Metal thermopile infrared detector with vertical graphene

Li Kai; Sun Jie; Du Zai-Fa; Qian Feng-Song; Tang Peng-Hao; Mei Yu; Xu Chen; Yan Qun; Liu Ming; Li Long-Fei; Guo Wei-Ling

doi:10.7498/aps.72.20221564

Abstract

Thermopile infrared detector is a kind of detector device mainly composed of thermocouple as the basic unit. Because of its simple principle, no need of cooling equipment, and other advantages, it has been widely used in various fields of production and life. However, the absorption rates of the materials in conventional thermopile devices are poor, and the majority of them are incompatible with microfabrication methods. In this work, a metal thermopile infrared detector with vertical graphene (VG) is designed and fabricated. The VG is grown via plasma enhanced chemical vapor deposition, and retained at the device’s thermal ends to provide the thermopile IR detector’s wideband and high response characteristics. The detector achieves a room temperature responsivity reaching a value as high as 1.53 V/W at 792 nm, which can increase the response results about 28 times and reduce the response time to 0.8 ms compared with the thermopile detector without VG. After systematically measuring the response results, it is finally found that there are three main mechanisms responsible for the response on the composite device. The first one is the response generated by the metal thermopile itself alone. The second one is the response increased eventually by the contribution of VG covered at the metal thermal junction that expands the temperature difference. The last one is the response generated by the temperature gradient existing inside the VG on the surface of the device after the absorption of heat. The portion of each partial response mechanism in the total response is also analyzed, providing a new reference direction for analyzing the response generation mechanism of thermopile detectors with other absorbing materials. The process is compatible with the microfabrication, while the device performance is enhanced and suitable for mass production. Furthermore, by utilizing the surface plasmon resonance to combine VG with metal nanoparticles, the material’s light absorption is found to be enhanced significantly under the same conditions, and the resulting thermal voltage can be increased to 6 times. The results indicate that VG promises to possess practical applications, in many fields such as photoelectric sensing and power production devices. This technology provides a new method to manufacture high-performance thermopile infrared detectors and other sensor devices.

Keywords:

Authors and contacts

1.
Key Laboratory of Optoelectronics Technology, College of Microelectronics, Beijing University of Technology, Beijing 100124, China
2.
Fujian Science and Technology Innovation Laboratory for Optoelectronic Information of China, National and Local United Engineering Laboratory of Flat Panel Display Technology, Fuzhou University, Fuzhou 350100, China
3.
Quantum Device Physics Laboratory, Chalmers University of Technology, Göteborg 41296, Sweden

Corresponding author: Sun Jie, jie.sun@fzu.edu.cn ; Guo Wei-Ling, guoweiling@bjut.edu.cn

Funds: Project supported by the National Key R&D Program of China (Grant No. 2018YFA0209000), the Fujian Provincial Science and Technology Department Project, China (Grant Nos. 2021HZ0114, 2021J01583, 2021L3004), and the Fujian Science & Technology Innovation Laboratory for Optoelectronic Information of China (Grant No. 2021ZZ122).

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References

[1]	Xia F, Mueller T, Lin Y, Valdes-Garcia A, Avouris P 2009 Nat. Nanotechnol. 4 839 Google Scholar
[2]	Mittendorff M, Winnerl S, Kamann J, Eroms J, Weiss D, Schneider H, Helm M 2013 Appl. Phys. Lett. 103 021113 Google Scholar
[3]	Compton O C, Nguyen S B T 2010 Small 6 711 Google Scholar
[4]	Katsnelson M I 2007 Mater. Today 10 20
[5]	Nair R R, Blake P, Grigorenko A N, Novoselov K S, Booth T J, Stauber T, Peres N M R, Geim A K 2008 Science 320 1308 Google Scholar
[6]	Liu C, Chang Y, Norris T B, Zhong Z 2014 Nat. Nanotechnol. 9 273 Google Scholar
[7]	Shi S F, Xu X, Ralph D C, McEuen P L 2011 Nano Lett. 11 1814 Google Scholar
[8]	Emani N K, Chung T F, Ni X, Kildishev A V, Chen Y P, Boltasseva A 2012 Nano Lett. 12 5202 Google Scholar
[9]	Lee H, Heo K, Park J, Park Y, Noh S, Kim K S, Lee C, Hong B H, Jian J, Hong S 2012 J. Mater. Chem. 22 8372 Google Scholar
[10]	Babichev A V, Zhang H, Lavenus P, Julien F H, Egorov A Y, Lin Y T, Tu L W, Tchernycheva M 2013 Appl. Phys. Lett. 103 201103 Google Scholar
[11]	Konstantatos G, Badioli M, Gaudreau L, Osmond J, Bernechea M, De Arquer P G F, Gatti F, Koppens F H 2012 Nat. Nanotechnol. 7 363 Google Scholar
[12]	Bo Z, Yang Y, Chen J, Yu K, Yan J, Cen K 2013 Nanoscale 5 5180 Google Scholar
[13]	Bo Z, Mao S, Han Z J, Cen K, Chen J, Ostrikov K K 2015 Chem. Soc. Rev. 44 2108 Google Scholar
[14]	Zhu W, Xue Z Y, Wang G, Zhao M H, Chen D, Guo Q L, Liu Z D, Feng X Q, Ding G Q, Chu P K, Di Z F 2020 ACS Appl. Nano Mater. 3 6915 Google Scholar
[15]	Yu K, Wang P, Lu G, Chen K H, Bo Z, Chen J 2011 J. Phys. Chem. Lett. 2 537 Google Scholar
[16]	Graf A, Arndt M, Sauer M, Gerlach G 2007 Meas. Sci. Technol. 18 R59 Google Scholar
[17]	Chaglla E J S, Celik N, Balachandran W 2018 Sensors 18 3315 Google Scholar
[18]	Moisello E, Malcovati P, Bonizzoni E 2021 Micromachines 12 148 Google Scholar
[19]	Buchner R, Sosna C, Maiwald M, Benecke W, Lang W 2006 Sens. Actuators, A 130 262
[20]	Dijkstra M, Lammerink T S, de Boer M J, Berenschot E J W, Wiegerink R J, Elwenspoek M 2014 J. Microelectromech. Syst. 23 908 Google Scholar
[21]	Randjelovic D, Petropoulos A, Kaltsas G, Stojanovic M, Lazic Z, Djuric Z, Matic M 2008 Sens. Actuators, A 141 404 Google Scholar
[22]	Yoo K P, Hong H P, Lee M J, Min S J, Park C W, Choi W S, Min N K 2011 Meas. Sci. Technol. 22 115206 Google Scholar
[23]	Itoigawa K, Ueno H, Shiozaki M, Toriyama T, Sugiyama S 2005 J. Micromech. Microeng. 15 S233 Google Scholar
[24]	Dhawan R, Madusanka P, Hu G Y, Debord J, Tran T, Maggio K, Edwards H, Lee M 2020 Nat. Commun. 11 4362 Google Scholar
[25]	Xu D H, Wang Y L, Xiong B, Li T 2017 Front. Mech. Eng. 12 557 Google Scholar
[26]	Shahmarvandi E K, Ghaderi M, Wolffenbuttel R F 2016 J. Phys. Conf. Ser. 757 012033 Google Scholar
[27]	Xu D, Xiong B, Wang Y 2010 IEEE Electron Device Lett. 31 512 Google Scholar
[28]	Zhang C C, Mao H Y, Shi M, Xiong J J, Long K W, Chen D P 2020 33rd IEEE International Confence on Micro Electro Mechannical Systems (MEMS 2020) Vancouver, Canada, January 18–22, 2020 p949
[29]	Qian F, Deng J, Xiong F, Dong Y, Xu C 2020 Opt. Mater. Express 10 2909 Google Scholar
[30]	Li X, Zhu M, Du M, Lv Z, Zhang L, Li Y, Yang Y, Yang T, Li X, Wang K, Zhu Y, Fang Y 2016 Small 12 549 Google Scholar
[31]	Tian W, Wang Y, Zhou H, Wang Y L, Li T 2020 J. Microelectromech Syst. 29 36 Google Scholar
[32]	Sofiane B M, Sébastien E, Thomas B, Laurent T, Pascal V, Danick B, Jean-Paul G, Laurent C 2015 Microsyst. Technol. 21 1627 Google Scholar
[33]	Allen L H, Patrick K H, Nathaniel M G, Sungjae H, Yong C S, Yi S, Matthew C, Madan D, Anantha P C, Jing K, Pablo J, Tomás P 2015 Nano Lett. 15 7211 Google Scholar
[34]	Willets K A, Van Duyne, R P 2007 Ann. Rev. Phys. Chem. 58 267 Google Scholar

Cited By

图 1 PECVD系统反应腔室结构示意图

Figure 1. Schematic diagram of the structure of the reaction chamber of the PECVD system.

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图 2 (a)—(e) VG热电堆探测器制备流程; (f) VG热电堆探测器及器件测试示意图

Figure 2. (a)–(e) Preparation process of VG thermopile detector; (f) schematic diagram of the VG thermopile detector and device measuring.

DownLoad: Full-Size Img PowerPoint

图 3 带有VG金属热电堆红外探测器实物图

Figure 3. Physical image of infrared detector with VG metal thermopile.

DownLoad: Full-Size Img PowerPoint

图 4 VG的(a) SEM图和(b)拉曼光谱图; 不同生长时间的VG对应的(c)光透射率和(d)反射率

Figure 4. (a) SEM image and (b) Raman spectrum of VG; (c), (d) corresponding optical transmittance (c) and reflectance (d) of VG with different growth time.

DownLoad: Full-Size Img PowerPoint

图 5 器件在(a), (b) 792和(c), (d) 1550 nm下的响应结果　(a), (c) 仅有金属的热电堆器件; (b), (d) 带有VG的金属热电堆器件

Figure 5. Response results of the device at (a), (b) 792 and (c), (d) 1550 nm: (a), (c) Metal-only thermopile device; (b), (d) metal thermopile device combined with VG.

DownLoad: Full-Size Img PowerPoint

图 6 VG热电堆探测器在792 nm下的测试结果　(a) 响应测试示意图; (b) 仅有金属的器件光照在左端; (c) 仅有金属的器件光照在右端; (d) 带有VG的器件光照在左端; (e) 带有VG的器件光照在中点; (f) 带有VG的器件光照在右端

Figure 6. Measure results of VG thermopile detector at 792 nm: (a) Measure schematic diagram; (b) metal-only device (laser on the left end); (c) metal-only device (laser on the right end); (d) with VG device (laser on the left end); (e) with VG device (laser on the midpoint); (f) with VG device (laser on the right end).

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图 10 VG与金属纳米颗粒结合前后的响应结果　(a) VG与AgNPs; (b) VG与AuNPs

Figure 10. Response results before and after the combination of VG and metal nanoparticles: (a) VG with AgNPs; (b) VG with AuNPs

DownLoad: Full-Size Img PowerPoint

图 7 VG热电堆探测器在1550 nm下的测试结果　(a) 带有VG的器件光照在左端; (b) 带有VG的器件光照在中点; (c) 带有VG的器件光照在右端

Figure 7. Measure results of VG thermopile detector at 1550 nm: (a) With VG device (laser on the left end); (b) with VG device (laser on the midpoint); (c) with VG device (laser on the right end).

DownLoad: Full-Size Img PowerPoint

图 8 厚度为8 nm Au薄膜和Ag薄膜退火后的SEM图和粒径统计直方图　(a) Au退火700 ℃; (b) Au退火 900 ℃; (c) Ag退火 300 ℃; (d) Ag退火 700 ℃; (e)—(h) 相对应的粒径统计直方图结果

Figure 8. SEM images and particle size statistical histograms of 8 nm thick Au films and Ag films after annealing: (a) Au annealed at 700 ℃; (b) Au annealed at 900 ℃; (c) Ag annealed at 300 ℃; (d) Ag annealed at 700 ℃; (e)–(h) corresponding particle size statistical histogram results.

DownLoad: Full-Size Img PowerPoint

图 9 VG与金属纳米颗粒结合前后的(a), (b)拉曼测试和(c), (d)光吸收率结果　(a), (c) VG与AgNPs; (b), (d) VG与AuNPs

Figure 9. (a), (b) Raman and (c), (d) optical absorption results before and after the combination of VG and metal nanoparticles: (a), (c) VG with AgNPs; (b), (d) VG with AuNPs.

DownLoad: Full-Size Img PowerPoint

表 1 不同种热电堆红外探测器的参数比较

Table 1. Parameter comparison of different thermopile infrared detectors.

吸收层热电堆材料响应度
R/(V·W^–1) 响应时间
τ/ms

Au^[31] P/n-polySi 16.5 14
Ti^[32] n-polySi/Ti 2 10
SiN-SiO₂^[33] p/n-graphene 9 23
VG Cu/Cu-Ni 1.53 0.8

DownLoad: CSV

[1]	Xia F, Mueller T, Lin Y, Valdes-Garcia A, Avouris P 2009 Nat. Nanotechnol. 4 839 Google Scholar
[2]	Mittendorff M, Winnerl S, Kamann J, Eroms J, Weiss D, Schneider H, Helm M 2013 Appl. Phys. Lett. 103 021113 Google Scholar
[3]	Compton O C, Nguyen S B T 2010 Small 6 711 Google Scholar
[4]	Katsnelson M I 2007 Mater. Today 10 20
[5]	Nair R R, Blake P, Grigorenko A N, Novoselov K S, Booth T J, Stauber T, Peres N M R, Geim A K 2008 Science 320 1308 Google Scholar
[6]	Liu C, Chang Y, Norris T B, Zhong Z 2014 Nat. Nanotechnol. 9 273 Google Scholar
[7]	Shi S F, Xu X, Ralph D C, McEuen P L 2011 Nano Lett. 11 1814 Google Scholar
[8]	Emani N K, Chung T F, Ni X, Kildishev A V, Chen Y P, Boltasseva A 2012 Nano Lett. 12 5202 Google Scholar
[9]	Lee H, Heo K, Park J, Park Y, Noh S, Kim K S, Lee C, Hong B H, Jian J, Hong S 2012 J. Mater. Chem. 22 8372 Google Scholar
[10]	Babichev A V, Zhang H, Lavenus P, Julien F H, Egorov A Y, Lin Y T, Tu L W, Tchernycheva M 2013 Appl. Phys. Lett. 103 201103 Google Scholar
[11]	Konstantatos G, Badioli M, Gaudreau L, Osmond J, Bernechea M, De Arquer P G F, Gatti F, Koppens F H 2012 Nat. Nanotechnol. 7 363 Google Scholar
[12]	Bo Z, Yang Y, Chen J, Yu K, Yan J, Cen K 2013 Nanoscale 5 5180 Google Scholar
[13]	Bo Z, Mao S, Han Z J, Cen K, Chen J, Ostrikov K K 2015 Chem. Soc. Rev. 44 2108 Google Scholar
[14]	Zhu W, Xue Z Y, Wang G, Zhao M H, Chen D, Guo Q L, Liu Z D, Feng X Q, Ding G Q, Chu P K, Di Z F 2020 ACS Appl. Nano Mater. 3 6915 Google Scholar
[15]	Yu K, Wang P, Lu G, Chen K H, Bo Z, Chen J 2011 J. Phys. Chem. Lett. 2 537 Google Scholar
[16]	Graf A, Arndt M, Sauer M, Gerlach G 2007 Meas. Sci. Technol. 18 R59 Google Scholar
[17]	Chaglla E J S, Celik N, Balachandran W 2018 Sensors 18 3315 Google Scholar
[18]	Moisello E, Malcovati P, Bonizzoni E 2021 Micromachines 12 148 Google Scholar
[19]	Buchner R, Sosna C, Maiwald M, Benecke W, Lang W 2006 Sens. Actuators, A 130 262
[20]	Dijkstra M, Lammerink T S, de Boer M J, Berenschot E J W, Wiegerink R J, Elwenspoek M 2014 J. Microelectromech. Syst. 23 908 Google Scholar
[21]	Randjelovic D, Petropoulos A, Kaltsas G, Stojanovic M, Lazic Z, Djuric Z, Matic M 2008 Sens. Actuators, A 141 404 Google Scholar
[22]	Yoo K P, Hong H P, Lee M J, Min S J, Park C W, Choi W S, Min N K 2011 Meas. Sci. Technol. 22 115206 Google Scholar
[23]	Itoigawa K, Ueno H, Shiozaki M, Toriyama T, Sugiyama S 2005 J. Micromech. Microeng. 15 S233 Google Scholar
[24]	Dhawan R, Madusanka P, Hu G Y, Debord J, Tran T, Maggio K, Edwards H, Lee M 2020 Nat. Commun. 11 4362 Google Scholar
[25]	Xu D H, Wang Y L, Xiong B, Li T 2017 Front. Mech. Eng. 12 557 Google Scholar
[26]	Shahmarvandi E K, Ghaderi M, Wolffenbuttel R F 2016 J. Phys. Conf. Ser. 757 012033 Google Scholar
[27]	Xu D, Xiong B, Wang Y 2010 IEEE Electron Device Lett. 31 512 Google Scholar
[28]	Zhang C C, Mao H Y, Shi M, Xiong J J, Long K W, Chen D P 2020 33rd IEEE International Confence on Micro Electro Mechannical Systems (MEMS 2020) Vancouver, Canada, January 18–22, 2020 p949
[29]	Qian F, Deng J, Xiong F, Dong Y, Xu C 2020 Opt. Mater. Express 10 2909 Google Scholar
[30]	Li X, Zhu M, Du M, Lv Z, Zhang L, Li Y, Yang Y, Yang T, Li X, Wang K, Zhu Y, Fang Y 2016 Small 12 549 Google Scholar
[31]	Tian W, Wang Y, Zhou H, Wang Y L, Li T 2020 J. Microelectromech Syst. 29 36 Google Scholar
[32]	Sofiane B M, Sébastien E, Thomas B, Laurent T, Pascal V, Danick B, Jean-Paul G, Laurent C 2015 Microsyst. Technol. 21 1627 Google Scholar
[33]	Allen L H, Patrick K H, Nathaniel M G, Sungjae H, Yong C S, Yi S, Matthew C, Madan D, Anantha P C, Jing K, Pablo J, Tomás P 2015 Nano Lett. 15 7211 Google Scholar
[34]	Willets K A, Van Duyne, R P 2007 Ann. Rev. Phys. Chem. 58 267 Google Scholar

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