Synopses & Reviews
This book provides the background, tools, and directions you need to confidently choose fabrication methods and materials for miniaturization problems (materials, processes, designs, characterisations and potential applications).MEMS technology and applications have grown at a tremendous pace, while structural dimensions have grown smaller and smaller, reaching down even to the molecular level. With this movement have come new types of applications and rapid advances in the technologies and techniques needed to fabricate the increasingly miniature devices that are literally changing our world. The development of micro-mechanical systems (MEMS) foreshadows momentous changes not only in the technology world, but in virtually every aspect of human life. The future of the field is bright with opportunities, but also riddled with challenges, ranging from further theoretical development through advances in fabrication process technologies and related-materials, to developing high-performance microscale systems, devices, and structures. Materials and process integration for MEMS offer unique, in-depth coverage of the science of miniaturization, its fabrication process techniques (including surface silicon micromachining, bulk silicon micromachining, lithography, precision grinding process, plasma etching process, SCREAMTM process, X-ray based fabrication, and novel techniques), materials (including silicon, UVIII resist, Gallium Arsenide (GaAs), TiNiCu films, Self-Assembled Monolayers (SAM), SU-8, polymers, ferro-electric BST thin film, etc.), their characterization and potential applications.Materials & Process Integration for MEMS offers unique and important information to both academics and professionals whom are active in the field of MEMS.
Synopsis
The field of materials and process integration for MEMS research has an extensive past as well as a long and promising future. Researchers, academicians and engineers from around the world are increasingly devoting their efforts on the materials and process integration issues and opportunities in MEMS devices. These efforts are crucial to sustain the long-term growth of the MEMS field. The commercial MEMS community is heavily driven by the push for profitable and sustainable products. In the course of establishing high- volume and low-cost production processes, the critical importance of materials properties, behaviors, reliability, reproducibility, and predictability, as well as process integration of compatible materials systems become apparent. Although standard IC fabrication steps, particularly lithographic techniques, are leveraged heavily in the creation of MEMS devices, additional customized and novel micromachining techniques are needed to develop sophisticated MEMS structures. One of the most common techniques is bulk micromachining, by which micromechanical structures are created by etching into the bulk of the substrates with either anisotropic etching with strong alk: ali solution or deep reactive-ion etching (DRIB). The second common technique is surface micromachining, by which planar microstructures are created by sequential deposition and etching of thin films on the surface of the substrate, followed by a fmal removal of sacrificial layers to release suspended structures. Other techniques include deep lithography and plating to create metal structures with high aspect ratios (LIGA), micro electrodischarge machining (J.
Table of Contents
Contributors. Acknowledgements. Foreword. Preface. 1. Integration of Piezoelectric Pb (ZrxTi1-x)O3 (PZT) Thin Films into Micromachined Sensors and Actuators; P. Muralt, et al. 2. Porous Silicon as a Sacrificial Layer in Production of Silicon Diaphragms by Precision Grinding; A. Prochaska, et al. 3. GaAs Cantilever and Bridge Membrane-Like Structures Fully Compatible with AlGaAs/InGaAs/GaAs and InGaP/InGaAs/GaAs Based HFETs; T. Lalinsky, et al. 4. Magnetron Sputtered TiNiCu Shape Memory Alloy Thin Film for MEMS Applications; Yongqing Fu, Hejun Du. 5. Chemically Amplified Resist for Micromachining using X-Ray Lithography; T.L. Tan, et al. 6. Self-Assembled Monolayers (SAM) for Tunneling Sensors; F.E.H. Tay, et al. 7. Oxidation Process-Optimization for Large Area Silicon Fusion Bonded Devices and MEMS Structures; K.N. Bhat, et al. 8. Silicon Nanomachining by Scanning Probe Lithography and Anisotropic Wet Etching; J.T. Sheu, et al. 9. A Novel Bulk Micromachining Method in Gallium Arsenide; Dong-il "Dan" Cho, et al.. 10. Deep X-Ray Lithography for MEMS-Photoelectron Exposure of the Upper and Bottom Resist Layers; V. Kudryashov, P. Lee. 11. Spray Coating Technology of Photoresist/Polymer for 3-D Patterning and Interconnect; A.B. Suriadi, et al. 12. Uncooled Infrared Image Sensor of Dielectric Bolometer Mode using Ferroelectric BST Thin Film Prepared by Metal Organic Decomposition; Hong Zhu, et al. 13. Tactical Grade MEMS Gyroscopes Fabricated by the SBM Process; Dong-il "Dan" Cho, et al. 14. Plasma Etching Techniques to Form High-Aspect-Ratio MEMS Structures; Won Jong Yoo, et al. Index.