Scalability of Phase Change Materials in Nanostructure Template

Wei Zhang; Biyun L. Jackson; Ke Sun; Jae Young Lee; Shyh Jer Huang; Hsin Chieh Yu; Sheng Po Chang; Shoou Jinn Chang; Ya Hong Xie

doi:10.1155/2015/253296

Scalability of Phase Change Materials in Nanostructure Template

Wei Zhang
, Biyun L. Jackson
, Ke Sun
, Jae Young Lee
, Shyh Jer Huang
, Hsin Chieh Yu
, Sheng Po Chang
, Shoou Jinn Chang
, Ya Hong Xie

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

1 Citation (Scopus)

Abstract

The scalability of Ine one of the phase change materials, is investigated. By depositing the material onto a nanopatterned substrate, individual Inenanoclusters are confined in the nanosize pits with well-defined shape and dimension permitting the systematic study of the ultimate scaling limit of its use as a phase change memory element. Ineof progressively smaller volume is heated inside a transmission electron microscope operating in diffraction mode. The volume at which the amorphous-crystalline transition can no longer be observed is taken as the ultimate scaling limit, which is approximately 5 nm³ for Ine The physics for the existence of scaling limit is discussed. Using phase change memory elements in memory hierarchy is believed to reduce its energy consumption because they consume zero leakage power in memory cells. Therefore, the phase change memory applications are of great importance in terms of energy saving.

Original language	English
Article number	253296
Journal	International Journal of Photoenergy
Volume	2015
DOIs	https://doi.org/10.1155/2015/253296
Publication status	Published - 2015

All Science Journal Classification (ASJC) codes

General Chemistry
Atomic and Molecular Physics, and Optics
Renewable Energy, Sustainability and the Environment
General Materials Science

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10.1155/2015/253296

Cite this

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title = "Scalability of Phase Change Materials in Nanostructure Template",

abstract = "The scalability of Ine one of the phase change materials, is investigated. By depositing the material onto a nanopatterned substrate, individual Inenanoclusters are confined in the nanosize pits with well-defined shape and dimension permitting the systematic study of the ultimate scaling limit of its use as a phase change memory element. Ineof progressively smaller volume is heated inside a transmission electron microscope operating in diffraction mode. The volume at which the amorphous-crystalline transition can no longer be observed is taken as the ultimate scaling limit, which is approximately 5 nm3 for Ine The physics for the existence of scaling limit is discussed. Using phase change memory elements in memory hierarchy is believed to reduce its energy consumption because they consume zero leakage power in memory cells. Therefore, the phase change memory applications are of great importance in terms of energy saving.",

author = "Wei Zhang and Jackson, \{Biyun L.\} and Ke Sun and Lee, \{Jae Young\} and Huang, \{Shyh Jer\} and Yu, \{Hsin Chieh\} and Chang, \{Sheng Po\} and Chang, \{Shoou Jinn\} and Xie, \{Ya Hong\}",

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year = "2015",

doi = "10.1155/2015/253296",

language = "English",

volume = "2015",

journal = "International Journal of Photoenergy",

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T1 - Scalability of Phase Change Materials in Nanostructure Template

AU - Zhang, Wei

AU - Jackson, Biyun L.

AU - Sun, Ke

AU - Lee, Jae Young

AU - Huang, Shyh Jer

AU - Yu, Hsin Chieh

AU - Chang, Sheng Po

AU - Chang, Shoou Jinn

AU - Xie, Ya Hong

PY - 2015

Y1 - 2015

N2 - The scalability of Ine one of the phase change materials, is investigated. By depositing the material onto a nanopatterned substrate, individual Inenanoclusters are confined in the nanosize pits with well-defined shape and dimension permitting the systematic study of the ultimate scaling limit of its use as a phase change memory element. Ineof progressively smaller volume is heated inside a transmission electron microscope operating in diffraction mode. The volume at which the amorphous-crystalline transition can no longer be observed is taken as the ultimate scaling limit, which is approximately 5 nm3 for Ine The physics for the existence of scaling limit is discussed. Using phase change memory elements in memory hierarchy is believed to reduce its energy consumption because they consume zero leakage power in memory cells. Therefore, the phase change memory applications are of great importance in terms of energy saving.

AB - The scalability of Ine one of the phase change materials, is investigated. By depositing the material onto a nanopatterned substrate, individual Inenanoclusters are confined in the nanosize pits with well-defined shape and dimension permitting the systematic study of the ultimate scaling limit of its use as a phase change memory element. Ineof progressively smaller volume is heated inside a transmission electron microscope operating in diffraction mode. The volume at which the amorphous-crystalline transition can no longer be observed is taken as the ultimate scaling limit, which is approximately 5 nm3 for Ine The physics for the existence of scaling limit is discussed. Using phase change memory elements in memory hierarchy is believed to reduce its energy consumption because they consume zero leakage power in memory cells. Therefore, the phase change memory applications are of great importance in terms of energy saving.

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SN - 1110-662X

VL - 2015

JO - International Journal of Photoenergy

JF - International Journal of Photoenergy

M1 - 253296

ER -

Scalability of Phase Change Materials in Nanostructure Template

Abstract

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