Applied Materials , 974 East Arques Avenue, M/S 81280, Sunnyvale, California 94085, United States.
ACS Nano. 2016 Apr 26;10(4):4451-8. doi: 10.1021/acsnano.6b00094. Epub 2016 Mar 15.
Area-selective atomic layer deposition (AS-ALD) is attracting increasing interest because of its ability to enable both continued dimensional scaling and accurate pattern placement for next-generation nanoelectronics. Here we report a strategy for depositing material onto three-dimensional (3D) nanostructures with topographic selectivity using an ALD process with the aid of an ultrathin hydrophobic surface layer. Using ion implantation of fluorocarbons (CFx), a hydrophobic interfacial layer is formed, which in turn causes significant retardation of nucleation during ALD. We demonstrate the process for Pt ALD on both blanket and 2D patterned substrates. We extend the process to 3D structures, demonstrating that this method can achieve selective anisotropic deposition, selectively inhibiting Pt deposition on deactivated horizontal regions while ensuring that only vertical surfaces are decorated during ALD. The efficacy of the approach for metal oxide ALD also shows promise, though further optimization of the implantation conditions is required. The present work advances practical applications that require area-selective coating of surfaces in a variety of 3D nanostructures according to their topographical orientation.
区域选择性原子层沉积(AS-ALD)因其能够为下一代纳米电子学实现持续的尺寸缩放和精确的图案定位而引起了越来越多的关注。在这里,我们报告了一种使用ALD 工艺在具有地形选择性的三维(3D)纳米结构上沉积材料的策略,该工艺借助超薄疏水性表面层。通过氟碳(CFx)的离子注入,形成疏水性界面层,这反过来又在 ALD 过程中导致成核明显延迟。我们在覆盖层和 2D 图案化衬底上演示了 Pt ALD 过程。我们将该工艺扩展到 3D 结构,证明该方法可以实现选择性各向异性沉积,选择性地抑制在失活的水平区域上的 Pt 沉积,同时确保仅在 ALD 过程中对垂直表面进行修饰。该方法在金属氧化物 ALD 中的应用也显示出了前景,尽管需要进一步优化注入条件。本工作推进了根据表面的地形取向对各种 3D 纳米结构进行区域选择性涂层的实际应用。
