人工智能时代计算机加速全球沸腾的氧化物陶瓷大规模集成装置

International Journal of Ceramic Engineering & Science Pub Date : 2025-06-13 DOI:10.1002/ces2.70011

Shunpei Yamazaki, Tatsuya Onuki, Satoru Saito, Shoki Miyata, Kazuma Furutani, Kazuki Tsuda, Hiromichi Godo, Takanori Matsuzaki, Kenichi Okazaki, Hidekazu Miyairi, Motomu Kurata, Yasuhiro Jinbo, Fumito Isaka, Yuji Egi, Yoshinori Ando, Tsutomu Murakawa, Ryota Hodo, Toshikazu Ohno, Ryosuke Motoyoshi, Yuichi Yanagisawa, Yukinori Shima, Masami Jincho, Yasutaka Nakazawa, Masahiro Watanabe, Kayo Kumakura, Masataka Nakada, Ami Sato, Shinya Fukuzaki, Toshiki Sasaki, Nobuharu Ohsawa, Yuto Yakubo

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引用次数: 0

摘要

人工智能（AI）的快速发展和广泛使用被认为是导致全球沸腾的一个因素，这正在成为一个严重的社会问题。我们专注于具有极低的关闭状态电流（Ioff）（1 zA/µm至1 yA/µm）和17位数的非常大的开/关比的氧化物陶瓷，我们的目标是通过氧化物半导体（os）的大规模集成实现超低功耗的AI。包含氧化铟晶体（IO）作为通道材料的场效应晶体管（fet）表现出与含有氧化铟镓锌（IGZO）的场效应晶体管（fet）相当的关断电流（Ioff）和高于含有IGZO的场效应晶体管（fet）的导通电流（Ion）。单晶IO被证明是一种很有前途的材料，可以提高操作系统器件的性能并减少其特性的变化。本报告介绍了氧化物陶瓷使用的最新趋势。我们预计，这些技术的发展将在未来实现超低功耗的人工智能，这将是应对全球沸腾的重要补救措施。

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Oxide Ceramic Large-scale Integration Device for Putting the Brakes on Global Boiling Accelerated by Artificial Intelligence Age Computers

One factor that is considered to be a cause of global boiling, which is becoming a serious social problem, is the rapid progress and widespread use of artificial intelligence (AI). We focus on an oxide ceramic with an extremely low off-state current (I_off) of 1 zA/µm to 1 yA/µm and a very large on/off ratio of 17 digits, and we aim to achieve AI with an ultra-low power consumption using the large-scale integration of oxide semiconductors (OSs). Field effect transistors (FETs) that include crystal indium oxide (IO) as a channel material exhibit an off-state current (I_off) equivalent to that of the FETs that contain indium gallium zinc oxide (IGZO) and an on-state current (I_on) that is higher than that of the FETs that contain IGZO. Single crystal IO is shown to be a promising material for improving performance and reducing the variation in the characteristics of OS devices. This report introduces the latest trends in the use of oxide ceramics. We expect that the development of these technologies will achieve AI with ultra-low power consumption in the future, which will be an important remediation against global boiling.

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International Journal of Ceramic Engineering & Science

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