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Journal of Synthetic Crystals ›› 2026, Vol. 55 ›› Issue (6): 886-897.DOI: 10.16553/j.cnki.issn1000-985x.xb2026.0021

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Effect of Seed Off-Axis Angles on Distribution of Basal Plane Dislocations in Top-Seeded Solution Growth of SiC Crystals

LUAN Sen(), QI Xiaofang(), MA Wencheng, XU Yongkuan   

  1. State Key Laboratory of Crystal Materials,Tianjin Key Laboratory of Functional Crystal Materials,Institute of Functional Crystals,Tianjin University of Technology,Tianjin 300384,China
  • Received:2026-02-10 Online:2026-06-20 Published:2026-07-07
  • Contact: QI Xiaofang

Abstract: Basal plane dislocations (BPDs) are critical defects that severely degrade the quality of 4H-silicon carbide (SiC) crystal and the performance of 4H-SiC based devices. The top-seeded solution growth (TSSG) method is promising for high-quality SiC crystals with its near-thermodynamic equilibrium conditions. However,the distribution of thermal stress and BPDs is not fully understood in the TSSG growth of 4H-SiC crystals. Both on-axis and off-axis seeds are widely used in the industrial TSSG processes. To investigate the effect of seed off-axis angle (θoff) on thermal stress and BPDs in 4H-SiC crystals grown by the TSSG method,a multi-physics coupled model was developed in this study by integrating global heat transfer,three-dimensional thermoelastic stress analysis,and the Alexander-Haasen dislocation evolution model. The resolved shear stress (RSS) and BPDs density distributions in 4H-SiC crystals grown at off-axis angles of 0°,4°,60°,and 90° were systematically simulated and analyzed. The results show that the seed off-axis angle critically affects the RSS distribution at the growth interface. Under on-axis (θoff=0°) growth,the RSS exhibits a highly symmetric,low-stress state,with stress near the center approaching zero and only minor perturbations at the edge. At the θoff is 4°,the RSS shows axisymmetric regional patterns. At the θoff is 60°,the RSS transitions to a fourfold symmetric distribution with alternating tensile and compressive stresses,and the stress amplitude increases by an order of magnitude compared to that at θoff ≤4°. At the θoff is 90°,the RSS becomes fully fourfold symmetric distribution. Under all conditions,the maximum RSS on the growth surface is lower than that on the seed back surface,and high-stress regions consistently concentrate at the crystal periphery. The density and distribution of BPDs closely correlate with RSS. Under on-axis growth,BPDs exhibit a sixfold symmetric distribution. As the θoff increases,the BPDs distribution gradually transitions to fourfold symmetric distribution,and the overall BPDs density increases significantly. At the θoff are 60° and 90°,the maximum BPDs density reaches approximately 105 cm-2,which is two orders of magnitude higher than that at 4° (approximately 103 cm-2). This substantial increase indicates that large θoff promote BPDs multiplication and are detrimental to high-quality crystal growth. In addition,the BPDs density is consistently higher on the seed back surface than on the growth surface,and high-BPDs regions coincide with high-RSS regions at the crystal periphery. This study elucidates the correlation among the seed off-axis angle,thermal stress field,and BPDs distribution in 4H-SiC crystals grown by the TSSG method. The findings demonstrate that using a seed with a small off-axis angle (≤4°) effectively suppresses BPD generation,thereby facilitating the growth of high-quality 4H-SiC single crystals. These results provide theoretical guidance for optimizing the TSSG process to achieve low defect density and high crystalline perfection.

Key words: top-seeded solution growth; SiC crystal; numerical simulation; off-axis angle; shear stress; basal plane dislocation

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