Micro-Raman Study of Stress Distribution Generated in Silicon During Proximity Rapid Thermal Diffusion

M. Nolan; T. Perova; R.A. Moore; C.J. Moore; K. Berwick; H.S. Gamble

Micro-Raman Study of Stress Distribution Generated in Silicon During Proximity Rapid Thermal Diffusion

M. Nolan, T. Perova, R.A. Moore, C.J. Moore, K. Berwick, H.S. Gamble

Technological University Dublin

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

Abstract

Micro-Raman spectroscopy has been used for analysing the thermally induced stress distributions in silicon wafers after proximity rapid thermal diffusion (RTD). A compressive stress was found on the whole silicon wafer after 15 s RTD. After 165 s RTD, the distribution of the stress across the wafer was found to be different: compressive at the edge and tensile at the middle. Thermal stress was relieved in the RTD wafers via slip dislocations. These slip dislocations were observed in the product wafers using optical microscopy. Slip lines propagated from the wafer edge to the wafer centre in eight preferred positions of maximum induced stress. The thermally induced stress and the slip dislocation density increased with time spent at the RTD peak temperature.

Original language	English
Pages (from-to)	168-172
Number of pages	5
Journal	Materials Science and Engineering: B
Volume	73
Issue number	1
Publication status	Published - 3 Apr 2000

Keywords

proximity rapid thermal diffusion
compressive stress
thermal stress
slip dislocations
optical microscopy
slip lines
thermally induced stress
slip dislocation density

Cite this

@article{03f4eed32c5a4854a42ea43cce06f079,

title = "Micro-Raman Study of Stress Distribution Generated in Silicon During Proximity Rapid Thermal Diffusion",

abstract = "Micro-Raman spectroscopy has been used for analysing the thermally induced stress distributions in silicon wafers after proximity rapid thermal diffusion (RTD). A compressive stress was found on the whole silicon wafer after 15 s RTD. After 165 s RTD, the distribution of the stress across the wafer was found to be different: compressive at the edge and tensile at the middle. Thermal stress was relieved in the RTD wafers via slip dislocations. These slip dislocations were observed in the product wafers using optical microscopy. Slip lines propagated from the wafer edge to the wafer centre in eight preferred positions of maximum induced stress. The thermally induced stress and the slip dislocation density increased with time spent at the RTD peak temperature.",

keywords = "proximity rapid thermal diffusion, compressive stress, thermal stress, slip dislocations, optical microscopy, slip lines, thermally induced stress, slip dislocation density",

author = "M. Nolan and T. Perova and R.A. Moore and C.J. Moore and K. Berwick and H.S. Gamble",

year = "2000",

month = apr,

day = "3",

language = "English",

volume = "73",

pages = "168--172",

journal = "Materials Science and Engineering: B",

issn = "0921-5107",

publisher = "Elsevier Ltd.",

number = "1",

}

TY - JOUR

T1 - Micro-Raman Study of Stress Distribution Generated in Silicon During Proximity Rapid Thermal Diffusion

AU - Nolan, M.

AU - Perova, T.

AU - Moore, R.A.

AU - Moore, C.J.

AU - Berwick, K.

AU - Gamble, H.S.

PY - 2000/4/3

Y1 - 2000/4/3

N2 - Micro-Raman spectroscopy has been used for analysing the thermally induced stress distributions in silicon wafers after proximity rapid thermal diffusion (RTD). A compressive stress was found on the whole silicon wafer after 15 s RTD. After 165 s RTD, the distribution of the stress across the wafer was found to be different: compressive at the edge and tensile at the middle. Thermal stress was relieved in the RTD wafers via slip dislocations. These slip dislocations were observed in the product wafers using optical microscopy. Slip lines propagated from the wafer edge to the wafer centre in eight preferred positions of maximum induced stress. The thermally induced stress and the slip dislocation density increased with time spent at the RTD peak temperature.

AB - Micro-Raman spectroscopy has been used for analysing the thermally induced stress distributions in silicon wafers after proximity rapid thermal diffusion (RTD). A compressive stress was found on the whole silicon wafer after 15 s RTD. After 165 s RTD, the distribution of the stress across the wafer was found to be different: compressive at the edge and tensile at the middle. Thermal stress was relieved in the RTD wafers via slip dislocations. These slip dislocations were observed in the product wafers using optical microscopy. Slip lines propagated from the wafer edge to the wafer centre in eight preferred positions of maximum induced stress. The thermally induced stress and the slip dislocation density increased with time spent at the RTD peak temperature.

KW - proximity rapid thermal diffusion

KW - compressive stress

KW - thermal stress

KW - slip dislocations

KW - optical microscopy

KW - slip lines

KW - thermally induced stress

KW - slip dislocation density

UR - https://www.scopus.com/pages/publications/0033876212

M3 - Conference article

SN - 0921-5107

VL - 73

SP - 168

EP - 172

JO - Materials Science and Engineering: B

JF - Materials Science and Engineering: B

IS - 1

ER -

Micro-Raman Study of Stress Distribution Generated in Silicon During Proximity Rapid Thermal Diffusion

Abstract

Keywords

Fingerprint

Cite this