Flexible dual functional piezoelectric pyroelectric sensor for high temperature applications

Yinhui Li , Kai Fan , Qiguo Li , Jinrong Sun , Yuen Jin , Gangyi Li , Jianguo Liang , Yunlei Zhou , Guibin Bian , YongAn Huang

Soft Science ›› 2026, Vol. 6 ›› Issue (2) -31.

PDF
Soft Science ›› 2026, Vol. 6 ›› Issue (2) -31. DOI: 10.20517/ss.2025.156
Research Article
Flexible dual functional piezoelectric pyroelectric sensor for high temperature applications
Author information +
History +
PDF

Abstract

Prolonged operation of mechanical components under high-temperature environment severely affects their performance and service life. It is urgently needed a high-temperature resistance sensor to monitor local temperature changes in the component to enhance the safety. However, conventional sensors are difficult to simultaneously achieve excellent sensing performance and conformability at high-temperature environments for curved surfaces. Herein, a polyacrylonitrile (PAN)/zirconium acetate [Zr(OAc)4]-based flexible and high-temperature-resistant piezo/pyroelectric bifunctional sensors are fabricated via heat treatment and typical package method. Incorporation of Zr(OAc)4 reduced the cyclization temperature of PAN molecular chains and effectively enhanced both the mechanical properties and electrical output of the composite membranes sensor. Compared to pure PAN, the PAN/Zr(OAc)4 composite nanofiber sensor (heat-treated at 450 °C) exhibits higher voltage output (~12.9 V) and piezoelectric sensitivity (~1.67 V/N) at room temperature. In addition, the sensor exhibits excellent pyroelectric output performance across a wide temperature gradient range, enabling accurate detection of engine temperature fluctuations. Remarkably, the sensor maintain stable piezoelectric and pyroelectric outputs after 5,000 press-release cycles at 400 °C, highlighting its robustness under extreme conditions. These results demonstrate that PAN/Zr(OAc)4 sensor provides reliable, flexible, and multifunctional solutions for real-time temperature monitoring in automobile engines, offering substantial benefits for extending engine lifespan and ensuring driving safety.

Keywords

PAN/Zr(OAc)4 composite nanofiber sensors / piezo/pyroelectric bifunctionality / high-temperature resistance / flexibility / temperature warning

Cite this article

Download citation ▾
Yinhui Li, Kai Fan, Qiguo Li, Jinrong Sun, Yuen Jin, Gangyi Li, Jianguo Liang, Yunlei Zhou, Guibin Bian, YongAn Huang. Flexible dual functional piezoelectric pyroelectric sensor for high temperature applications. Soft Science, 2026, 6(2): -31 DOI:10.20517/ss.2025.156

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Liu Z,Jiang Z.Flexible temperature sensor with high sensitivity ranging from liquid nitrogen temperature to 1200 °C.Int J Extrem Manuf2023;5:015601

[2]

Liu Y,Liu T.Triboelectric tactile sensor for pressure and temperature sensing in high-temperature applications.Nat Commun2025;16:383 PMCID:PMC11698958
[3]

Li Y,Wen C,Luo Z.Rub-impact dynamic analysis of a dual-rotor system with bolted joint structure: theoretical and experimental investigations.Mech Syst Signal Process2024;209:111144

[4]

Liu H,Lei S.In-service aircraft engines turbine blades life prediction based on multi-modal operation and maintenance data.Propuls Power Res2021;10:360-73

[5]

Zhang X,Gao X.High-temperature and flexible piezoelectric sensors for lamb-wave-based structural health monitoring.ACS Appl Mater Interfaces2021;13:47764-72

[6]

Chen S,Zhang C.Flexible piezoresistive three-dimensional force sensor based on interlocked structures.Sens Actuators A Phys2021;330:112857

[7]

Xu C,Zhang J.Three-dimensional micro strain gauges as flexible, modular tactile sensors for versatile integration with micro- and macroelectronics.Sci Adv2024;10:eadp6094 PMCID:PMC11338218
[8]

Khan B,Khan B.Next-generation piezoelectric materials in wearable and implantable devices for continuous physiological monitoring.Adv Sci2025;12:e07853 PMCID:PMC12591194
[9]

Li M,Yaseen S.High performance piezoelectric nanogenerator based on aligned single crystal BaTiO3 nanowires for self-powered applications.Chem Eng J2025;516:163834

[10]

Kumar M,Kumari P.Piezoelectric performance enhancement of electrospun functionally graded PVDF/BaTiO3 based flexible nanogenerators.Mater Res Bull2024;174:112739

[11]

Yuan L,Yang X.Piezoelectric PAN/BaTiO3 nanofiber membranes sensor for structural health monitoring of real-time damage detection in composite.Compos Commun2021;25:100680

[12]

King D,Vinayak S.A gas ionization sensor with a novel pyroelectric lithium niobate crystal as a voltage source.Sens Actuators A Phys2025;389:116544

[13]

Wang G,Gao X.Near stoichiometric lithium niobate crystal with dramatically enhanced piezoelectric performance for high-temperature acceleration sensing.J Mater Chem C2024;12:16357-66

[14]

Dagdeviren C,Joe P.Conformable amplified lead zirconate titanate sensors with enhanced piezoelectric response for cutaneous pressure monitoring.Nat Commun2014;5:4496

[15]

Yuan Y,Li N.Bottom electrode effects on piezoelectricity of Pb(Zr0.52,Ti0.48)O3 thin film in flexible sensor applications.Materials2023;16:7470 PMCID:PMC10707225
[16]

Sun Y,Li Q.Piezoelectric property of a tetragonal (Ba,Ca)(Zr,Ti)O3 single crystal and its fine-domain structure.ACS Appl Mater Interfaces2018;10:12847-53

[17]

Costa CM,Martins P.Smart and multifunctional materials based on electroactive poly(vinylidene fluoride): recent advances and opportunities in sensors, actuators, energy, environmental, and biomedical applications.Chem Rev2023;123:11392-487 PMCID:PMC10571047
[18]

Peng R,Dong G.Enhanced piezoelectric energy harvester by employing freestanding single‐crystal BaTiO3 films in PVDF‐TrFE based composites.Adv Funct Mater2024;34:2316519

[19]

Zhang H,Qiu C.Polyaniline/ZnO heterostructure-based ammonia sensor self-powered by electrospinning of PTFE-PVDF/MXene piezo-tribo hybrid nanogenerator.Chem Eng J2024;496:154226

[20]

Qian F,Cheng M.An overview of polylactic acid (PLA) nanocomposites for sensors.Adv Compos Hybrid Mater2024;7:75

[21]

Li Z,Wu B.Interfacial-engineered robust and high performance flexible polylactic acid/polyaniline/MXene electrodes for high-perfarmance supercapacitors.J Mater Sci Technol2024;203:201-10

[22]

Peng W,Zhang M,Li X.Biodegradable flexible conductive film based on sliver nanowires and PLA electrospun fibers.J Appl Polym Sci2024;141:e55433

[23]

Zhao X,Wang X,Zhou W.Strong synergistic toughening and compatibilization enhancement of carbon nanotubes and multi-functional epoxy compatibilizer in high toughened polylactic acid (PLA)/poly (butylene adipate-co-terephthalate) (PBAT) blends.Int J Biol Macromol2023;250:126204

[24]

Azimi B,Lazzeri A.Electrospinning piezoelectric fibers for biocompatible devices.Adv Healthc Mater2020;9:e1901287 PMCID:PMC6949425
[25]

Lee HJ.Design of low-loss 1-3 piezoelectric composites for high-power transducer applications.IEEE Trans Ultrason Ferroelectr Freq Control2012;59:1969-75 PMCID:PMC3666951
[26]

Jian G,Meng Q.Excellent high-temperature piezoelectric energy harvesting properties in flexible polyimide/3D PbTiO3 flower composites.Nano Energy2021;82:105778

[27]

Hyeon DY,Lee S.High-temperature workable flexible piezoelectric energy harvester comprising thermally stable (K,Na)NbO3-based ceramic and polyimide composites.Compos Part B Eng2022;234:109671

[28]

Zhang X,Shi X.Heteroepitaxy of flexible piezoelectric Pb(Zr0.53Ti0.47)O3 sensor on inorganic mica substrate for lamb wave-based structural health monitoring.Ceram Int2021;47:13156-63

[29]

Kaur G,Jassal M.ZnO-poly(acrylonitrile) composite films with improved piezoelectric properties for energy harvesting and sensing applications.Compos Sci Technol2023;243:110260

[30]

Wang W,Sun Y.High-temperature piezoelectric conversion using thermally stabilized electrospun polyacrylonitrile membranes.J Mater Chem A2021;9:20395-404

[31]

Klinar K,Franco V,Kitanovski A.Perspectives and energy applications of magnetocaloric, pyromagnetic, electrocaloric, and pyroelectric materials.Adv Energy Mater2024;14:2401739

[32]

Yin R,Li W.High-temperature flexible electric Piezo/pyroelectric bifunctional sensor with excellent output performance based on thermal-cyclized electrospun PAN/Zn(Ac)2 nanofiber mat.Nano Energy2024;124:109488

[33]

Li Y,Liang K.Enhanced piezoelectric performance of multi-layered flexible polyvinylidene fluoride–BaTiO3–rGO films for monitoring human body motions.J Mater Sci Mater Electron2022;33:4291-304

[34]

Dang W,Wang X.Structural transformation of polyacrylonitrile (PAN) fibers during rapid thermal pretreatment in nitrogen atmosphere.Polymers2020;12:63 PMCID:PMC7023665
[35]

Chao HW,Chen YR.Characterizing the dielectric properties of carbon fiber at different processing stages.Sci Rep2021;11:17475 PMCID:PMC8410780
[36]

Zhang W,Shen Z,Wang X.Effect of diameter on the structural evolution and tensile properties of electrospun PAN-based carbon nanofiber mats.ACS Omega2023;8:19002-5 PMCID:PMC10233825
[37]

Love-Baker CA,Vautard F,Li X.Analysis of the turbostratic structures in PAN-based carbon fibers with wide-angle x-ray diffraction.Carbon2024;224:119037

[38]

Podder S,Mukherjee C,Jana S.Fabrication and characterization of sol–gel-based coatings on quartz glass to obtain antireflective effect at 1054 nm for optics of high power Nd:phosphate glass laser.Bull Mater Sci2022;45:2732

[39]

Zeng J,Liu J,Guo S.Interaction between thermal stabilization temperature program, oxidation reaction, and mechanical properties of polyacrylonitrile (PAN) based carbon fibers.Diamond Relat Mater2024;141:110588

[40]

Liu Y,Shang L.Study on the structural evolution of polyacrylonitrile fibers in stepwise heat treatment process and its relationship with properties.J Appl Polym Sci2022;139:52077

[41]

Zhou H,Wang H.Tuning of structural/functional feature of carbon fibers: new insights into the stabilization of polyacrylonitrile.Polymer2023;282:126157

[42]

He Z,Zhang S.Investigation of the cyclization mechanism of poly(acrylonitrile-co-ethylenesulfonic acid) copolymer during thermal oxidative stabilization by in situ infrared spectroscopy.Ind Eng Chem Res2020;59:9519-31

[43]

Sun Y,Zheng Y.Enhanced energy harvesting ability of ZnO/PAN hybrid piezoelectric nanogenerators.ACS Appl Mater Interfaces2020;12:54936-45

[44]

Jie L.Structural changes during the thermal stabilization of modified and original polyacrylonitrile precursors.J Appl Polym Sci2005;97:2047-53

[45]

Ahn H,Lee BS.Designing materials and processes for strong polyacrylonitrile precursor fibers.Polymers2021;13:2863 PMCID:PMC8434603
[46]

Zhang X,Nishijima A.Thermal transformation of polyacrylonitrile accelerated by the formation of ultrathin nanosheets in a metal-organic framework.ACS Macro Lett2023;12:415-20

[47]

Zeng W,Shen Y.Conformational selection of polymer chains upon π-π interactions with small molecules.Phys Rev Lett2024;133:178101

[48]

Konstantopoulos G,Dragatogiannis D.Introduction of a methodology to enhance the stabilization process of PAN fibers by modeling and advanced characterization.Materials2020;13:2749 PMCID:PMC7344712
[49]

Wang C,Xin Z.Effect of monomethyl itaconate on thermal stabilization and rheological properties of narrow polydispersity polyacrylonitrile synthesized in continuous flow.Eur Polym J2024;210:112931

[50]

Kissinger HE.Reaction kinetics in differential thermal analysis.Anal Chem1957;29:1702-6

[51]

Valdez S.Understanding non-isothermal crystallization behaviors of polyethylene-derived vitrimers.Macromolecules2025;58:9348-57 PMCID:PMC12424294
[52]

Tabbagh A,Jougnot D.Experimental and numerical analysis of dielectric polarization effects in near‐surface earth materials in the 100 Hz-10 MHz frequency range: first interpretation paths.Near Surf Geophys2024;22:468-81

[53]

Li J,Xu Z.High-temperature-resistant dual-scale ceramic nanofiber films toward improved air filtration.ACS Appl Mater Interfaces2024;16:60608-15

[54]

Pan F,Shi Y.Heterointerface engineering of β-chitin/carbon nano-onions/Ni-P composites with boosted Maxwell-Wagner-Sillars effect for highly efficient electromagnetic wave response and thermal management.Nanomicro Lett2022;14:85 PMCID:PMC8964898
[55]

Liu L,Xu K.High piezoelectric property with exceptional stability in self-poled ferroelectric films.Nat Commun2024;15:10798 PMCID:PMC11685493
[56]

Ye J,Wu X.Development and performance research of PSN-PZT piezoelectric ceramics based on road vibration energy harvesting technology.Mater Today Commun2023;34:105135

[57]

Pan D.Lead zirconate titanate (PZT) piezoelectric ceramics: applications and prospects in human motion monitoring.Ceram Silik2024;68:444-58

[58]

Kim N,Chen J.Piezoelectric pressure sensor based on flexible gallium nitride thin film for harsh-environment and high-temperature applications.Sens Actuators A Phys2020;305:111940

[59]

Liu S L,Wu QF.Highly sensitive flexible high-temperature sensor based on ITO/In2O3 for underwater hot spring monitoring.Sci China Mater2025;68:4115-24

[60]

He P,Zhang B.Mechanically robust porous polyimide films for piezoelectric sensing at extreme condition.Compos Sci Technol2025;261:111006

PDF

0

Accesses

0

Citation

Detail
Sections
Recommended

/