Restricted accessResearch articleFirst published online 2018-3
Preparation of poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate)/silicon dioxide nanoparticles composite films with large thermoelectric power factor
Herein, poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate) (PEDOT:PSS)/silicon dioxide nanoparticles (SiO2-NPs) composite films were prepared via a simple method by direct vacuum filtration technique. The effect of SiO2-NPs contents on the thermoelectric performance of PEDOT:PSS was investigated systematically. PEDOT:PSS nanofilm without SiO2-NPs exhibited a maximum electrical conductivity of 1487 S cm−1 and a Seebeck coefficient of 17.4 µV/K. When the SiO2-NPs were introduced, the Seebeck coefficient of PEDOT:PSS/SiO2-NPs nanocomposite films increased to a peak value of 24.2 µV/K at 20 wt% SiO2-NPs, and the corresponding electrical conductivity was 1132 S/cm. Although a compromise in electrical conductivity, a large optimized power factor up to be 66.29 µW/m K2 was achieved due to the contribution of improved Seebeck coefficient. The presence of SiO2-NPs in the composite films with small-size structure and abundant grain boundaries may cause the carrier scattering and filtering effect, which accounts for the enhanced Seebeck coefficient.
ZhangBSunJKatzHEet al.Opila, Promising thermoelectric properties of commercial PEDOT:PSS materials and their Bi2Te3 powder composites. ACS Appl Mater Interf2010; 2: 3170–3178.
2.
LeeSHParkHKimSet al.Transparent and flexible organic semiconductor nanofilms with enhanced thermoelectric efficiency. J Mater Chem A2014; 2: 7288–7294.
3.
SongHJLiuCCXuJKet al.Fabrication of a layered nanostructure PEDOT:PSS/SWCNTs composite and its thermoelectric performance. RSC Adv2013; 3: 22065–22071–22065–22071.
RemeliMFTanLDateAet al.Simultaneous power generation and heat recovery using a heat pipe assisted thermoelectric generator system. Energy Convers Manage2015; 91: 110–119.
6.
KojdaDMitdankRMogilatenkoAet al.The effect of a distinct diameter variation on the thermoelectric properties of individual Bi0.39Te0.61 nanowires. Semicond Sci Technol2014; 29: 124006–124006.
LiJTangXLiHet al.Synthesis and thermoelectric properties of hydrochloric acid-doped polyaniline. Synth Met2010; 160: 1153–1158.
12.
DuYCaiKFChenSet al.Facile preparation and thermoelectric properties of Bi2Te3 based alloy nanosheet/PEDOT:PSS composite films. ACS Appl Mater Interf2014; 6: 5735–5743.
13.
SavagatrupSChanERenteria-GarciaSMet al.Plasticization of PEDOT:PSS by common additives for mechanically robust organic solar cells and wearable sensors. Adv Funct Mater2015; 25: 427–436.
14.
MengistieDAIbrahemMAWangPCet al.Highly conductive PEDOT:PSS treated with formic acid for ITO-free polymer solar cells. ACS Appl Mater Interf2014; 6: 2292–2299.
15.
WangZJBrownESMaldonadoS. Hybrid solar cells constructed of macroporous n-type GaP coated with PEDOT:PSS. Chin Chem Lett2015; 26: 469–473.
16.
ShiHLiuCCJiangQLet al.Effective approaches to improve the electrical conductivity of PEDOT:PSS: A review. Adv Electron Mater2015; 1: 1500017–1500033–1500017–1500033.
17.
LiZFMaGQGeRet al.Free-standing conducting polymer films for high-performance energy devices. Angew Chem2016; 128: 991–994.
18.
KaulPBDayKAAbramsonAR. Application of the three omega method for the thermal conductivity measurement of polyaniline. J Appl Phys2007; 101: 083507–083507.
19.
SongHJLiuCCZhuHFet al.Improved Thermoelectric Performance of Free-Standing PEDOT:PSS/Bi2Te3 Films with Low Thermal Conductivity. J Electron Mater2013; 42: 1268–1274.
20.
LiuCCLuBYYanJet al.Highly conducting free-standing poly(3,4-ethylenedioxythiophene)/poly(styrenesulfonate) films with improved thermoelectric performances. Synth Met2010; 160: 2481–2485.
21.
NardesAMKemerinkMKokMMet al.Conductivity, work function, and environmental stability of PEDOT:PSS thin films treated with sorbitol. Org Electron2008; 9: 727–734.
22.
XiaYJOuyangJ. Anion effect on salt-induced conductivity enhancement of poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) films. Org Electron2010; 11: 1129–1135.
23.
XiongJHJiangFXZhouWQet al.Highly electrical and thermoelectric properties of a PEDOT:PSS thin-film via direct dilution–filtration. RSC Adv2015; 5: 60708–60712.
24.
CrispinXJakobssonFLECrispinAet al.The Origin of the High Conductivity of Poly(3,4-ethylenedioxythiophene)-Poly(styrenesulfonate)(PEDOT-PSS) Plastic Electrodes. Chem Mater2006; 18: 4354–4360.
ZhuZYLiuCCShiHet al.An Effective Approach to Enhanced Thermoelectric Properties of PEDOT:PSS Films by a DES Post-Treatment. J Polym Sci Pol Phys2015; 53: 885–892.
27.
JiangQLLiuCCSongHJet al.Improved thermoelectric performance of PEDOT:PSS films prepared by polar-solvent vapor annealing method. J Mater Sci Mater Electron2013; 24: 4240–4246.
28.
XiaYJOuyangJY. PEDOT:PSS films with significantly enhanced conductivities induced by preferential solvation with cosolvents and their application in polymer photovoltaic cells. J Mater Chem2011; 21: 4927–4927.
29.
XiaYJZhangHMOuyangJY. Highly conductive PEDOT:PSS films prepared through a treatment with zwitterions and their application in polymer photovoltaic cells. J Mater Chem2010; 20: 9740–9740.
30.
JiangFXXiongJHZhouWQet al.Use of organic solvent-assisted exfoliated MoS2 for optimizing the thermoelectric performance of flexible PEDOT:PSS thin films. J Mater Chem A2016; 4: 5265–5273.
31.
KimJJangJGHongJIet al.Sulfuric acid vapor treatment for enhancing the thermoelectric properties of PEDOT:PSS thin-films. J Mater Sci Mater Electron2016; 27: 6122–6127.
32.
HeMQiuFLinZ. Towards high-performance polymer-based thermoelectric materials. Energ Environ Sci2013; 6: 1352–1361–1352–1361.
33.
LiFCaiKShenSChenS. Preparation and thermoelectric properties of reduced graphene oxide/PEDOT:PSS composite films. Syn Met2014; 197: 58–61.
34.
YooDKimJKimJH. Direct synthesis of highly conductive poly(3,4-ethylenedioxythiophene):poly(4-styrenesulfonate)(PEDOT:PSS)/graphene composites and their applications in energy harvesting systems. Nano Res2014; 7: 717–730.
35.
XiongJHJiangFXShiHet al.Liquid Exfoliated Graphene as Dopant for Improving the Thermoelectric Power Factor of Conductive PEDOT:PSS Nanofilm with Hydrazine Treatment. ACS Appl Mater Interf2015; 7: 14917–14925.
36.
WangHHsuJHYiSIet al.Thermally Driven Large N-Type Voltage Responses from Hybrids of Carbon Nanotubes and Poly(3,4-ethylenedioxythiophene) with Tetrakis(dimethylamino)ethylene. Adv Mater2015; 27: 6855–6861.
DuranASernaCFornesVet al.Structural considerations about SiO2 glasses prepared by sol-gel. J Non-Cryst Solids1986; 82: 69–77.
39.
GopalNONarasimhuluKVRaoJL. EPR, optical, infrared and Raman spectral studies of Actinolite mineral. Spectrochim Acta A2004; 60: 2441–2448.
40.
Al-OweiniREl-RassyH. Synthesis and characterization by FTIR spectroscopy of silica aerogels prepared using several Si(OR)4 and R′′Si(OR′)3 precursors. J Mol Struct2009; 919: 140–145.
41.
LiXLiuYShiZet al.Influence of draw ratio on the structure and properties of PEDOT-PSS/PAN composite conductive fibers. RSC Adv2014; 4: 40385–40389.
42.
AntoPLPanickerCYVargheseHTet al.Potential-dependent SERS profile of orthanilic acid on silver electrode. J Raman Spectrosc2006; 37: 1265–1271.
43.
LingHLuJPhuaSet al.One-pot sequential electrochemical deposition of multilayer poly (3,4-ethylenedioxythiophene):poly(4-styrenesulfonic acid) / tungsten trioxide hybrid films and their enhanced electrochromic properties. J Mater Chem A2014; 2: 2708–2717–2708–2717.
44.
LeeSHParkHSonWet al.Novel solution-processable, dedoped semiconductors for application in thermoelectric devices. J Mater Chem A2014; 2: 13380–13387–13380–13387.
KimGHHwangDHWooSI. Thermoelectric properties of nanocomposite thin films prepared with poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate) and grapheme. Phys Chem Chem Phys2012; 14: 3530–3536.
