Molecular beam epitaxy growth of multilayer FeSe thin film on SrTiO3 (001)

Zhang Ma-Lin; Ge Jian-Feng; Duan Ming-Chao; Yao Gang; Liu Zhi-Long; Guan Dan-Dan; Li Yao-Yi; Qian Dong; Liu Can-Hua; Jia Jin-Feng

doi:10.7498/aps.65.127401

Abstract

Single-layer FeSe film grown on SrTiO3(001) surface (STO surface) by molecular beam epitaxy has aroused a great research boom ever since the discovery of its huge superconductive energy gap which indicates a possible critical temperature (Tc) higher than the liquid nitrogen temperature. The interface enhanced superconductivity with a Tc above 100 K is revealed in an in situ electrical transport measurement by using a four-point probe installed in a scanning tunneling microscope (STM). Consequent research interest in multi-layer FeSe films grown on STO surface is also increasing. The quality of thick FeSe film, however, has not been well studied yet in previous studies, although it is related to the sample properties including superconductivity. Here, reflection high-energy electron diffraction (RHEED) is used to monitor the growths of multi-layer FeSe thin films on STO surface under different growth conditions. Combing the RHEED results with STM observations taken at various FeSe coverages, we find that the intensity evolution of the RHEED pattern in the early growth stage can be well explained by the step density model but not by the widely known facet model. The intensity evolution of the FeSe(02) diffraction streak exhibits a single-peak oscillation in the growing of the first layer of FeSe. As the oscillation does not depend on the grazing angle of the high-energy electron beam, the FeSe(02) diffraction streak is very suitable for calibrating the FeSe growth rate. In contrast, the intensity of the specular spot exhibits different evolution pattern when the grazing angle of electron beam is changed. It is found in STM observations that only at an appropriate substrate temperature and a growth rate can the high-quality multi-layer FeSe films be grown on STO substrates. If the growth temperature is too high, the FeSe molecules nucleate into islands so that FeSe films with various thickness values eventually come into being on the STO surface. If the growth temperature is too low, a different phase of FeSe film is formed. The optimal growth temperature is in a range from 400 ℃ to 430 ℃, within which a two-layer FeSe film grown at a low rate (0.15 layer/min) coveres the whole STO surface with a negligible number of small FeSe islands. In contrast, a larger growth rate is necessary for growing thicker FeSe film. This is because FeSe islands tend to come into form at steps when the growth rate is too low, which is more distinct in a thicker FeSe film. An STM image of 80-layer FeSe film grown under an optimal condition, i.e., the substrate temperature of 420 ℃ and the growth rate of 2.3 layer/min, shows that it is in a perfect layer-by-layer growth mode. These experimental results are useful for growing high-quality multi-layer FeSe films on STO substrates, which could be critical for studying their physical properties and relevant physical phenomena.

Keywords:

FeSe /
reflection high-energy electron diffraction /
molecular beam epitaxy /
step-density

Authors and contacts

1.
Key Laboratory of Artificial Structures and Quantum Control (Ministry of Education), Department of Physics and Astronomy, Shanghai Jiao Tong University, Shanghai 200240, China;
2.
Collaborative Innovation Center of Advanced Microstructures, Nanjing 210093, China

Corresponding author: Liu Can-Hua, canhualiu@sjtu.edu.cn

Funds: Project supported by the National Basic Research Program of China (Grant Nos. 2013CB921902, 2012CB927401, 2011CB922202), the National Natural Science Foundation of China (Grant Nos. 11521404, 11134008, 11574201, 11574202, 11504230), and the Funds of Shanghai Committee of Science and Technology, China (Grant Nos. 15JC1402300, 14PJ1404600).

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[23]	Shin B, Leonard J P, McCamy J W, Aziz Michael J 2007 J. Vac. Sci. Technol. A 25 221
[24]	Okamoto H 1991 J. Phase. Equilib. Diff. 12 383
[25]	Ohring M 2001 Materials Science of Thin Films 7.6.1 (San Diego: Academic press) pp340-345
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[30]	Zhang W, Li Z, Li F, Zhang H M, Peng J P, Tang C J, Wang Q Y, He K, Chen X, Wang L L, Ma X C, Xue Q K 2014 Phys. Rev. B 89 060506

Cited By

[1]	Hsu F C, Luo J Y, Yeh K W, Chen T K, Huang T W, Wu Phillip M, Lee Y C, Huang Y L, Chu Y Y, Yan D C, Wu M K 2008 Proc. Natl. Acad. Sci. USA 105 14262
[2]	Wang Q Y, Li Z, Zhang W H, Zhang Z C, Zhang J S, Li W, Ding H, Ou Y B, Deng P, Chang K, Wen J, Song C L, He K, Jia J F, Ji S H, Wang Y Y, Wang L L, Chen X, Ma X C, Xue Q K 2012 Chin. Phys. Lett. 29 037402
[3]	Ge J F, Liu Z L, Liu C H, Gao C L, Qian D, Xue Q K, Liu Y, Jia J F 2015 Nat. Mater. 14 285
[4]	Miyata Y, Nakayama K, Sugawara K, Sato T, Takahashi T 2015 Nat. Mater. 14 775
[5]	Wang L L, Ma X C, Chen X, Xue Q K 2013 Chin. Phys. B 22 086801
[6]	Imai Y, Sawada Y, Nabeshima F, Maedaet A 2015 Proc. Natl. Acad. Sci. USA 112 1937
[7]	Medvedev S, McQueen T M, Troyan I A, Palasyuk T, Eremets M I, Cava R J, Naghavi1 S, Casper1 F, Ksenofontov V, Wortmann G, Felseret C 2009 Nat. Mater. 8 630
[8]	Margadonna S, Takabayashi Y, Ohishi Y, Mizuguchi Y, Takano Y, Kagayama T, Nakagawa T, Takata M, Prassides K 2009 Phys. Rev. B 80 064206
[9]	Jung S G, Lee N H, Choi E M, Kang W N, Lee S I, Hwang T J, Kim D H 2010 Physica C 470 1977
[10]	Chen L, Tsai C F, Zhu Y Y, Bi Z X, Wang H Y 2011 Physica C 471 515
[11]	Li Z, Peng J P, Zhang H M, Zhang W H, Ding H, Deng P, Chang K, Song C L, Ji S H, Wang L L, He K, Chen X, Xue Q K, Ma X C 2014 J. Phys: Condens. Mat. 26 265002
[12]	Wang M, Ou Y B, Li F S, Zhang W H, Tang C J, Wang L L, Xue Q K, Ma X C 2014 Acta Phys. Sin. 63 027401 (in Chinese) [王萌, 欧云波, 李坊森, 张文号, 汤辰佳, 王立莉, 薛其坤, 马旭村 2014 物理学报 63 027401]
[13]	Hanzawa K, Sato H, Hiramatsu H, Kamiya T, Hosono H 2015 arXiv: 1508 07689
[14]	Resh J, Jamison K D, Strozier J, Bensaoula A, Ignatiev A 1989 Phys. Rev. B 40 11799
[15]	Nemcsics 2002 Thin Solid Films 412 60
[16]	Zhang J, Neave J H, Dobson P J, Joyce B A 1987 Appl. Phys. A 42 317
[17]	Tan S, Zhang Y, Xia M, Ye Z R, Chen F, Xie X, Peng R, Xu D F, Fan Q, Xu H C, Jiang J, Zhang T, Lai X H, Xiang T, Hu J P, Xie B P, Feng D L 2013 Nat. Mater. 12 634
[18]	Huang D, Song C L, Webb T A, Fang S A, Chang C Z, Moodera J S, Kaxiras E, Hoffman J E 2015 Phys. Rev. Lett. 115 017002
[19]	Neave J H, Joyce B A, Dobson P J, Norton N 1983 Appl. Phys. A 31 1
[20]	Blger B, Larsen P K 1986 Rev. Sci. Instrum. 57 1363
[21]	Chen K M, Zhou T C, Fan Y L, Sheng C, Yu M R 1990 Acta Phys. Sin. 39 1937 (in Chinese) [陈可明, 周铁城, 樊永良, 盛篪, 俞鸣人 1990 物理学报 39 1937]
[22]	Wang Z L 1993 Rep. Prog. Phys. 56 997
[23]	Shin B, Leonard J P, McCamy J W, Aziz Michael J 2007 J. Vac. Sci. Technol. A 25 221
[24]	Okamoto H 1991 J. Phase. Equilib. Diff. 12 383
[25]	Ohring M 2001 Materials Science of Thin Films 7.6.1 (San Diego: Academic press) pp340-345
[26]	Clarke S, Vvedensky D D 1988 J. Appl. Phys. 63 2272
[27]	Braun W, Trampert A, Dweritz L, Ploog K H 1997 Phys. Rev. B 55 1689
[28]	Sudijono J, Johnson M D, Snyder C W, Elowitz M B, Orr B G 1992 Phys. Rev. Lett. 69 2811
[29]	Korte U, Maksym P A 1997 Phys. Rev. Lett. 78 2381
[30]	Zhang W, Li Z, Li F, Zhang H M, Peng J P, Tang C J, Wang Q Y, He K, Chen X, Wang L L, Ma X C, Xue Q K 2014 Phys. Rev. B 89 060506

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Vol. 65, Issue 12 - 2016-06-20

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