Cu metallization has been widely applied in back-end-of-line (BEOL) of integrated circuit fabrication, as well as in advanced packaging such as 3-D interconnects and through silicon via (TSV). As the device feature size further shrinks copper diffusion barrier layers with high conductivity, good thermal stability and low Cu diffusion coefficient are to be developed. Amorphous metal alloy films of Ta-transition metal (TM = Ni, Cr, Ti) are proposed and examined as a potential copper diffusion barrier. All Ta-TM films deposited on Si showed lower resistivity compared to the conventional Ta nitride films. Ta-Ni films containing up to 86 wt% Ta were found to have as-deposited amorphous phase. Ta-Cr films also contained glassy phase in all studied composition range. However, crystalline phase was observed in the as-deposited Ta-Ti films. The glassy Ta-Ni thin films showed high stability up to 800?C. Beyond this temperature, crystallization of Ta, Ni3Si2, Ta2O5 and Ta5Si3 were detected. As-deposited glassy Ta-Cr also maintained the amorphous phase up to 800?C, with Ta2O5 and Ta crystalline peak observed. For Ta-Ti films, a solid phase amorphourization was observed when films were annealed at 600?C. The amorphous phase was stable up to 800?C, with TaxTi1-xO2 crystalline phase has appeared. Therefore it is concluded that Ta-Cr and Ta-Ni has higher glass forming ability and higher thermal stability compared to Ta-Ti films. Copper diffusion barrier performance of Ta-TM films were studied on Cu/Ta-TM/Si stack at different temperatures, ranging from 600 to 800?C. For Cu/Ta-Ti/Si, solid phase amorphourization of Ta-Ti at 600?C was observed. No Cu3Si peaks were observed for all samples until 700?C. XRD study showed that at 700?C, fast reaction between Cu and Si was observed in Ta-Cr and Ta-Ti barriers, while very low Cu3Si peak could be obs-erved in Ta-Ni barrier. TEM observation showed that Ta-Ti films lost continuity while Ta-Cr and Ta-Ni still maintained integrity at 700?C. It is therefore concluded that the studied Ta-TM binary metallic thin films can be applied as a good amorphous copper diffusion barrier, with low electrical resistivity, high thermal stability and good copper diffusion retardation performance. In order to reduce the diffusion rate of Cu in barrier, Ta-Ni barrier is preferred, followed by Ta-Cr and Ta-Ti.
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机译:铜金属化已广泛应用于集成电路制造的后端(BEOL),以及高级封装(如3-D互连和硅通孔(TSV))中。随着器件特征尺寸进一步缩小具有高导电率的铜扩散阻挡层,将开发出良好的热稳定性和低的Cu扩散系数。提出并研究了Ta过渡金属(TM = Ni,Cr,Ti)的非晶态金属合金膜作为潜在的铜扩散阻挡层。与传统的氮化钽薄膜相比,所有沉积在硅上的钽薄膜都具有较低的电阻率。发现含有至多86wt%的Ta的Ta-Ni膜具有沉积态的非晶相。在所有研究的组成范围内,Ta-Cr膜还含有玻璃相。然而,在沉积的Ta-Ti膜中观察到结晶相。呈玻璃状的Ta-Ni薄膜在高达800°C的温度下显示出高稳定性。超过此温度,Ta,Ni 3 Si 2 ,Ta 2 O 5 和Ta 的结晶检测到5 Si 3 。沉积态的玻璃态Ta-Cr也保持高达800℃的非晶相,并观察到Ta 2 O 5 和Ta结晶峰。对于Ta-Ti薄膜,当薄膜在600°C退火时,观察到固相非晶化。非晶相在高达800°C的温度下都稳定,并出现了Ta x Ti 1-x O 2 晶相。因此,可以得出结论,与Ta-Ti膜相比,Ta-Cr和Ta-Ni具有更高的玻璃形成能力和更高的热稳定性。在Cu / Ta-TM / Si叠层上,在600至800°C的不同温度下研究了Ta-TM膜的铜扩散阻挡性能。对于Cu / Ta-Ti / Si,在600℃观察到Ta-Ti的固相非晶化。直到700℃,所有样品都未观察到Cu 3 Si峰。 XRD研究表明,在700°C时,Ta-Cr和Ta-Ti势垒中Cu和Si发生了快速反应,而Cu 3 Si峰很低。
在Ta-Ni阻挡层中弯曲。 TEM观察表明,Ta-Ti薄膜失去了连续性,而Ta-Cr和Ta-Ni在700°C时仍保持完整性。因此,可以得出结论,所研究的Ta-TM二元金属薄膜可以用作良好的非晶态铜扩散阻挡层,具有低电阻率,高热稳定性和良好的铜扩散延迟性能。为了降低Cu在势垒中的扩散速率,优选Ta-Ni势垒,其次是Ta-Cr和Ta-Ti。
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