pH敏感有机电化学晶体管<i>I</i>-<i>V</i>特性及其电压依赖性

李诗嘉; 王振兴; 牛焱; 王彬; 桑胜波; 张文栋; 高杨; 冀健龙

doi:10.7498/aps.71.20220241

摘要

pH敏感的有机电化学晶体管有望广泛用于可穿戴电子设备进行生理指标原位监测. 然而, pH敏感的有机电化学晶体管电流-电压(I-V)特性关系尚不明确, 这严重制约其设计、优化与应用等方面的发展. 本文联合电化学平衡方程与栅极/电解液、半导体沟道/电解液界面微分电容串联物理模型构建了pH敏感的有机电化学晶体管I-V特性方程. 进一步, 以聚3,4-乙烯二氧噻吩/聚苯乙烯磺酸盐为半导体层材料, 以pH敏感聚合物(聚3,4-乙烯二氧噻吩/溴百里酚蓝)修饰晶体管栅极, 构建pH敏感的有机电化学晶体管. 测试晶体管输出、转移及pH响应特征, 验证I-V特性方程的有效性. 实验结果表明, 该有机电化学晶体管的pH检测灵敏度为0.22 mA·pH·unit^–1, 并且晶体管pH响应具有栅极电压依赖特性. 引入栅极电压多项式进一步修正晶体管I-V特性方程. 理论模型对转移曲线实验结果的拟合优度达到0.998. 峰值跨导对应栅极电压位置、pH灵敏度响应栅极电压的实验及理论预测结果比较亦可表明修正理论模型的有效性. 研究结果可为基于pH敏感有机电化学晶体管的柔性生物传感器设计与制造提供理论支撑.

关键词:

有机电化学晶体管 /
电流-电压特性方程

Abstract

The pH-sensitive organic electrochemical transistors are expected to be widely used in wearable electronic devices for in-situ physiological monitoring. However, the unclear current-voltage relationship seriously hinders it from developing in design, optimization, and application. In the present work, the current-voltage characteristic of pH-sensitive organic electrochemical transistor is investigated by combining the electrochemical equilibrium equation with the series model of differential capacitances formed at gate electrode/electrolyte and semiconductor channel/electrolyte interface. Moreover, a pH-sensitive organic electrochemical transistor is constructed by using poly (3,4-ethylenedioxythiophene)/polystyrene sulfonate as the semiconductor layer material and modifying the gate electrode with pH-sensitive polymer (poly (3,4-ethylenedioxythiophene)/bromothymol blue). The effectiveness of the theoretical model is verified by investigating the output, transfer, and pH response characteristics of the pH-sensitive organic electrochemical transistor. The experimental results show that the detection sensitivity can reach up to 0.22 mA·pH·unit^–1, and the pH response is gate-bias dependent. Then, a polynomial indicating the gate bias effect is introduced to modify the current-voltage characteristic equation. The goodness of fitting the theoretical model to the experimental results of transfer curves is found to be 0.998. The comparison between experimental and theoretical results of the gate bias corresponding to the peak transconductance and pH sensitivity responding to gate bias can also verify the effectiveness of the modified theoretical model. The results can provide theoretical support for the design and manufacture of pH-sensitive organic electrochemical transistors based flexible biosensors.

Keywords:

organic electrochemical transistors /
current-voltage characteristics

作者及机构信息

1.
太原理工大学信息与计算机学院, 微纳传感与人工智能感知山西省重点实验室, 晋中　030600

2.
西南科技大学信息工程学院, 绵阳　621010

3.
清华大学集成电路学院, 北京　100084

通信作者: 冀健龙, jianlongji@yeah.net

基金项目: 国家自然科学基金(批准号: 52175542)、山西省基础研究计划自然科学研究面上项目(批准号: 20210302123136)、重庆市自然科学基金(批准号: cstc2020jcyj-msxmX0002)和中国博士后基金(批准号: 2020M673646)资助的课题.

Authors and contacts

1.
Key Laboratory of Micro-Nano Sensing and Artificial Intelligence Sensing of Shanxi Province, Institute of Information and Computer science, Taiyuan University of Technology, Jinzhong 030600, China

2.
Institute of Information Engineering, Southwest University of Science and Technology, Mianyang 621010, China

3.
Institute of Integrated Circuits, Tsinghua University, Beijing 100084, China

Corresponding author: Ji Jian-Long, jianlongji@yeah.net

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 52175542), the Natural Science Foundation of Shanxi Province, China (Grant No. 20210302123136), the Natural Science Foundation Project of Chongqing, China (Grant No. cstc2020jcyj-msxmX0002), and the China Postdoctoral Science Foundation (Grant No. 2020M673646).

文章全文 : translate this paragraph

参考文献

[1]	Rivnay J, Inal S, Salleo A, Owens R M, Berggren M, Malliaras G G 2018 Nat. Rev. Mater. 3 1 Google Scholar
[2]	Donahue M J, Williamson A, Strakosas X, Friedlein J T, McLeod R R, Gleskova H, Malliaras G G 2018 Adv. Mater. 30 1705031 Google Scholar
[3]	Liang Y, Wu C, Figueroa-Miranda G, Offenhaeusser A, Mayer D 2019 Biosens. Bioelectron. 144 111668 Google Scholar
[4]	Guo K, Wustoni S, Koklu A, Díaz-Galicia E, Moser M, Hama A, Alqahtani A A, Ahmad A N, Alhamlan F S, Shuaib M, Pain A, McCulloch I, Arold S T, Grünberg R, Inal S 2021 Nat. Biomed. Eng. 5 666 Google Scholar
[5]	White K A, Grillo-Hill B K, Barber D L 2017 J. Cell Sci. 130 663 Google Scholar
[6]	Mariani F, Gualandi I, Tessarolo M, Fraboni B, Scavetta E 2018 Nat. Rev. Mater. 10 22474
[7]	Scheiblin G, Coppard R, Owens R M, Mailley P, Malliaras G G 2017 Adv. Mater. Technol. 2 1600141 Google Scholar
[8]	Demuru S, Kunnel B P, Briand D 2020 Adv. Mater. Technol. 5 2000328 Google Scholar
[9]	Demuru S, Kunnel B P, Briand D 2021 Biosens. Bioelectron. X 7 100065
[10]	Mariani F, Gualandi I, Tonelli D, Decataldo F, Possanzini L, Fraboni B, Scavetta E 2020 Electrochem. Commun. 116 106763 Google Scholar
[11]	Bernards D A, Malliaras G G 2007 Adv. Funct. Mater. 17 3538 Google Scholar
[12]	Ji J L, Li M M, Chen Z W, Wang H W, Jiang X N, Zhuo K, Liu Y, Yang X, Gu Z, Sang S B, Shu Y 2019 Nano Res. 12 1943 Google Scholar
[13]	Moser M, Hidalgo T C, Surgailis J, Gladisch J, Ghosh S, Sheelamanthula R, Thiburce Q, Giovannitti A, Salleo A, Gasparini N, Wadsworth A, Zozoulenko I, Berggren M, Stavrinidou E, Inal S, McCulloch I 2020 Adv. Mater. 32 2002748 Google Scholar
[14]	Wu X, Surendran A, Ko J, Filonik O, Herzig E M, Müller-Buschbaum P, Leong W L 2019 Adv. Mater. 31 1805544 Google Scholar
[15]	Bidinger S L, Han S, Malliaras G G, Hasan T 2022 Appl. Phys. Lett. 120 073302 Google Scholar
[16]	He Y, Kukhta N A, Marks A, Luscombe C K 2022 J. Mater. Chem. C 10 2314 Google Scholar
[17]	Kim S H, Hong K, Xie W, Lee K H, Zhang S, Lodge T P, Frisbie C D 2013 Adv. Mater. 25 1822 Google Scholar
[18]	Yan Y, Chen Q, Wu X, Wang X, Li E, Ke Y, Liu Y, Chen H, Guo T 2020 ACS Appl. Mater. Interfaces 12 49915 Google Scholar
[19]	Rivnay J, Leleux P, Sessolo M, Khodagholy D, Hervé T, Fiocchi M, Malliaras G G 2013 Adv. Mater. 25 7010 Google Scholar

施引文献

图 1 有机电化学晶体管(OECT)　(a)结构制备示意图, 其中S, D, G分别表示OECT的源极、漏极与栅极; (b)OECT半导体沟道的原子力显微镜测试图; (c)修饰有PEDOT:BTB膜的OECT栅极激光共聚焦扫描显微镜测试图

Fig. 1. The organic electrochemical transistors (OECTs): (a) Schematic of structure preparation, S, D, and G represents the source, drain, and gate, respectively; (b) the atomic force microscope image of the semiconductor channel; (c) the laser confocal scanning microscope image of the gate electrode modified with PEDOT:BTB films.

下载: 全尺寸图片幻灯片

图 2 pH敏感的OECT　(a)结构示意图; (b)电路模型示意图

Fig. 2. pH-sensitive OECTs: (a) Structure schematic; (b) schematic of the circuit model.

下载: 全尺寸图片幻灯片

图 3 使用 (a) 5次、(b) 10次、(c) 20次循环伏安法(CV)电沉积制备PEDOT:BTB膜, 并以此修饰栅极获得的晶体管输出曲线与(d)转移曲线, 其中绿色、红色、蓝色转移曲线分别对应于图(a)、图(b)与图(c)

Fig. 3. Output curves of OECTs, PEDOT:BTB film modifying the gate electrode is obtained by (a) 5 cycles, (b) 10 cycles, and (c) 20 cycles of CV electrodepositions; (d) transfer curves of OECTs, in which the green, red, and blue curves correspond to (a), (b) and (c), respectively.

下载: 全尺寸图片幻灯片

图 4 栅极/电解质界面电容(C_G)与CV次数关系　(a)电化学阻抗谱(Electrochemical impedance spectroscopy, EIS)波特图; (b)由EIS获得的C_G等效电容(C_eff), 插图用10^–1 Hz处C_eff表示C_G, 其值随CV次数增大而增大. 绿色, 红色、蓝色曲线分别表示5, 10, 20次CV循环的测试结果

Fig. 4. Relationship between gate/electrolyte interface capacitance (C_G) and CV times: (a) The Bode electrochemical impedance spectroscopy (EIS); (b) the equivalent capacitance of C_G (C_eff). The inset shows that C_G, indicated by C_eff at 10^–1 Hz, increases with CV cycles. The green, red and blue curves represent the experimental results using 5, 10, and 20 CV cycles.

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图 5 晶体管pH响应与C_G的关系　(a)Δi_DS是基于pH = 2的源漏极瞬态电流(i_DS)归一化的pH响应; (b)Δi_DS/ΔpH随着C_G的增大而增大. 图中绿色, 红色、蓝色数据分别表示采用5, 10, 20次CV循环的测试结果

Fig. 5. The relationship between the pH sensitivity and CV cycle numbers: (a) Δi_DS represents the pH response normalized by the source-drain transient current (i_DS) obtained at pH = 2; (b) Δi_DS/ΔpH increases with the C_G increment. The green, red and blue data represent the experimental results using 5, 10, and 20 CV cycles, respectively.

下载: 全尺寸图片幻灯片

图 6 OECT对于pH值的响应　(a)不同V_G条件下OECT瞬态响应电流i_DS对于pH的响应, Δi_DS由任意pH条件下的i_DS与pH = 2的值归一化所得; (b)不同pH条件下晶体管的转移曲线; (c)不同pH条件下晶体管的跨导曲线; (d)不同V_G条件下OECT稳态响应电流I_DS对于pH的响应, ΔI_DS由任意pH条件下的I_DS与pH = 2时的值归一化所得

Fig. 6. The response of OECT to the ambient pH: (a) the effect of V_G on OECTs transient response (i_DS), Δi_DS is obtained by normalizing i_DS under specific pH level and the value at pH = 2; (b) OECTs transfer curves under different pH levels; (c) OECTs transconductance curves under different pH levels; (d) the effect of V_G on OECTs steady-state response (I_DS), ΔI_DS is obtained by normalizing I_DS under specific pH level and the value at pH = 2.

下载: 全尺寸图片幻灯片

图 7 实验结果与拟合数据比较　(a) OECT转移曲线; (b)由拟合转移曲线获得的跨导曲线; (c)不同pH条件下的峰值跨导对应的栅极电压, 蓝色与红色分别代表实验与拟合结果; (d) V_G对于晶体管pH响应的影响, 蓝色与红色分别代表实验与拟合结果

Fig. 7. Comparisons of experimental and fitting results: (a) Transfer curves; (b) transconductance curves derived by the fitting transfer curves; (c) the gate bias corresponding to the peak transconductance under different pH levels; (d) the effect of V_G on the pH response of transistors. The blue and red data in (c) and (d) represent the experimental and fitting results, respectively.

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表 1 不同pH敏感OECT的性能对比

Table 1. Performance comparison of pH sensitive OECTs

文献	敏感材料	灵敏度 (μA^.pH^–1)	归一化灵敏度 (pH^–1)	检测范围
[7]	聚苯胺	5.25	—	5—6.7
[9]	聚苯胺	16	—	4—10
[7]	氧化铱	9.5	—	5—7.3
[8]	氢离子选择性膜	11	—	4—7
[6]	PEDOT:BTB	—	14.8	2.3—9.2
本文	PEDOT:BTB	220	—	2—9

下载: 导出CSV

[1]	Rivnay J, Inal S, Salleo A, Owens R M, Berggren M, Malliaras G G 2018 Nat. Rev. Mater. 3 1 Google Scholar
[2]	Donahue M J, Williamson A, Strakosas X, Friedlein J T, McLeod R R, Gleskova H, Malliaras G G 2018 Adv. Mater. 30 1705031 Google Scholar
[3]	Liang Y, Wu C, Figueroa-Miranda G, Offenhaeusser A, Mayer D 2019 Biosens. Bioelectron. 144 111668 Google Scholar
[4]	Guo K, Wustoni S, Koklu A, Díaz-Galicia E, Moser M, Hama A, Alqahtani A A, Ahmad A N, Alhamlan F S, Shuaib M, Pain A, McCulloch I, Arold S T, Grünberg R, Inal S 2021 Nat. Biomed. Eng. 5 666 Google Scholar
[5]	White K A, Grillo-Hill B K, Barber D L 2017 J. Cell Sci. 130 663 Google Scholar
[6]	Mariani F, Gualandi I, Tessarolo M, Fraboni B, Scavetta E 2018 Nat. Rev. Mater. 10 22474
[7]	Scheiblin G, Coppard R, Owens R M, Mailley P, Malliaras G G 2017 Adv. Mater. Technol. 2 1600141 Google Scholar
[8]	Demuru S, Kunnel B P, Briand D 2020 Adv. Mater. Technol. 5 2000328 Google Scholar
[9]	Demuru S, Kunnel B P, Briand D 2021 Biosens. Bioelectron. X 7 100065
[10]	Mariani F, Gualandi I, Tonelli D, Decataldo F, Possanzini L, Fraboni B, Scavetta E 2020 Electrochem. Commun. 116 106763 Google Scholar
[11]	Bernards D A, Malliaras G G 2007 Adv. Funct. Mater. 17 3538 Google Scholar
[12]	Ji J L, Li M M, Chen Z W, Wang H W, Jiang X N, Zhuo K, Liu Y, Yang X, Gu Z, Sang S B, Shu Y 2019 Nano Res. 12 1943 Google Scholar
[13]	Moser M, Hidalgo T C, Surgailis J, Gladisch J, Ghosh S, Sheelamanthula R, Thiburce Q, Giovannitti A, Salleo A, Gasparini N, Wadsworth A, Zozoulenko I, Berggren M, Stavrinidou E, Inal S, McCulloch I 2020 Adv. Mater. 32 2002748 Google Scholar
[14]	Wu X, Surendran A, Ko J, Filonik O, Herzig E M, Müller-Buschbaum P, Leong W L 2019 Adv. Mater. 31 1805544 Google Scholar
[15]	Bidinger S L, Han S, Malliaras G G, Hasan T 2022 Appl. Phys. Lett. 120 073302 Google Scholar
[16]	He Y, Kukhta N A, Marks A, Luscombe C K 2022 J. Mater. Chem. C 10 2314 Google Scholar
[17]	Kim S H, Hong K, Xie W, Lee K H, Zhang S, Lodge T P, Frisbie C D 2013 Adv. Mater. 25 1822 Google Scholar
[18]	Yan Y, Chen Q, Wu X, Wang X, Li E, Ke Y, Liu Y, Chen H, Guo T 2020 ACS Appl. Mater. Interfaces 12 49915 Google Scholar
[19]	Rivnay J, Leleux P, Sessolo M, Khodagholy D, Hervé T, Fiocchi M, Malliaras G G 2013 Adv. Mater. 25 7010 Google Scholar

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pH敏感有机电化学晶体管I-V特性及其电压依赖性