Novel Capacitor Structure Using Sidewall Spacer for Highly Reliable Ferroelectric Random Access Memory Device
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概要
- 論文の詳細を見る
Since ferroelectric capacitors prepared by 1-mask etching are degraded after the etching, we systematically investigated the origin of the degradation. It was found that the major degradation originates from the formation of the nonstoichiometric and amorphorized Pb(ZrxTi1-x)O3 (PZT) layer on the sidewall of the PZT film during etching of the bottom electrode (BE). Therefore, to eliminate the undesired etch-damaged layer, we developed a novel etching technology using a ferroelectric (FE) sidewall spacer, which results in the enhancement of the remnant polarization after completing the capacitor etching process. Using the novel FE sidewall spacer, the sensing margin of bit-line-developed voltage was improved to 400 mV, which can guarantee highy reliable high-density ferroelectric random access memory (FRAM) devices.
- 2004-04-15
著者
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Kim Kinam
Advanced Technology Development 2 Memory Device Business Samsung Electronics Co.
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JANG Nak-Won
Department of Electrical & Electronics Engineering, Korea Maritime University
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KANG Seung-Kuk
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics C
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JOO Seok-Ho
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics C
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Park Jung-hoon
Advanced Technology Development Team Memory Division Semiconductor Business Samsung Electronics Co.
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Lee Sung-young
Advanced Technology Development Team Memory Division Semiconductor Business Samsung Electronics Co.
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Joo Heung-jin
Advanced Technology Development Team Memory Division Semiconductor Business Samsung Electronics Co.
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Song Yoon-jong
Advanced Technology Development Semiconductor R&d Centre Samsung Electronics Co. Ltd.
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Kim Hyun-ho
Advanced Technology Development Team Memory Division Semiconductor Business Samsung Electronics Co.
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Jang Nak-Won
Department of Electrical & Electronics Engineering, Korea Maritime University, Busan, Korea
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Song Yoon-Jong
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Lee Sung-Young
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Park Jung-Hoon
Advanced Technology Development 2 Team, Semiconductor R&D Center, Memory Division, Samsung Electronics Co., Ltd., San 24, Nongseo-Dong, Kiheung-Gu, Yongin-Si, Kyungki-Do 446-711, Korea
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Park Jung-Hoon
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Kim Kinam
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Kang Seung-Kuk
Advanced Technology Development 2 Team, Semiconductor R&D Center, Memory Division, Samsung Electronics Co., Ltd., San 24, Nongseo-Dong, Kiheung-Gu, Yongin-Si, Kyungki-Do 446-711, Korea
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Joo Seok-Ho
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Kim Hyun-Ho
Advanced Technology Development 2 Team, Semiconductor R&D Center, Memory Division, Samsung Electronics Co., Ltd., San 24, Nongseo-Dong, Kiheung-Gu, Yongin-Si, Kyungki-Do 446-711, Korea
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Kim Hyun-Ho
Advanced Technology Development Team, Memory Division, Semiconductor Business, Samsung Electronics Co. Ltd., San #24, Nongseo-Li, Kiheung-Eup, Yongin-Si, Kyungki-Do, Korea
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Joo Heung-Jin
Advanced Technology Development 2 Team, Semiconductor R&D Center, Memory Division, Samsung Electronics Co., Ltd., San 24, Nongseo-Dong, Kiheung-Gu, Yongin-Si, Kyungki-Do 446-711, Korea
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