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作为集成电路(ICs)的基础材料, 直拉硅(CZ-Si)单晶的机械强度不仅是硅片加工和ICs制造过程中工艺参数设定的重要考虑因素, 而且在很大程度上决定了ICs芯片在测试和封装过程中出现的失效情况. 目前, ICs的器件特征尺寸仍在继续减小, 由此带来的器件集成规模的增长会导致硅衬底中应力水平的提高, 从而使位错更易产生. 因此, 改善直拉硅片的机械强度对于提高ICs的制造成品率具有重要意义. 本文提出在直拉硅单晶中同时掺入锗和氮两种杂质来改善硅片机械强度的思路. 基于此, 对比研究了普通的、单一掺锗的、单一掺氮的、锗和氮共掺的直拉硅单晶的室温硬度及其在600—1200 ℃时的位错滑移行为. 研究结果表明: 1)单一的锗掺杂或氮掺杂以及锗和氮两种杂质的共掺几乎都不影响直拉硅单晶的室温硬度, 意味着上述掺杂没有改变室温下的位错滑移行为. 2)氮掺杂能显著抑制位错在600—1000 ℃的滑移, 但对位错在1100 ℃及以上温度的滑移几乎没有抑制效应; 锗掺杂几乎不能抑制位错在 600—900 ℃的滑移, 但对位错在1000 ℃及以上温度的滑移具有显著的抑制效应. 3)锗和氮两种杂质的共掺对位错在600—1200 ℃的滑移均有显著的抑制效应, 表明氮掺杂和锗掺杂的互补优势得到了很好的结合. 分析认为, 在600—1000 ℃的温度范围内, 氮掺杂导致在位错核心处形成与氮-氧复合体相关的钉扎中心, 从而抑制位错的滑移; 在1000 ℃及以上温度, 锗掺杂导致在位错前沿附近形成锗-氧复合体, 从而阻碍位错的滑移. 总之, 本文的研究表明在直拉硅单晶中同时掺入锗和氮两种杂质可以进一步地增强硅片在ICs制造工艺温度下的机械强度.Czochralski (CZ) silicon is a base material for manufacturing integrated circuits (ICs). The mechanical strength of CZ silicon determines the processing limitations and often dominates the issues related to packaging and failure of ICs. With the ever-smaller feature size of ICs, the scaling of device dimensions may indirectly lead to increase the stress in silicon substrate, thus increasing the probability of generating dislocations. Consequently, improving the mechanical strength of CZ silicon is of significance for increasing the manufacturing yield of ICs. In this work, we propose a strategy of co-doping germanium (Ge) impurity and nitrogen (N) impurity into CZ silicon to achieve better mechanical strength. In order to explore the feasibility of such a strategy, we comparatively investigate the room-temperature hardness and dislocation gliding behaviors in the temperature range of 600–1200 ℃ in the conventional CZ silicon, Ge-doped CZ silicon, N-doped CZ silicon, as well as N and Ge co-doped CZ silicon. The significant experimental results are described as follows. 1) Ge-doping, N-doping or co-doping of Ge and N hardly influences the hardness and therefore the dislocation gliding behavior at room temperature. 2) The suppressing effect of N-doping on the dislocation gliding is remarkable at 600–1000 ℃ and becomes weakened at the temperatures higher than 1100 ℃, while Ge-doping hardly affects the dislocation gliding at 600–900 ℃ but exhibits a strong suppressing effect on the dislocation gliding at 1000–1200 ℃. 3) Co-doping Ge and N impurities into CZ silicon can take the complementary advantages of both Ge- and N-doping to suppress the dislocation gliding at 600–1200 ℃. It is believed that N-doping can result in the formation of N-O complex-related pinning agents within the dislocation cores to suppress the dislocation gliding at 600–1000 ℃. For Ge-doping, it is supposed that Ge-O complexes acting as the pinning agents can form near the front of a single dislocation when the temperature is as high as 1000 ℃ and above. In a word, it is verified in this work that co-doping Ge and N into CZ silicon can further improve the mechanical strength at the processing temperatures of ICs fabrication.
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Keywords:
- Czochralski slicon/
- mechanical strength/
- dislocation gliding/
- co-doping/
- germanium/
- nitrogen
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硅片 杂质 [Ge]/(1019cm–3) [N]/(1014cm–3) [Oi]/(1017cm–3) CZ — — 7.9 GCZ 2.8 — 8.1 NCZ — 9.0 8.1 GNCZ 2.0 8.1 8.0 CZ GCZ NCZ GNCZ Q/eV 2.12 2.10 2.07 2.00 -
[1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40]
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