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Background
Decrease of feature size has been the driving force in electronics. With smaller sizes, there are more transistors on a chip, allowing higher speed and larger memory in computers, cell phones, IPODs, and other consumer electronics.
Objectives
We strive to develop a suite of multi-scale electronic design automation (EDA) tools ranging from atomistic simulation methods to circuit simulators and to electromagnetic solvers for electrical signals for emerging sub-22nm technology. With these tools, we will study the sub-22nm devices and their systems; and calculate their physical and dynamical properties, and explore the possible paradigm shifts of next generation electronics. Our objectives are specifically listed below:
- ★ To simulate from first-principles the electrical properties and processes of sub-22nm devices with atomistic details
- ★ To investigate lithography modeling, and to employ efficient electromagnetic solvers to simulate electrical signals, power delivery, crosstalk, interference, and noise in multi-scale complex integrated circuits
- ★ To calculate and model the electrical, chemical and mechanical properties of new materials for sub-22nm technology
- ★ To develop modeling tools for the emerging spintronics and magnetic random access memory (MRAM)
- ★ To use electron beam lithography technology to fabricate the sub-22nm devices for measurement and calibration of the parameters in our EDA tools
- ★ To develop a set of multi-scale EDA tools for emerging devices and integrated circuits
Connections to Semiconductor Industry
- ★ Our former students and postdoctoral fellows are working in leading IT companies (such as Intel, IBM, HP, Cadence, Agilent, Qualcom, Synopsys, TSMC and SMIC)
- ★ Members have received funding from leading IT companies including SRC, IBM, Intel, and Mentor Graphics
- ★ Five Innovation and Technology Funds have been awarded to our team members
Facilities
- ★ Several computer clusters including a 64-bit Linux cluster (consisting of 16 blade servers; each equipped with two 64-bit six-core Intel Xeon CPU running at 3GHz and 48GB physical memory, and theoretically delivers the processing power up to 2.304 Tera-flops)
- ★ Multi-chamber ultrahigh vacuum (UHV) system with a UHV-scanning tunneling microscope (STM) and atomic force microscope (AFM), low energy electron diffraction (LEED), reflection high-energy electron diffraction (RHEED), and X-ray photoelectron spectroscopy (XPS)
- ★ Confocal microscope based spectroscopy system, a femtosecond laser system, and an electrical probe station
- ★ Low temperature (He-3 cryostat) and high magnetic field transport measurement platform
- ★ Nanofabrication Fabrication Facility (NFF), in HKUST, is the first micro and nanofabrication laboratory established at a tertiary institution in Hong Kong. The mission of the NFF is to provide facilities for the faculty and students of all the UGC funded institutions to conduct teaching and research, particularly in new semiconductor devices and nanoelectronics process technology
- ★ Material Characterization and Preparation Facility (MCPF), in HKUST, is a central facility intensively serving the academic researchers and postgraduate students in schools of science and engineering for the preparation, characterization and analysis of various advanced materials. In addition to serving HKUST, MCPF also provides services to Hong Kong sister institutions and clients from government laboratories and regional industries. Since the MCPF was established in 1991, it has become an indispensable central facility in HKUST