Add to ORKGtextThis document details experiments attempting to increase the performance of metal-oxide-semiconductor field-effect-transistors (MOSFETs) which are the mainstay of the semiconductor industry. Replacing the silicon channel with an ultra-thin epitaxial germanium layer grown selectively on a silicon (100) bulk wafer is examined in detail. The gate oxide chosen for the germanium devices is a high-k gate oxide, HfO2, and the gate electrode is a metal gate, tantalum-nitride. They demonstrate large improvements in drive current and mobility over identically processed silicon PMOSFETs. In addition to the planar germanium PMOSFETs, a process has been developed for 50nm and smaller germanium P-finFETs and N and P germanium tunnel-FETs. The patte...
textSince metal-oxide-semiconductor (MOS) device was first reported around 1959 and utilized for int...
The development and implementation of a metal gate technology (alloy, compound, or silicide) into me...
The performance of strained silicon (Si) as the channel material for today’s metal-oxide-semiconduct...
textAfter the integrated circuit was invented in 1959, complementary metal-oxidesemiconductor (CMOS...
textThe continued scaling of Si CMOS devices has led to an increased attention to high-k gate diele...
Electronic devices that make up 99% of the computer processor and memory market are based on silicon...
textThe continued scaling of Si CMOS devices has led to an increased attention to high-k gate diele...
The objective of this study is to gain understanding of MOS devices built on germanium. Ge PMOS tran...
As silicon MOSFETs have reached their saturation limits due to aggressive scaling, high mobility cha...
Recently, the best 65 nm Ge p-channel metal-oxide-semiconductor field-effect transistor (pMOSFET) pe...
textThis dissertation investigates the fabrication and characteristics of the metaloxide-semiconduct...
textThis dissertation investigates the fabrication and characteristics of the metaloxide-semiconduct...
textSince metal-oxide-semiconductor (MOS) device was first reported around 1959 and utilized for int...
The continued scaling of device dimensions in complementary metal oxide semiconductor (CMOS) technol...
The development and implementation of a metal gate technology (alloy, compound, or silicide) into me...
textSince metal-oxide-semiconductor (MOS) device was first reported around 1959 and utilized for int...
The development and implementation of a metal gate technology (alloy, compound, or silicide) into me...
The performance of strained silicon (Si) as the channel material for today’s metal-oxide-semiconduct...
textAfter the integrated circuit was invented in 1959, complementary metal-oxidesemiconductor (CMOS...
textThe continued scaling of Si CMOS devices has led to an increased attention to high-k gate diele...
Electronic devices that make up 99% of the computer processor and memory market are based on silicon...
textThe continued scaling of Si CMOS devices has led to an increased attention to high-k gate diele...
The objective of this study is to gain understanding of MOS devices built on germanium. Ge PMOS tran...
As silicon MOSFETs have reached their saturation limits due to aggressive scaling, high mobility cha...
Recently, the best 65 nm Ge p-channel metal-oxide-semiconductor field-effect transistor (pMOSFET) pe...
textThis dissertation investigates the fabrication and characteristics of the metaloxide-semiconduct...
textThis dissertation investigates the fabrication and characteristics of the metaloxide-semiconduct...
textSince metal-oxide-semiconductor (MOS) device was first reported around 1959 and utilized for int...
The continued scaling of device dimensions in complementary metal oxide semiconductor (CMOS) technol...
The development and implementation of a metal gate technology (alloy, compound, or silicide) into me...
textSince metal-oxide-semiconductor (MOS) device was first reported around 1959 and utilized for int...
The development and implementation of a metal gate technology (alloy, compound, or silicide) into me...
The performance of strained silicon (Si) as the channel material for today’s metal-oxide-semiconduct...