Your search keyword '"J.T.-C. Lee"' showing total 6 results

1. The Vertical Replacement-Gate (VRG) MOSFET: a 50-nm vertical MOSFET with lithography-independent gate length

Author

J.M. Hergenrother, D. Monroe, F.P. Klemens, A. Komblit, G.R. Weber, W.M. Mansfield, M.R. Baker, F.H. Baumann, K.J. Bolan, J.E. Bower, N.A. Ciampa, R.A. Cirelli, J.I. Colonell, D.J. Eaglesham, J. Frackoviak, H.J. Gossmann, M.L. Green, S.J. Hillenius, C.A. King, R.N. Kleiman, W.Y.C. Lai, J.T.-C. Lee, R.C. Liu, H.L. Maynard, M.D. Morris, S.-H. Oh, C.-S. Pai, C.S. Rafferty, J.M. Rosamilia, T.W. Sorsch, and H.-H. Vuong

Subjects

Scanning probe microscopy, Planar, Materials science, Gate oxide, business.industry, MOSFET, Electrical engineering, Optoelectronics, Short-channel effect, Diffusion (business), business, Capacitance, Lithography

Abstract

We have fabricated and demonstrated a new device called the Vertical Replacement-Gate (VRG) MOSFET. This is the first MOSFET ever built that combines (1) a gate length controlled precisely through a deposited film thickness, independently of lithography and etch, and (2) a high-quality gate oxide grown on a single-crystal Si channel. In addition to this unique combination, the VRG-MOSFET includes a self-aligned S/D formed by solid source diffusion (SSD) and small parasitic overlap, junction, and S/D capacitances. The drive current per /spl mu/m of coded width is significantly higher than that of advanced planar MOSFETs because each rectangular device pillar (with a thickness of minimum lithographic dimension) contains two MOSFETs driving in parallel. All of this is achieved using current manufacturing methods, materials, and tools, and competitive devices with 50-nm gate lengths (L/sub G/) have been demonstrated without advanced lithography.

Published

2003

2. A boron-retarding and high interface quality thin gate dielectric for deep-submicron devices

Author

K. Krisch, L. Manchanda, Y.O. Kim, R.C. Kistler, R. Storz, Martin L. Green, N. Moriya, D.M. Boulin, W. Mansfields, H. S. Luftman, J.T.-C. Lee, G.R. Weber, Leonard C. Feldman, and F. Klemens

Subjects

Materials science, Fabrication, business.industry, Gate dielectric, chemistry.chemical_element, Chemical vapor deposition, Dielectric, chemistry, Electronic engineering, Optoelectronics, business, Boron, Layer (electronics), NMOS logic, Deposition (law)

Abstract

We report the fabrication and device characteristics of a 50 /spl Aring/ thick dual-layer gate dielectric with high interface quality (D/sub it/ and Q/sub f/ /spl sim/10/sup 10/ cm/sup 2/) and capable of retarding boron penetration. This dual-layer dielectric is formed by low temperature CVD deposition of a /spl sim/40 /spl Aring/ thick oxynitride layer, through which slow O/sub 2/ diffusion is used to grow a /spl sim/10 /spl Aring/ thick SiO/sub 2/ at the interface. The small thickness of the SiO/sub 2/ layer reduces the oxidation time at high temperature, thus reducing the required thermal budget. The top oxynitride retards boron penetration and the thin SiO/sub 2/ layer provides a high quality interface. The channel mobility of NMOS devices with this dual dielectric is equal to the mobility of devices with a RTO dielectric grown at 950/spl deg/C. >

Published

2002

3. Low leakage, ultra-thin gate oxides for extremely high performance sub-100 nm nMOSFETs

Author

G. Timp, A. Agarwal, F.H. Baumann, T. Boone, M. Buonanno, R. Cirelli, V. Donnelly, M. Foad, D. Grant, M. Green, H. Gossmann, S. Hillenius, J. Jackson, D. Jacobson, R. Kleiman, A. Komblit, F. Klemens, J.T.-C. Lee, W. Mansfield, S. Moccio, A. Murrell, M. O'Malley, J. Rosamilia, J. Sapjeta, P. Silverman, T. Sorsch, W.W. Tai, D. Tennant, H. Vuong, and B. Weir

Subjects

Materials science, business.industry, Gate oxide, Transconductance, MOSFET, Electrical engineering, Gate leakage current, Optoelectronics, Low leakage, Time-dependent gate oxide breakdown, High current, business

Abstract

Reports measurements of the DC characteristics of sub-100 nm nMOSFETs that employ low leakage ultra-thin gate oxides only 1-2 nm thick to achieve high current drive capability and transconductance. We demonstrate that I/sub Dsat//spl ap/1.8 mA//spl mu/m can be achieved with a 60 nm gate at 1.5 V using a 1.3-1.4 nm gate oxide with a gate leakage current less than 20 nA//spl mu/m/sup 2/. Furthermore, we find that I/sub Dsat/ deteriorates for gate oxides thicker or thinner than this.

Published

2002

4. 50 nm Vertical Replacement-Gate (VRG) pMOSFETs

Author

J. Rosamilia, Frieder H. Baumann, Rafael N. Kleiman, T. Boone, Sang Hyun Oh, Steven James Hillenius, J. P. Garno, J. Frackoviak, J.L. Grazul, K. Short, R. Cirelli, D. Barr, E. Ferry, N.A. Ciampa, James D. Plummer, K. Bolan, G. R. Weber, G.D. Wilk, M.R. Baker, R.W. Johnson, H.-J. Gossmann, John Michael Hergenrother, Conor S. Rafferty, Allen G. Timko, J.F. Miner, F. Klemens, Anthony T. Fiory, Avi Kornblit, Martin L. Green, D. J. Eaglesham, J.T.-C. Lee, M.D. Morris, Don Monroe, R.C. Keller, William M. Mansfield, T. Nigam, C. A. King, and T.W. Sorsch

Subjects

Ion implantation, Materials science, business.industry, Gate oxide, Doping, MOSFET, Electrical engineering, Pillar, Optoelectronics, business, Key features

Abstract

We present the first p-channel Vertical Replacement-Gate (VRG) MOSFETs. Like the VRG-nMOSFETs demonstrated last year, these devices show promise as a successor to planar MOSFETs for highly-scaled ULSI. Our pMOSFETs retain the key features of the nMOSFETs and add channel doping by ion implantation and raised source/drain extensions (SDEs). We have significantly improved the core VRG process to provide high-performance devices with gate lengths of 100 nm and below. Since both sides of the device pillar drive in parallel, the drive current per /spl mu/m of coded width can far exceed that of planar MOSFETs. Our 100 nm VRG-pMOSFETs with t/sub ox/=25 /spl Aring/ drive 615 /spl mu/A//spl mu/m at 1.5 V with I/sub OFF/=8 nA//spl mu/m-80% more drive than specified in the 1999 ITRS Roadmap at the same I/sub OFF/. We demonstrate 50 nm VRG-pMOSFETs with t/sub ox/=25 /spl Aring/ that approach the 1.0 V roadmap target of I/sub ON/=350 /spl mu/A//spl mu/m at I/sub OFF/=20 nA//spl mu/m without the need for a hyperthin (

Published

2002

5. SALVO process for sub-50 nm low-V/sub T/ replacement gate CMOS with KrF lithography

Author

R. Cirelli, D. Barr, H.-H. Vuang, E.J. Lloyd, J.T.-C. Lee, M.R. Baker, C.P. Chang, E. Ferry, M. Frei, J.F. Miner, A. Kornbllit, T.W. Sorsch, M. Bude, S.N. Rogers, J.L. Grazul, C.S. Pai, Rafael N. Kleiman, William M. Mansfield, K. Bolan, F.P. Klemens, and Frieder H. Baumann

Subjects

Materials science, Fabrication, business.industry, Process (computing), Nanotechnology, law.invention, Controllability, Ion implantation, CMOS, Etching (microfabrication), law, Optoelectronics, Photolithography, business, Lithography

Abstract

We present the SALVO CMOS process, first device data and simulation study with the following features: (1) self-aligned local channel implants for SCE reduction; (2) sub-50 nm fabrication using only current production tools; (3) replacement gate with dual-polysilicon for low V/sub T/; (4) low aspect-ratio gates with CD insensitive to lithography and etch profile variability. The first demonstration of SALVO process shows it is a viable candidate for future ULSI CMOS production, in view of its versatility, controllability and compatibility.

Published

2002

6. 50 nm vertical replacement-gate (VRG) nMOSFETs with ALD HfO/sub 2/ and Al/sub 2/O/sub 3/ gate dielectrics

Author

Steven James Hillenius, J. Rosamilia, J.L. Grazul, M.R. Baker, F.P. Klemens, N.A. Ciampa, C. Werkhoven, J.T.-C. Lee, P. Kalavade, B. Busch, David A. Muller, K. Short, C. A. King, T. Boone, Eric Shero, G.D. Wilk, B. J. Sapjeta, M. Mazanec, M.D. Morris, K. Steiner, A. Kornblit, R.W. Johnson, E. Ferry, Christophe F. Pomarede, P.J. Silverman, D. C. Jacobson, J.F. Miner, William M. Mansfield, Sang Hyun Oh, T.W. Sorsch, John Michael Hergenrother, R.C. Keller, H. W. Krautter, Martin L. Green, Anthony T. Fiory, Don Monroe, M. Bude, Paul M. Voyles, Michael Eugene Givens, and T. Nigam

Subjects

Materials science, business.industry, Transistor, Oxide, Electrical engineering, Chemical vapor deposition, Dielectric, law.invention, Amorphous solid, chemistry.chemical_compound, chemistry, law, Electrode, MOSFET, Optoelectronics, business, Leakage (electronics)

Abstract

We have integrated HfO/sub 2/ and Al/sub 2/O/sub 3/ gate dielectrics grown by atomic layer chemical vapor deposition (ALD) with poly-Si gate electrodes in the vertical replacement-gate (VRG) MOSFET geometry. These transistors are among the first reported with ALD HfO/sub 2/ gate dielectrics, and have HfO/sub 2/ target equivalent oxide thicknesses (tEOT's) down to 13 /spl Aring/. The poly-crystalline HfO/sub 2/ films in these VRG nMOSFETs exhibit extremely low gate leakage (GL) current densities of J/sub G/ /spl sim/ 10/sup -7/ A/cm/sup 2/ at V/sub G/-V/sub T,Long/ = 0.6 V for 15 /spl Aring/ tEOT devices. This indicates that amorphous gate dielectrics may not be necessary to meet GL requirements. HfO/sub 2/ devices with 50 nm gate length L/sub G/ exhibit drive currents [normalized by the coded width W/sub C/] of 490 /spl mu/A//spl mu/m for 1 V operation (overdrive V/sub GS/-V/sub T/ = 0.6 V) with good short-channel performance. These results demonstrate that ALD is compatible with the demanding VRG geometry, thereby illustrating that it should be well-suited to essentially any novel device structure built with Si-compatible materials.

Published

2001