Lau Wai Shing
Lau Wai Shing, also known as Wai Shing Lau, is a Hong Kong electrical engineer and materials scientist. He worked on both Si-based and III-V based microelectronics.
Biography
Lau was born in Hong Kong in 1955 to Lau Pak Chau, a public health inspector and amateur painter, and Tse Kwan Fong. He has 2 older brothers and 2 younger sisters.He graduated in Electrical Engineering at the University of Hong Kong in 1977. He obtained a master's degree from the Department of Electronics, the Chinese University of Hong Kong in 1980. Subsequently, he published a paper on the analysis of constant-capacitance deep-level transient spectroscopy by negative feedback theory in 1982. For his PhD in Electrical Engineering from the Pennsylvania State University, Pennsylvania, USA in 1987 he worked on transparent conductive thin films like tin oxide, indium oxide and zinc oxide. Then he served as a post-doctoral student in the same laboratory to work on PECVD silicon nitride samples from IBM. New insight was gained regarding hysteresis in the C-V characteristics and how to suppress it in MNS capacitors.
Lau served as lecturer and then senior lecturer in the National University of Singapore from 1988 to 1997.
Lau worked on gallium arsenide and gallium nitride devices and materials. He developed the "true oxide electron beam induced current" technique to study local defects in insulating thin films. TOEBIC can be applied to MOS capacitors. Dr. Lau's theory was that local defects in the oxide and local defects in silicon could be distinguished when electron beam induced current was performed on M/SiO2/Si capacitor structures. He proposed to use PECVD silicon nitride / polyimide dual passivation for AlGaN/GaN HEMT. When PECVD silicon nitride is thick, there is mechanical stress problem. It may also have pinholes. Polyimide can be quite thick without stress problem but it is not a good barrier for moisture. Thick polyimide can cover up the pinholes in the PECVD silicon nitride below. The two combined together with polyimide on top of the nitride can be a practical and better approach. In addition, the dielectric constant of polyimide is smaller than that of PECVD silicon nitride, resulting in less parasitic capacitance.
Dr. Lau also worked on Ohmic contact technology for GaN and AlGaN/GaN HEMT. He noticed that the presence of a small quantity of moisture in the rapid thermal annealing chamber is particularly bad for Ohmic contact on AlGaN/GaN HEMT wafers. However, this is less serious for Ohmic contact on GaN only.
Dr. Lau has also published a paper on low frequency noise in polysilicon emitter bipolar transistors in 1992. Basically, the application of a very thin layer of interfacial oxide between the polysilicon emitter and the single-crystalline emitter can help to increase the current gain. However, this approach will very significantly increase low frequency noise probably because of tunnelling 1/f noise.
During 1997–1998, he worked on embedded DRAM technology in Chartered Semiconductor Manufacturing, Singapore. He studied the mechanism of under-sensitive test structures and over-sensitive test structures. He pointed out that if this is properly understood, electrical failure analysis can be more easily achieved by electrical testing at the test structure level instead of at the product engineering level. This will make the job of DRAM yield enhancement easier.
Dr. Lau became an associate professor in the Nanyang Technological University since 2001.
He was the first in making a correlation between the leakage current of ultrathin tantalum pentoxide films with defect states detected by zero-bias thermally stimulated current. Most scientists cannot see any relationship between the leakage current in tantalum oxide and the defect states detected by thermally stimulated current. For example, Dr. Yasushiro Nishioka could not see any relationship between the leakage current and the defect states detected by thermally stimulated current. Dr. Lau managed to see the relationship between the leakage current and the defect states and published his theory in various papers. He invented "zero temperature gradient zero bias thermally stimulated current" as a method to detect defect states in ultrathin high-κ dielectric films. This was patented as US Patent 6909273 in 2005. In addition, he has also developed a technique known as "two-scan zero-bias thermally stimulated current" when an insulator or semiconductor has some traps that can be filled at low temperature and some traps that can only be filled at relatively high temperature.
He also worked on Cu/kow-κ back-end-of-line technology.
He also wrote various papers on MOS transistors. For example, he worked on the application of strain engineering to CMOS technology. He pointed out that if tensile stress can increase the on current of n-channel MOS transistors, tensile stress will also increase the off current. Then he proposed a theory why tensile stress can improve n-channel MOS transistors even though there is an increase in the off current. A lady graduate student, Peizhen Yang, was recruited to work on research in this direction. Similarly, his theory can be applied to the study of p-channel MOS transistors with the conventional <110> channel or the newer <100> channel. He also studied the reduction of boron lateral channelling due to switching from the conventional <110> channel to the newer <100> channel.
Dr. Lau also studied the theory of electron mobility in Si-based MOSFET. In 2005, Dr. Lau pointed out as Lau's hypothesis that "remote Coulombic scattering" is only important in the subthreshold region and in the region slightly above threshold.
Dr. Lau also explained the observation of anomalous narrow channel effect in very short p-channel MOSFET. This effect is relatively weak in n-channel MOSFET. An explanation why this effect is strong in PMOS but weak in NMOS has been proposed by Dr. Lau; p-type dopants like boron tends to segregate into the STI oxide while n-type dopants tend to accumulate at the STI oxide/Si interface.
Dr. Lau is also interested in quasi-ballistic transport in MOS transistors and has published his theory on it. Instead of a carrier saturation velocity according to convention velocity saturation theory, an effective saturation velocity can be defined. It turns out that the value of effective saturation velocity in real-life MOS transistors is similar to established values of the carrier saturation velocity. However, Dr. Lau pointed out that the effective saturation velocity can be a function of the gate voltage.
Besides semiconductor materials and devices research, Dr. Lau also works privately on the research of traditional Chinese medicine, foot or hand reflexology, "unrefreshing sleep", chronic fatigue syndrome, irritable bowel syndrome, toothache, etc. For example, he noticed that there are two toothache mechanisms according to his personal experience: Mechanism according to Western medicine and Mechanism according to traditional Chinese medicine. He had direct experience of toothache that can be easily explained by Western medicine and also a kind of toothache that cannot be explained by Western dental theory but can be explained by traditional Chinese medicine. Thus the two mechanisms are not contradictory. They are actually complementary. The solution of the second kind of toothache is explained in various books on traditional Chinese medicine. However, those solutions are too complicated or inconvenient for an ordinary person living in the Western World; Dr. Lau has privately developed a much simpler and convenient solution. Dr. Lau is also interested in the application of Oldenlandia diffusa to treat some medical problems.
He has also worked on the application of infrared spectroscopy to semiconductor materials. He has published a book Infrared Characterization for Microelectronics, World Scientific, Singapore, 1999. He has also developed some new insight regarding the application of Raman spectroscopy to health problems. He has also done some work on control theory and applied it to his research. The application of negative feedback control to a chaotic system is highly challenging. He has developed some insight on the practical feedback control of chaotic systems.
Dr. Lau has developed a theory regarding the symmetry of the I-V characteristics of high-κ dielectric capacitor structures . In addition, he has proposed an "extended unified Schottky-Poole-Frenkel theory" . Furthermore, he observed Poole-Frenkel saturation experimentally .