Mark Y. Liu

A 65nm logic technology featuring 35nm gate lengths, enhanced channel strain, 8 Cu interconnect layers, low-k ILD and 0.57 /spl mu/m/sup 2/ SRAM cell

A 65nm generation logic technology with 1.2nm physical gate oxide, 35nm gate length, enhanced channel strain, NiSi, 8 layers of Cu interconnect, and low-k ILD for dense high performance logic is presented. Transistor gate length is scaled down to 35nm while not scaling the gate oxide as a means to improve performance and reduce power. Increased NMOS and PMOS drive currents are achieved by enhanced channel strain and junction engineering. 193nm lithography along with APSM mask technology is used on critical layers to provide aggressive design rules and a 6-T SRAM cell size of 0.57/spl mu/m/sup 2/. Process yield, performance and reliability are demonstrated on a 70 Mbit SRAM test vehicle with >0.5 billion transistors.

A 14nm logic technology featuring 2 nd -generation FinFET, air-gapped interconnects, self-aligned double patterning and a 0.0588 µm 2 SRAM cell size

A 14nm logic technology using 2nd-generation FinFET transistors with a novel subfin doping technique, self-aligned double patterning (SADP) for critical patterning layers, and air-gapped interconnects at performance-critical layers is described. The transistors feature rectangular fins with 8nm fin width and 42nm fin height, 4th generation high-k metal gate, and 6th-generation strained silicon, resulting in the highest drive currents yet reported for 14nm technology. This technology is in high-volume manufacturing.

High performance 32nm logic technology featuring 2 nd generation high-k + metal gate transistors

A 32nm logic technology for high performance microprocessors is described. 2nd generation high-k + metal gate transistors provide record drive currents at the tightest gate pitch reported for any 32nm or 28nm logic technology. NMOS drive currents are 1.62mA/um Idsat and 0.231mA/um Idlin at 1.0V and 100nA/um Ioff. PMOS drive currents are 1.37mA/um Idsat and 0.240mA/um Idlin at 1.0V and 100nA/um Ioff. The impact of SRAM cell and array size on Vccmin is reported.

A 32nm logic technology featuring 2 nd -generation high-k + metal-gate transistors, enhanced channel strain and 0.171μm 2 SRAM cell size in a 291Mb array

A 32 nm generation logic technology is described incorporating 2nd-generation high-k + metal-gate technology, 193 nm immersion lithography for critical patterning layers, and enhanced channel strain techniques. The transistors feature 9 Aring EOT high-k gate dielectric, dual band-edge workfunction metal gates, and 4th-generation strained silicon, resulting in the highest drive currents yet reported for NMOS and PMOS. Process yield, performance and reliability are demonstrated on a 291 Mbit SRAM test vehicle, with 0.171 mum2 cell size, containing >1.9 billion transistors.

An advanced low power, high performance, strained channel 65nm technology

An advanced low power, strained channel, dual poly CMOS 65nm technology with enhanced transistor performance is presented. At 1V and off current of 100nA/mum, transistors have record currents of 1.21mA/mum and 0.71mA/mum for NMOS and PMOS respectively. This industry leading 65nm technology is currently in high volume manufacturing

Technology options for 22nm and beyond

This paper explores the challenges facing the 22nm process generation and beyond. CMOS transistor architectures such as ultra-thin body, FinFET, and nanowire will be compared and contrasted. Mobility enhancements such as channel stress, alternative orientations, and exotic materials will be explored. Resistance challenges will be reviewed in relation to key process techniques such as silicidation, implantation and anneal. Capacitance challenges with traditional and new architectures will be discussed in light of new materials and processing techniques. The impact of new transistor architectures and enhanced channel materials on traditional junction engineering solutions will be summarized.

Transistor aging and reliability in 14nm tri-gate technology

This paper details the transistor aging and gate oxide reliability of Intels 14nm process technology. This technology introduces Intels 2nd generation tri-gate transistor and the 4th generation of high-κ dielectrics and metal-gate electrodes. The reliability metrics reported here highlight reliability gains attained through transistor optimizations as well as intrinsic challenges from device scaling.

Modeling of NMOS performance gains from edge dislocation stress

Stress from edge dislocations introduced by solid phase epitaxial regrowth increases as gate pitch is scaled, reaching 1GPa at 100nm gate pitch. This scaling trend makes edge dislocations attractive for future technology nodes, as stress from epitaxial and deposited film stressors reduces as pitch is scaled (1,2). We show a gate last flow is best for maximizing the dislocation stress, and the stress varies with layout and topography. We arrive at these results by the application of the finite element method to model the dislocation stress.