Experimental studies on the damage produced in (100) Ge substrates by implantation of Ge+ ions at different energies (from 25 to 600 keV), fluences (from 2×1013 to 4×1014 cm−2) and temperature (room temperature, RT, or liquid-nitrogen temperature, LN2T) have been performed by using the Rutherford backscattering spectrometry technique. We demonstrated that the higher damage rate of Ge with respect to Si is due to both the high stopping power of germanium atoms and the low mobility of point defects within the collision cascades. The amorphization of Ge has been modeled by employing the critical damage energy density model in a large range of implantation energies and fluences both at RT and LN2T. The experimental results for implantation at LN2T were fitted using a critical damage energy density of ∼1 eV/atom. A fictitious value of ∼5 eV/atom was obtained for the samples implanted at RT, essentially because at RT the damage annihilation plays a non-negligible role against the crystalline–amorphous transition phase. The critical damage energy density model was found to stand also for other ions implanted in crystalline Ge (Ar+ and Ga+).
展开▼
机译:通过注入不同能量(25至600 keV),注量(2×10 13 )的Ge + 离子在(100)Ge衬底中产生损伤的实验研究至4×10 14 cm −2 )和温度(室温,RT或液氮温度,LN 2 T)已使用卢瑟福背散射光谱技术进行分析。我们证明,相对于Si,Ge的损坏率更高是由于锗原子的高阻止能力和碰撞级联内的点缺陷迁移率较低。 Ge的非晶化已通过在室温和LN 2 T的大范围注入能量和注量下采用临界损伤能量密度模型进行建模。使用〜1 eV /原子的临界损伤能量密度拟合了在LN 2 T处植入的实验结果。对于在室温下注入的样品,获得的假想值约为5 eV /原子,这主要是因为在室温下,破坏an灭对晶态-非晶态过渡相起着不可忽略的作用。发现临界损伤能量密度模型也适用于注入晶体Ge中的其他离子(Ar + 和Ga + )。
展开▼
