Preparation, doping modulation and field emission properties of square-shaped GaN nanowires

Yang Meng-Qi; Ji Yu-Hang; Liang Qi; Wang Chang-Hao; Zhang Yue-fei; Zhang Ming; Wang Bo; Wang Ru-Zhi

doi:10.7498/aps.69.20200445

Abstract

GaN nanomaterials, as one of the most important third-generation semiconductor materials, have attracted wide attention. In this study, GaN nanowires with square cross section were successfully prepared by microwave plasma chemical vapor deposition system. The diameters of nanowires are from 300 to 500 nm and the lengths from 15 to 20 μm. The results show that the cross section of nanowires could be transformed from triangle into square by adjusting the ratio of Mg to Ga in source materials. X-ray diffraction(XRD)result indicate that the structure of GaN nanowires are agree with the hexagonal wurtzite. X-ray photoelectron spectroscopy (XPS) rusult show that a certain amount of Mg and O impurities incoporated in the square-shaped GaN nanowires. Transmission electron microscopy (TEM) result suggested that square-shaped GaN nanowires had high crystallinity with a growth direction of [$0\bar 110$]. The ratio of source materials- and time-depented growth mechanism was also studied. It was suggested that the transformation of the cross section from triangle to square structure should be derived from the growth mechanism change from vapor-liquid-solid(VLS)process to vapor-solid(VS)process. The doped Mg increased the growth rate of the nanowires sidewalls, which led to a symmetrically growth of GaN nanowires along the twin boundaries. GaN nanowires gradually transformed to square structure by auto-catalytic growth. Moreover, the property of field emission were further investigated. The results showed that the turn-on electric field of square-shaped GaN nanowires was 5.2 V/m and a stable field emission property at high electric field. This research provides a new method for the preparation of square-shaped GaN nanowires and a prospective way for the design and fabrication of novel nano-scale devices.

Keywords:

Authors and contacts

1.
College of Materials Science and Engineering, Beijing University of Technology, Beijing 100124, China
2.
School of Physics, Beihang University, Beijing 100191, China
3.
Institute and Beijing Key Laboratory of Solid Microstructure and Properties, Beijing University of Technology, Beijing 100124, China

Corresponding author: Wang Ru-Zhi, wrz@bjut.edu.cn

Funds: National Natural Science Foundation of China (Grant Nos. 11774017, 51761135129)

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References

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[34]	Limbach F, Caterino R, Gotschke T, Stoica T, Calarco R, Geelhaar L, Riechert H 2012 AIP Advances 2 012157 Google Scholar
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[41]	Shi F, Huang Y L, Xue C S 2011 J. Exp. Nanosci. 6 174 Google Scholar
[42]	Rackauskas S, Jiang H, Wagner J B, Shandakov S D, Hansen T W, Kauppinen E I, Nasibulin A G 2014 Nano Lett. 14 5810 Google Scholar
[43]	Gamalski A D, Voorhees P W, Ducati C, Sharma R, Hofmann S 2014 Nano Lett. 14 1288 Google Scholar
[44]	Boukhicha R, Gardès C, Vincent L, Renard C, Yam V, Fossard F, Patriarche G, Jabeen F, Bouchier D 2011 EPL 95 18004 Google Scholar
[45]	Ngo T H, Gil B, Shubina T V, Damilano B, Vezian S, Valvin P, Massies J 2018 Sci. Rep. 8 15767 Google Scholar
[46]	Reshchikov M A, Morkoç H 2005 J. Appl. Phys. 97 061301 Google Scholar
[47]	Kaufmann U, Kunzer M, Maier M, Obloh H, Ramakrishnan A, Santic B, Schlotter P 1998 Appl. Phys. Lett. 72 1326 Google Scholar
[48]	Stoica T, Calarco R 2011 IEEE J. Sel. Top. Quant. 17 859 Google Scholar
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[52]	Wang R Z, Zhao W, Yan H 2017 Sci. Rep. 7 43625 Google Scholar
[53]	Li W D, Zhang M, Li Y, Liu G X, Li Z J 2019 CrystEngComm 21 3993 Google Scholar
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Cited By

图 1 不同原料配比制备Mg掺杂GaN纳米线的FESEM图　(a)样品A-a; (b)样品A-b; (c)样品A-c; (d)样品A-d; (e)样品A-e

Figure 1. FESEM images Mg doped GaN nanowires prepared at different source materials ratio. (a) Sample A-a; (b) sample A-b; (c) sample A-c; (d) sample A-d; (e) sample A-e.

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图 2 不同生长时间制备Mg掺杂GaN纳米线的FESEM图　(a)样品B-a; (b)样品B-b; (c)样品B-c; (d)样品B-d

Figure 2. FESEM images Mg doped GaN nanowires prepared at different growth times. (a) Sample B-a; (b) sample B-b; (c) sample B-c; (d) sample B-d.

DownLoad: Full-Size Img PowerPoint

图 3 样品A-e的XRD图谱

Figure 3. XRD spectra of sample A-e.

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图 4 样品A-e的XPS图谱

Figure 4. XPS spectra of sample A-e.

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图 5 样品A-e的(a) TEM图; (b) HRTEM图插图为样品A-e的SAED图

Figure 5. (a) TEM image; (b) HRTEM image and SAED pattern (inset) of sample A-e.

DownLoad: Full-Size Img PowerPoint

图 6 四方结构GaN纳米线的成核和生长过程示意图

Figure 6. Schematic diagram of nucleation and growth for square-shaped GaN nanowires.

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图 7 (a)样品A-a及样品A-e的PL图谱;(b)样品A-e的带隙分析图

Figure 7. (a) PL spectra of sample A-a and sample A-e; (b) band gap analysis spectra of sample A-e.

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图 8 样品A-a及样品A-e的(a) J-E曲线; (b) F-N曲线

Figure 8. (a) J-E curves; (b) F-N curves of sample A-a and sample A-e.

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表 1 不同原料配比制备Mg掺杂GaN纳米线的实验参数

Table 1. The experimental parameter of preparing Mg doped GaN nanowiresat different source materials ratio.

编号 N₂/sccm 气压/Torr T/℃ t/min 微波功率/W C∶Ga₂O₃∶MgO

A-a 13 10 870 30 300 12∶1∶0
A-b 13 10 870 30 300 12：1：0.2
A-c 13 10 870 30 300 12∶1∶0.5
A-d 13 10 870 30 300 12∶1∶1
A-e 13 10 870 30 300 12∶1∶1.5

DownLoad: CSV

表 2 不同生长时间制备Mg掺杂GaN纳米线的实验参数

Table 2. The experimental parameter of preparing Mg doped GaN nanowiresat different growth time.

编号 N₂/sccm 气压/Torr T/℃ t/min 微波功率/W C∶Ga₂O₃∶MgO

B-a 13 10 870 10 300 12∶1∶1.5
B-b 13 10 870 20 300 12∶1∶1.5
B-c 13 10 870 30 300 12∶1∶1.5
B-d 13 10 870 40 300 12∶1∶1.5

DownLoad: CSV

[1]	Han S, Choi I, Lee C R, Jeong K U, Lee S K, Kim J S 2020 ACS Appl. Mater. Inter. 12 970 Google Scholar
[2]	Guo D X, Wang X F, Wang H, Song W D, Chen H, Qi M Y, Luo X J, Luo X, Li G, Qin G G, Li S T 2018 ACS Photonics 5 4810 Google Scholar
[3]	Ko S M, Hur J, Lee C, Isnaeni, Gong S H, Kim M, Cho Y H 2020 Sci. Rep. 10 358 Google Scholar
[4]	邓长发, 燕少安, 王冬, 彭金峰, 郑学军 2019 物理学报 68 237304 Google Scholar Deng C F, Yan S A, Wang D, Peng J F, Zheng X J 2019 Acta Phys. Sin. 68 237304 Google Scholar
[5]	Liu B, Hu T, Wang Z, Liu L, Qin F, Huang N, Jiang X 2012 Cryst. Res. Technol. 47 207 Google Scholar
[6]	Sahoo P, Dhara S, Amirthapandian S, Kamruddin M 2013 J Mater. Chem. C 1 7237 Google Scholar
[7]	Johar M A, Song H G, Waseem A, Hassan M A, Bagal I V, Cho Y H, Ryu S W 2020 Appl. Mater. Today 19 100541 Google Scholar
[8]	Liao H, Wei T T, Zong H, Jiang S X, Li J C, Yang Y, Yu G, Wen P J, Lang R, Wang W J, Hu X D 2019 Appl. Surf. Sci. 489 346 Google Scholar
[9]	Morassi M, Guan N, Dubrovskii V G, Berdnikov Y, Barbier C, Mancini L, Largeau L, Babichev A V, Kumaresan V, Julien F H, Travers L, Gogneau N, Harmand J C, Tchernycheva M 2019 Cryst. Growth Des. 20 552
[10]	Treeck D v, Garrido S F, Geelhaar L 2020 Phys. Rev. Mater. 4 013404 Google Scholar
[11]	Sun J M, Han M M, Gu Y, Yang Z X, Zeng H B 2018 Adv. Optical Mater. 6 1800256 Google Scholar
[12]	赵军伟, 张跃飞, 宋雪梅, 严辉, 王如志 2014 物理学报 63 117702 Google Scholar Zhao J W, Zhang Y F, Song X M, Yan H, Wang R Z 2014 Acta Phys. Sin. 63 117702 Google Scholar
[13]	Ji Y H, Wang R Z, Feng X Y, Zhang Y F, Yan H 2017 J. Phys. Chem. C 121 24804 Google Scholar
[14]	Feng X Y, Wang R Z, Liang Q, Ji Y H, Yang M Q 2019 Cryst. Growth Des. 19 2687 Google Scholar
[15]	Zhao J W, Zhang Y F, Li Y H, Su C H, Song X M, Yan H, Wang R Z 2015 Sci. Rep. 5 17692 Google Scholar
[16]	Bernal R A, Agrawal R, Peng B, Bertness K A, Sanford N A 2011 Nano Lett. 11 548 Google Scholar
[17]	Pozina G, Gubaydullin A R, Mitrofanov M I, Kaliteevski M A, Levitskii I V, Voznyuk G V, Tatarinov E E 2018 Sci. Rep. 8 7218 Google Scholar
[18]	Ross F M, Tersoff J, Reuter M C 2005 Phys. Rev. Lett. 95 146104 Google Scholar
[19]	Gholampour M, Abdollah-zadeh A, Poursalehi R, Shekari L 2014 Mater. Lett. 120 136 Google Scholar
[20]	Srivastava P, Kumar A, Jaiswal N K, Sharma V 2016 Proceeding of International Conference on Condensed Matter and Applied Physics Bikaner, INDIA, OCT 30–31, 2015 p020071
[21]	Srivastava P, Kumar A, Jaiswal N K, Sharma V 2016 Phys. Status Solidi B 253 2185 Google Scholar
[22]	Wang Y Q, Wang R Z, Zhu M K, Wang B B, Yan H 2013 Appl. Surf. Sci. 285 115 Google Scholar
[23]	Liu B D, Bando Y, Tang C C, Xu F F 2005 J. Phys. Chem. B 109 21521 Google Scholar
[24]	Li E L, Wu B, Lv S T, Cui Z, Ma D M, Shi W 2016 J. Alloy. Compd. 681 324 Google Scholar
[25]	Xia S H, Liu L, Diao Y, Feng S 2017 J. Appl. Phys. 122 135102 Google Scholar
[26]	Pan C J, Chi G C 1999 Solid State Electron. 43 621 Google Scholar
[27]	Jaud A, Auvray L, Kahouli A, Abi-Tannous T, Cauwet F, Ferro G, Brylinski C 2017 Phys. Status Solidi A 214 1600428 Google Scholar
[28]	Bae S Y, Lekhal K, Lee H J, Min J W, Lee D S, Honda Y, Amano H 2017 Phy. Status Solidi B 254 1600722 Google Scholar
[29]	Kamimura J, Bogdanoff P, Ramsteiner M, Corfdir P, Feix F, Geelhaar L, Riechert H 2017 Nano Lett. 17 1529 Google Scholar
[30]	Siladie A M, Amichi L, Mollard N, Mouton I, Bonef B, Bougerol C, Grenier A, Robin E, Jouneau P H, Garro N, Cros A, Daudin B 2018 Nanotechnology 29 255706 Google Scholar
[31]	Miceli G, Pasquarello A 2016 Phys.l Rev. B 93 165207 Google Scholar
[32]	Wang Y Q, Wang R Z, Li Y J, Zhang Y F, Zhu M K, Wang B B, Yan H 2013 CrystEngComm 15 1626 Google Scholar
[33]	Lymperakis L, Neugebauer J 2009 Phys. Rev. B 79 241308 Google Scholar
[34]	Limbach F, Caterino R, Gotschke T, Stoica T, Calarco R, Geelhaar L, Riechert H 2012 AIP Advances 2 012157 Google Scholar
[35]	Nayak S, Kumar R, Pandey N, Nagaraja K K, Gupta M, Shivaprasad S M 2018 J. Appl. Phys. 123 135303 Google Scholar
[36]	Park J B, Kim N J, Kim Y J, Lee S H, Yi G C 2014 Curr. Appl. Phys. 14 1437 Google Scholar
[37]	Ji Y H, Wang R Z, Yang M Q, Feng X Y, Zhang Y F, Huang A P, Yang L X, Liu Y Q, Yan Y Z, Yan H 2020 J. Phys. Chem. C 124 6725 Google Scholar
[38]	Li Z J, Li W D, Wang X L, Zhang M 2014 Phys. Status Solidi A 211 1550 Google Scholar
[39]	Consonni V, Knelangen M, Geelhaar L, Trampert A, Riechert H 2010 Phys. Rev. B 81 085310 Google Scholar
[40]	Zhang D D, Xue C S, Zhuang H Z, Sun H B, Cao Y P, Huang Y L, Wang Z P, Wang Y 2009 Chemphyschem 10 571 Google Scholar
[41]	Shi F, Huang Y L, Xue C S 2011 J. Exp. Nanosci. 6 174 Google Scholar
[42]	Rackauskas S, Jiang H, Wagner J B, Shandakov S D, Hansen T W, Kauppinen E I, Nasibulin A G 2014 Nano Lett. 14 5810 Google Scholar
[43]	Gamalski A D, Voorhees P W, Ducati C, Sharma R, Hofmann S 2014 Nano Lett. 14 1288 Google Scholar
[44]	Boukhicha R, Gardès C, Vincent L, Renard C, Yam V, Fossard F, Patriarche G, Jabeen F, Bouchier D 2011 EPL 95 18004 Google Scholar
[45]	Ngo T H, Gil B, Shubina T V, Damilano B, Vezian S, Valvin P, Massies J 2018 Sci. Rep. 8 15767 Google Scholar
[46]	Reshchikov M A, Morkoç H 2005 J. Appl. Phys. 97 061301 Google Scholar
[47]	Kaufmann U, Kunzer M, Maier M, Obloh H, Ramakrishnan A, Santic B, Schlotter P 1998 Appl. Phys. Lett. 72 1326 Google Scholar
[48]	Stoica T, Calarco R 2011 IEEE J. Sel. Top. Quant. 17 859 Google Scholar
[49]	Das S N, Patra S, Kar J P, Lee M J, Hwang S H, Lee T I, Myoung J M 2013 Mater. Lett. 106 352 Google Scholar
[50]	Bayel M W, Brandt M S, Glaser E R, Wickenden A E, D. K D, Henry R L, Stutzmann M 1999 Phys. Ptat. Pol. B 216 547
[51]	Glaser E R, Carlos W E, Braga G C B 2002 Phys. Rev. B 65 085312 Google Scholar
[52]	Wang R Z, Zhao W, Yan H 2017 Sci. Rep. 7 43625 Google Scholar
[53]	Li W D, Zhang M, Li Y, Liu G X, Li Z J 2019 CrystEngComm 21 3993 Google Scholar
[54]	Zhao W, Wang R Z, Song Z W, Wang H, Yan H, Chu P K 2013 J. Physl. Chem. C 117 1518 Google Scholar
[55]	Vayssieres L, Graetzel M 2004 Angew. Chem. Int. Ed. Engl. 43 3666 Google Scholar
[56]	Diao Y, Liu L, Xia S H, Feng S, Lu F F 2018 Superlattice Microst. 115 140 Google Scholar
[57]	Wang Z, Chen Y H, Ye X L 2004 13th International Conference on Semiconducting and Insulating Materials Beijing, China, Sep. 20–25, 2004 pp57–60

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Vol. 69, Issue 16 - 2020-08-20

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