Abstract
This paper presents a low temperature process (≤450°C) to transfer amorphous, hydrogenated silicon carbide (a-SiC:H) thin films from a silicon deposition substrate to a second silicon substrate by way of a-SiC:H/Si direct bonding. Compared to traditional thin film bonding and transfer processes, the proposed approach does not rely on IC-incompatible substances or high process temperatures to form the bond. Due to the ultra-smooth a-SiC surfaces, a CMP step normally used in traditional direct bonding is not required. Using this approach, prototype structures, such as nano-gap channels and vacuum-sealed, micron-deep reservoirs with a-SiC films as capping layers have been successfully fabricated. With the aid of finite element simulation, the role of each individual parameter to the bonding process was analyzed. A calculation method based on the concept of strain-energy was introduced to estimate the lower bound of the presented bonding strength.
Keywords: Direct bonding, silicon carbide, vacuum sealed cavities, NEMS, MEMS, mechanical calculation
Related Books
Nanoscale Field Effect Transistors: Emerging Applications
Nanoelectronics Devices: Design, Materials, and Applications Part II
Nanoelectronics Devices: Design, Materials, and Applications (Part I)
Role of Nanotechnology in Cancer Therapy
Synthesis and Applications of Semiconductor Nanostructures
Pathways to Green Nanomaterials: Plants as Raw Materials, Reducing Agents and Hosts
Applications of Nanomaterials in Medical Procedures and Treatments
Synthesis of Nanomaterials
Nanobiotechnology: Principles and Applications
Bio-Inspired Nanotechnology
3