Manufacturable multiple gate oxynitride thickness technology for system on a chip

C. H. Lee; H. F. Luan; S. C. Song; S. J. Lee; B. Evans; D. L. Kwong

Manufacturable multiple gate oxynitride thickness technology for system on a chip

C. H. Lee
, H. F. Luan
, S. C. Song
, S. J. Lee
, B. Evans
, D. L. Kwong

University of Texas at Austin

Research output: Contribution to journal › Conference article › peer-review

4 Scopus citations

Abstract

System-on-a-chip has received considerable attention for future CMOS technology. One of the major technological requirements of system-on-a-chip is the ability to grow multiple gate oxide thickness simultaneously on a wafer with significantly differential oxide growth rate. System-on-a-chip has become the trend of future CMOS technologies. Combining logic circuits and several different memory elements in one chip with multiple supply voltages requires the use of multiple gate oxides or oxynitride thicknesses on the same wafer. In this paper, a novel approach to realize >500% difference in oxide growth rate is demonstrated for the first time using Vertical High Pressure (VHP) oxidation (15-25atm 750 approx. 800°C) and N implantation (1E14-3E15 atoms/cm²).

Original language	English
Pages (from-to)	491-494
Number of pages	4
Journal	Technical Digest - International Electron Devices Meeting
State	Published - 1999
Externally published	Yes
Event	1999 IEEE International Devices Meeting (IEDM) - Washington, DC, USA Duration: 5 Dec 1999 → 8 Dec 1999

Cite this

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title = "Manufacturable multiple gate oxynitride thickness technology for system on a chip",

abstract = "System-on-a-chip has received considerable attention for future CMOS technology. One of the major technological requirements of system-on-a-chip is the ability to grow multiple gate oxide thickness simultaneously on a wafer with significantly differential oxide growth rate. System-on-a-chip has become the trend of future CMOS technologies. Combining logic circuits and several different memory elements in one chip with multiple supply voltages requires the use of multiple gate oxides or oxynitride thicknesses on the same wafer. In this paper, a novel approach to realize >500\% difference in oxide growth rate is demonstrated for the first time using Vertical High Pressure (VHP) oxidation (15-25atm 750 approx. 800°C) and N implantation (1E14-3E15 atoms/cm2).",

author = "Lee, \{C. H.\} and Luan, \{H. F.\} and Song, \{S. C.\} and Lee, \{S. J.\} and B. Evans and Kwong, \{D. L.\}",

year = "1999",

language = "English",

pages = "491--494",

journal = "Technical Digest - International Electron Devices Meeting",

issn = "0163-1918",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

note = "1999 IEEE International Devices Meeting (IEDM) ; Conference date: 05-12-1999 Through 08-12-1999",

}

TY - JOUR

T1 - Manufacturable multiple gate oxynitride thickness technology for system on a chip

AU - Lee, C. H.

AU - Luan, H. F.

AU - Song, S. C.

AU - Lee, S. J.

AU - Evans, B.

AU - Kwong, D. L.

PY - 1999

Y1 - 1999

N2 - System-on-a-chip has received considerable attention for future CMOS technology. One of the major technological requirements of system-on-a-chip is the ability to grow multiple gate oxide thickness simultaneously on a wafer with significantly differential oxide growth rate. System-on-a-chip has become the trend of future CMOS technologies. Combining logic circuits and several different memory elements in one chip with multiple supply voltages requires the use of multiple gate oxides or oxynitride thicknesses on the same wafer. In this paper, a novel approach to realize >500% difference in oxide growth rate is demonstrated for the first time using Vertical High Pressure (VHP) oxidation (15-25atm 750 approx. 800°C) and N implantation (1E14-3E15 atoms/cm2).

AB - System-on-a-chip has received considerable attention for future CMOS technology. One of the major technological requirements of system-on-a-chip is the ability to grow multiple gate oxide thickness simultaneously on a wafer with significantly differential oxide growth rate. System-on-a-chip has become the trend of future CMOS technologies. Combining logic circuits and several different memory elements in one chip with multiple supply voltages requires the use of multiple gate oxides or oxynitride thicknesses on the same wafer. In this paper, a novel approach to realize >500% difference in oxide growth rate is demonstrated for the first time using Vertical High Pressure (VHP) oxidation (15-25atm 750 approx. 800°C) and N implantation (1E14-3E15 atoms/cm2).

UR - https://www.scopus.com/pages/publications/0033345378

M3 - Conference article

AN - SCOPUS:0033345378

SN - 0163-1918

SP - 491

EP - 494

JO - Technical Digest - International Electron Devices Meeting

JF - Technical Digest - International Electron Devices Meeting

T2 - 1999 IEEE International Devices Meeting (IEDM)

Y2 - 5 December 1999 through 8 December 1999

ER -

Manufacturable multiple gate oxynitride thickness technology for system on a chip

Abstract

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