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Research progress of Cu2Se thin film thermoelectric properties

Yang Liang-Liang Qin Yuan-Hao Wei Jiang-Tao Song Pei-Shuai Zhang Ming-Liang Yang Fu-Hua Wang Xiao-Dong

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Research progress of Cu2Se thin film thermoelectric properties

Yang Liang-Liang, Qin Yuan-Hao, Wei Jiang-Tao, Song Pei-Shuai, Zhang Ming-Liang, Yang Fu-Hua, Wang Xiao-Dong
Acta Phys. Sin., 2021, 70(7): 076802.
doi: 10.7498/aps.70.20201677
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  • Abstract

    Thermoelectric (TE) materials can directly realize the mutual conversion between heat and electricity, and it is an environmentally friendly functional material. At present, the thermoelectric conversion efficiencies of thermoelectric materials are low, which seriously restricts the large-scale application of thermoelectric devices. Therefore, finding new materials with better thermoelectric properties or improving the thermoelectric properties of traditional thermoelectric materials has become the subject of thermoelectric research. Thin film materials, compared with bulk materials, possess both the two-dimensional macroscopic properties and one-dimensional nanostructure characteristics, which makes it much easier to study the relationships between physical mechanisms and properties. Besides, thin film are also suitable for the preparation of wearable electronic devices. This article summarizes five different preparation methods of Cu2Se thin films, i.e. electrochemical deposition, thermal evaporation, spin coating, sputtering, and pulsed laser deposition. In addition, combing with typical examples, the characterization methods of the film are summarized, and the influence mechanism of each parameter on the thermoelectric performance from electrical conductivity, Seebeck coefficient and thermal conductivity is discussed. Finally, the hot application direction of Cu2Se thin film thermoelectrics is also introduced.

    Authors and contacts

    • 1.

      Engineering Research Center for Semiconductor Integrated Technology, Institute of Semiconductors, Chinese Academy of Sciences, Beijing 100083, China

    • 2.

      College of Microelectronics and Research Center of Materials and Optoelectronics, University of Chinese Academy of Sciences, Beijing 100049, China

    • 3.

      Beijing Institute of Quantum Information Science, Beijing 100193, China

    • 4.

      Beijing Semiconductor Micro/Nano Integrated Engineering Technology Research Center, Beijing 100083, China

      • Corresponding author: Wang Xiao-Dong, xdwang@semi.ac.cn
    • Funds: Project supported by the National Key Research and Development Program of China (Grant Nos. 2019YFB1503602, 2018YFB1107502), the Pilot B Program of the Chinese Academy of Sciences, China (Grant No. XDB43020500) and Development Program of Scientific Research Instruments and Equipment of the Chinese Academy of Sciences, China (Grant No. GJJSTD20200006)

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  • 图 1  Cu2Se高温β相晶体结构[34] (a)在8c和32f间隙位置显示有铜原子的晶胞; (b)沿着立方[$1\bar{1} 0$]方向的晶体结构的投影平面表示

    Figure 1.  Cu2Se high temperature β- phase crystal structure[34] (a) Unit cell where the 8c and 32f interstitial positions are shown with Cu atoms; (b) projected plane representation of the crystal structure along the cubic [$1\bar{1} 0$] direction.

    DownLoad: Full-Size Img PowerPoint

    图 2  (a)电镀沉积生长机制示意图; (b) Cu2Se薄膜的XRD图案; (c) Cu2Se薄膜的场发射扫描电子显微镜(FESEM)图像; (d) ITO基板上Cu2Se薄膜的AFM 3D图像[41]

    Figure 2.  (a) Schematic diagram of Galvanic Deposition mechanism; (b) XRD pattern of Cu2Se thin film; (c) FESEM image of Cu2Se thin film; (d) AFM 3D image of Cu2Se film on ITO substrate[41].

    DownLoad: Full-Size Img PowerPoint

    图 3  (a)溶解在硫醇胺中的Cu2–x Se溶液; (b) 旋涂和退火后, 玻璃上的Cu2Se薄膜; (c) (d) Cu2–x Se薄膜样品浸泡前的SEM图像; (d) Cu2–x Se薄膜样品浸泡后的SEM图像; (e) 旋涂制备的Cu2–x Se样品的XRD图谱[54]

    Figure 3.  (a) Cu2–x Se solution dissolved in thiolamine; (b) after spin coating and annealing, the Cu2Se film on the glass; (c) SEM image of Cu2–x Se thin film sample before soaking; (d) SEM image of Cu2–x Se thin film sample after soaking; (e) XRD pattern of Cu2–x Se sample prepared by spin coating[54].

    DownLoad: Full-Size Img PowerPoint

    图 4  (a) Al2O3基板上沉积的Cu2Se薄膜的照片; (b) 在573 K下退火的薄膜能量色散X射线光谱(EDS); (c) Al2O3基材上薄膜的横截面SEM分析; (d) 薄膜中纳米晶体的TEM分析, 其中虚线突出了晶界, 插图是TEM图像的相应FFT[40]

    Figure 4.  (a) Photograph of Cu2Se thin film deposited on Al2O3 substrate; (b) energy dispersive X-ray spectroscopy (EDS) of thin film annealed at 573 K; (c) cross-sectional SEM analysis of thin film on Al2O3 substrate; (d) TEM analysis of nanocrystals in the thin film, the dotted line highlights the grain boundaries, the inset is the corresponding FFT of the TEM image.[40]

    DownLoad: Full-Size Img PowerPoint

    图 5  (a) 脉冲混合反应磁控溅射(PHRMS)沉积系统; (b) 从标称成分分别为Cu/Se = 1, 2, 2.4, 3.6, 5和9的薄膜上获得的掠入射同步辐射X射线衍射图[60]

    Figure 5.  (a) Pulse hybrid reactive magnetron sputtering (PHRMS) deposition system; (b) grazing incident synchrotron radiation X Ray diffraction pattern obtained from a film with a nominal composition of Cu/Se = 1, 2, 2.4, 3.6, 5 and 9[60].

    DownLoad: Full-Size Img PowerPoint

    图 6  具有不同铜/硒比的薄膜的SEM图像[60]  (a) Cu/Se = 1; (b) Cu/Se = 2; (c) Cu/Se = 2.4; (d) Cu/Se = 3.6; (e) Cu/Se = 5; (f) Cu/Se = 9

    Figure 6.  SEM images of films with different copper/selenium ratios[60] (a) Cu/Se = 1; (b) Cu/Se = 2; (c) Cu/Se = 2.4; (d) Cu/Se = 3.6; (e) Cu/Se = 5; (f) Cu/Se = 9.

    DownLoad: Full-Size Img PowerPoint

    图 7  (a)由各种Cu2+x Se靶沉积的Cu2–y Se膜中的XRD图案; (b) 根据布拉格定律计算的(001)面的晶面晶体间距(c); (c) Cu2Se膜的截面HRTEM图像; (d) (e)不同Cu2–x Se靶沉积的Cu2–y Se膜的FESEM图像, (d) x = 0.1, (d) x = 0.3 [10]

    Figure 7.  (a) XRD patterns in Cu2–y Se films deposited from various Cu2+x Se targets; (b) (001) plane crystal spacing (c) calculated according to Bragg's law; (c) HRTEM image of the cross-section of Cu2Se film; (d)(e) FESEM images of Cu2–y Se films deposited on different Cu2–x Se targets, (d) x = 0.1, (e) x = 0.3 [10]

    DownLoad: Full-Size Img PowerPoint

    图 8  (a)在不同温度下退火的Cu2Se薄膜中的室温载流子浓度; (b)电导率对薄膜中载流子浓度的依赖性; (c)塞贝克系数对薄膜中载流子浓度的依赖性; (d) (e) 柔性塑料基板上Cu2Se薄膜的热电性能; (f)沉积在聚酰亚胺基板上的薄膜的电导率σ, (g)塞贝克系数S, (h) 功率因数PF = σS2 [40]

    Figure 8.  (a) Room temperature carrier concentration in Cu2Se thin films annealed at different temperatures; (b) dependence of conductivity on carrier concentration in thin films; (c) dependence of Seebeck coefficient on carrier concentration in film; (d)(e) thermoelectric properties of Cu2Se film on flexible plastic substrate, (f) conductivity σ of the film deposited on polyimide substrate, (g) Seebeck coefficient S, (h) power factor PF = σS2 [40].

    DownLoad: Full-Size Img PowerPoint

    图 9  (a) Cu2Se/PEDOT: PSS复合膜的输出电压与温度梯度的关系; (b) 在不同温差下的输出电压和功率与电流的关系; (c) 设备的数码照片; (d) 由于手臂和周围环境之间的温差而产生的4.5 mV电压的照片; (e) 将茶水倒入500 mL烧杯中直至液位到达设备下边缘时产生的15.4 mV电压的照片, d部分和e部分的插图是红外热像图[77]

    Figure 9.  (a) Cu2Se/PEDOT: Relationship between the output voltage of the PSS composite film and the temperature gradient; (b) relationship between output voltage and power and current under different temperature differences; (c) digital photos of the device; (d) photo of the 4.5 mV voltage generated due to the temperature difference between the arm and the surrounding environment; (e) pour the tea water into a 500 mL beaker until the liquid level reaches the bottom edge of the device at 15.4 mV voltage, where Illustrations in the (d) and (e) parts are infrared thermal images[77]

    DownLoad: Full-Size Img PowerPoint

    表 1  近年来Cu2Se薄膜热电性能研究进展

    Table 1.  Research progress of Cu2Se thin film thermoelectric properties in recent years.

    MethodsFilmCu/SeCrystallite
    size/mm    		S/μV·K–1σ/
    ×103 S/m    		κ/
    W·(m·K)–1    		PF/
    mW·(m·K2) –1    		ZTRef.
    Chemical
    deposition    		6001.83818[68]
    3302.1251[69]
    4031.9637.03917.8[70]
    17001.818.13 × 103[71]
    Pulsed laser
    deposition    		401.7 < 10450[72]
    23457130619[10]
    6010350[61]
    Electrochemial
    deposition    		90—1001.92—1.890.14—0.22[42]
    1.7840—5080270.771730.07[41]
    2.1913456130[73]
    Sputtering deposition1—3100010—100100[74]
    3—10100 > 1001
    48—1311.77737.31.4—4.9[5]
    600—8501—925—841001000.8 ± 0.11100.4[60]
    Spin coating
    process    		300—50044.603[75]
    62.61.9—1.995200—250250.626530.34[54]
    50—100801000.4—1.40.14[76]
    551.79 ± 0.06101.3—1.5620[40]
    Simple mechanical
    pressing    		10000—500001.74314.3557.820.79111.840.04[9]
    Wet-chemical
    process    		80001.9850.8104.70.25—0.3270.30.3[77]
    DownLoad: CSV
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  • Received Date:  10 October 2020
  • Accepted Date:  19 November 2020
  • Available Online:  29 March 2021
  • Published Online:  05 April 2021

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