Channel strain measurement of Si1-xCx structures: Effects of gate length, source/drain length, and source/drain elevation

Sun Wook Kim; Dae Seop Byun; Mijin Jung; Saurabh Chopra; Yihwan Kim; Jae Hyun Kim; Seung Min Han; Dae Hong Ko; Hoo Jeong Lee

doi:10.7567/APEX.6.066601

Channel strain measurement of Si_1-xC_x structures: Effects of gate length, source/drain length, and source/drain elevation

Sun Wook Kim, Dae Seop Byun, Mijin Jung, Saurabh Chopra, Yihwan Kim, Jae Hyun Kim, Seung Min Han, Dae Hong Ko, Hoo Jeong Lee

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

This study examined the dimensional effects on the channel strain in transistor structures with epitaxial Si_1-xC_x stressors embedded in the source/drain region using both nanobeam diffraction and finite element simulations. The sizes of the gate and source/drain exerted a strong influence on the channel strain but in opposite directions: While declining linearly with decreasing source/drain length, the channel strain increases at an escalating rate with decreasing gate length. For source/drain elevation, its effects on the channel strain were found to be quite limited to the top surface region; however, this elevation method could be more effective for short-channel transistors.

Original language	English
Article number	066601
Journal	Applied Physics Express
Volume	6
Issue number	6
DOIs	https://doi.org/10.7567/APEX.6.066601
Publication status	Published - 2013 Jun

All Science Journal Classification (ASJC) codes

Engineering(all)
Physics and Astronomy(all)

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title = "Channel strain measurement of Si1-xCx structures: Effects of gate length, source/drain length, and source/drain elevation",

abstract = "This study examined the dimensional effects on the channel strain in transistor structures with epitaxial Si1-xCx stressors embedded in the source/drain region using both nanobeam diffraction and finite element simulations. The sizes of the gate and source/drain exerted a strong influence on the channel strain but in opposite directions: While declining linearly with decreasing source/drain length, the channel strain increases at an escalating rate with decreasing gate length. For source/drain elevation, its effects on the channel strain were found to be quite limited to the top surface region; however, this elevation method could be more effective for short-channel transistors.",

author = "Kim, {Sun Wook} and Byun, {Dae Seop} and Mijin Jung and Saurabh Chopra and Yihwan Kim and Kim, {Jae Hyun} and Han, {Seung Min} and Ko, {Dae Hong} and Lee, {Hoo Jeong}",

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AU - Kim, Sun Wook

AU - Byun, Dae Seop

AU - Jung, Mijin

AU - Chopra, Saurabh

AU - Kim, Yihwan

AU - Kim, Jae Hyun

AU - Han, Seung Min

AU - Ko, Dae Hong

AU - Lee, Hoo Jeong

PY - 2013/6

Y1 - 2013/6

N2 - This study examined the dimensional effects on the channel strain in transistor structures with epitaxial Si1-xCx stressors embedded in the source/drain region using both nanobeam diffraction and finite element simulations. The sizes of the gate and source/drain exerted a strong influence on the channel strain but in opposite directions: While declining linearly with decreasing source/drain length, the channel strain increases at an escalating rate with decreasing gate length. For source/drain elevation, its effects on the channel strain were found to be quite limited to the top surface region; however, this elevation method could be more effective for short-channel transistors.

AB - This study examined the dimensional effects on the channel strain in transistor structures with epitaxial Si1-xCx stressors embedded in the source/drain region using both nanobeam diffraction and finite element simulations. The sizes of the gate and source/drain exerted a strong influence on the channel strain but in opposite directions: While declining linearly with decreasing source/drain length, the channel strain increases at an escalating rate with decreasing gate length. For source/drain elevation, its effects on the channel strain were found to be quite limited to the top surface region; however, this elevation method could be more effective for short-channel transistors.

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Channel strain measurement of Si_1-xC_x structures: Effects of gate length, source/drain length, and source/drain elevation

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