga2O3 crystals. In UID crystals with an electron concentration of 10^17 cm-3, we observe levels at 0.18 eV and 0.46 eV in addition to the previously reported 0.86 (E2) and 1.03 eV (E3) levels. For 10^18 cm-3 Zr-doped Ga2O3, signatures at 0.30 eV (E15) and 0.71 eV (E16) are present. For the highest Zr doping of 5*10^18 cm-3, we observe only one signature at 0.59 eV. Electric field-enhanced emission rates are demonstrated via increasing the reverse bias during measurement. The 0.86 eV signature in the UID sample displays phonon-assisted tunneling enhanced thermal emission and is consistent with the widely reported E2 (FeGa) defect. The 0.71 eV (E16) signature in the lower-Zr-doped crystal also exhibits phonon-assisted tunneling emission enhancement. Taking into account that the high doping in the Zr-doped diodes also increases the electric field, we propose that the 0.59 eV signature in the highest Zr-doped sample likely corresponds to the 0.71 eV signature in lower-doped samples. Our analysis highlights the importance of testing for and reporting on field-enhanced emission especially the electric field present during DLTS and other characterization experiments on beta-Ga2O3 along with the standard emission energy, cross-section, and lambda-corrected trap density. This is important because of the intended use of beta-Ga2O3 in high-field devices and the many orders of magnitude of possible doping.