Application of Ge50Te50/Zn15Sb85 nanocomposite multilayer films in high thermal stability and low power phase change memory

Zhu Xiao-Qin; Hu Yi-Feng

doi:10.7498/aps.69.20200502

Abstract

The Ge₅₀Te₅₀/Zn₁₅Sb₈₅ nanocomposite multilayer films are prepared by the magnetron sputtering. The variation of resistance with temperature and with crystallization activation energy is studied. The multilayer structure of the section before and after the crystallization for Ge₅₀Te₅₀/Zn₁₅Sb₈₅ nanocomposite multilayer film is compared by transmission electron microscope. The phase change memory device based on [GT(7nm)/ZS(3nm)]₅ is manufactured, and the electrical performance is measured. The fast switching speed, low operating power consumption, and good cycling performance are achieved for Ge₅₀Te₅₀/Zn₁₅Sb₈₅. Ge₅₀Te₅₀/Zn₁₅Sb₈₅, which is a kind of nanocomposite multilayer film, a promising phase change storage material with high thermal stability and low power consumption.

Keywords:

Authors and contacts

School of Mathematics and Physics, Jiangsu University of Technology, Changzhou 213001, China

Corresponding author: Hu Yi-Feng, hyf@jsut.edu.cn

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References

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Cited By

图 1 GT/ZS多层复合纳米薄膜的电阻随温度的变化

Figure 1. Resistance vs. temperature of GT/ZS nanocomposite multilayer films.

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图 2 GT/ZS多层复合纳米薄膜的失效时间随1/(k_BT)的变化曲线

Figure 2. Failure time vs. 1/(k_BT) GT/ZS nanocomposite multilayer films.

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图 3 [GT(7 nm)/ZS(3 nm)]₅多层复合薄膜的截面高分辨透射电子显微镜图像(a)(b)和选取电子衍射图(c) (d)　(a), (c) 非晶态; (b), (d) 晶态

Figure 3. The high-resolution transmission electron microscopy images (a) (b) and selected area electron diffraction diagrams (c) (d) of section for [GT(7 nm)/ZS(3 nm)]₅ multilayer composite film: (a), (c) Amorphous; (b), (d) crystalline.

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图 4 基于[GT(7 nm)/ZS(3 nm)]₅多层复合薄膜的PCM器件的(a) PCM器件单元的截面示意图, (b) I-V曲线, (c) R-V曲线, (d)循环特性曲线

Figure 4. (a) The cross section diagram of PCM devices cell; the curves of (b) I-V, (c) R-V, (d) cycling performance for PCM device based on [GT(7 nm)/ZS(3 nm)]₅ multilayer composite film.

DownLoad: Full-Size Img PowerPoint

map

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[5]	Wang Z R, Joshi S, Savelev S E, Jiang H, Midya R, Lin P, Hu M, Ge N, Strachan J P, Li Z Y, Wu Q, Barne M, Li G L, Xin H L, Williams R S, Xia Q F, Yang J J 2017 Nat. Mater. 16 101 Google Scholar
[6]	Xu M, Li B, Xu K, Tong H, Cheng X, Xu M, Miao X 2019 Phys. Chem. Chem. Phys. 21 4494 Google Scholar
[7]	Guo T Q, Song S N, Zheng Y H, Xue Y, Yan S, Liu Y X, Li T, Liu G Y, Wang Y, Song Z T, Qi M, Feng S L 2018 Nanotechnology 29 505710 Google Scholar
[8]	Hu Y F, Qiu Q Q, Zhu X Q, Lai T S 2020 Appl. Surf. Sci. 505 144337 Google Scholar
[9]	Zheng L, Song W X, Song Z T, Song S N 2019 ACS Appl. Mater. Interfaces 11 45885 Google Scholar
[10]	Okabe K L, Sood A, Yalon E, Neumann C M, Asheghi M, Pop E, Goodson K E, Wong H S P 2019 J. Appl. Phys. 125 184501 Google Scholar
[11]	Lu Y G, Wang M, Song S N, Xia M J, Jia Y, Shen X, Wang G X, Dai S X, Song Z T 2016 Appl. Phys. Lett. 109 8181
[12]	Zhou L J, Yang Z, Wang X J, Qian H, Xu M, Cheng X M, Tong H, Miao X S 2019 Adv. Electron. Mater. 5 1900781
[13]	Li Z G, Lu Y G, Wang M, Shen X, Zhang X H, Song S N, Song Z T 2018 J. Non-Cryst. Solids. 481 110 Google Scholar
[14]	Wu W H, Chen S Y, Zhai J W, Liu X Y, Lai T S, Song S N, Song Z T 2017 Nanotechnology 28 405206 Google Scholar
[15]	Zhang J H, Hu Y F, Zhang R, Zou H, Xue J Z, Zhu X Q, Song S N, Song Z T 2019 Ecs J. Solid State Sc. 8 563
[16]	Zhang R, Hu Y F, Chou Q Q, Lai T S, Zhu X Q 2019 J. Alloys Compd. 798 342 Google Scholar
[17]	He Z F, Chen S Y, Wu W H, Zhai J W, Song S N, Song Z T 2017 Appl. Phys. Express 10 055504 Google Scholar
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Vol. 69, Issue 14 - 2020-07-20

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Application of Ge₅₀Te₅₀/Zn₁₅Sb₈₅ nanocomposite multilayer films in high thermal stability and low power phase change memory