Preparation and properties of 3D cross-finger electrode symmetrical micro capacitor based on PI

Weiwei JI; Peng GAO; Baocheng LIU; Zhankun MENG; He WANG; Xingjiang LIU

doi:10.11868/j.issn.1001-4381.2023.000018

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Journal of Materials Engineering ›› 2023, Vol. 51 ›› Issue (11) : 205-213. DOI: 10.11868/j.issn.1001-4381.2023.000018

RESEARCH ARTICLE

Preparation and properties of 3D cross-finger electrode symmetrical micro capacitor based on PI

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Abstract

With the development of the Internet of Things， the rapid development of miniaturized self-powered electronic products and further micro-modulation greatly stimulate the urgent demand for microscale electrochemical energy storage devices. In each electrochemical energy storage device， the supercapacitor based on the plane pattern shape is highly compatible with modern electronic products in terms of functional features such as miniaturization and integration. In this work， the flexible 3D interdigital electrode symmetric micro capacitor was prepared by the combination of semiconductor preparation technology and electrophoresis printing technology， and the 3D printing was carried out by using oxygen enriched activated carbon ink. The 3D interdigital symmetric electrode was prepared by adjusting and optimizing the electric field strength， line width， number of printing layers and other parameters. The energy dispersive spectrometer （EDS）， scanning electron microscopy（SEM），rheometer，electrochemical workstation and test system were used to characterize materials， pastes and microcapacitor devices， and to explore the influence of materials and pastes on the performance of 3D interdigital microcapacitor. The results that the 3D interdigital supercapacitor prepared by the combination of semiconductor and electrophoresis printing process has good performances， and its area capacitance can reach 22.3 mF·cm^-2. In addition， the device can achieve 96% capacity retention after 2000 cycles through packaging optimization. This simple and controllable 3D jet printing technology provides an effective way to prepare advanced miniaturized electrochemical energy storage devices.

Key words

flexible / interdigital electrode / 3D / micro capacitor

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Weiwei JI , Peng GAO , Baocheng LIU , et al . Preparation and properties of 3D cross-finger electrode symmetrical micro capacitor based on PI[J]. Journal of Materials Engineering. 2023, 51(11): 205-213 https://doi.org/10.11868/j.issn.1001-4381.2023.000018

References

List( Publishing order | Descend order by publishing year | Descend order by cited within ) Chart analysis

1	PECH D， BRUNET M， DUROU H， et al.Ultrahigh-power micrometre-sized supercapacitors based on onion-like carbon［J］. Nature Nanotechnology， 2010， 5（9）：651-654. Cited in this article [1]

2	QIU J， ZHAO H， LEI Y. Emerging smart design of electrodes for micro-supercapacitors：a review［J］.SmartMat，2022，3：447-473.

3	GUI X W， RUI Z， HONG Q Z， et al. Aqueous MXene inks for inkjet-printing microsupercapacitors with ultrahigh energy densities ［J］. Journal of Colloid and Interface Science， 2023，645：359-370. Cited in this article [1]

4	GRACE W， TEDDY S， MING L，et al.Printable photo-supercapacitor using single-walled carbon nanotubes［J］. Energy Environmental Science， 2011， 4（2）：413-416. Cited in this article [1]

5	HU H， PEI Z， YE C. Recent advances in designing and fabrication of planar micro-supercapacitors for on-chip energy storage［J］. Energy Storage Materials， 2015， 1：82-102. Cited in this article [1]

6	ZHANG F， WEI M， VISWANATHAN V， et al. 3D printing technologies for electrochemical energy storage［J］. Nano Energy， 2017， 40： 418-431. Cited in this article [1]

7	LU X， YU M， WANG G G， et al. Flexible solid-state supercapacitors： design， fabrication and applications［J］. Energy Environmental Science， 2014， 7（7）：2160. Cited in this article [1]

8	HYUN W J， SENSOR E B， KIM C H， et al. Scalable， self-aligned printing of flexible graphene micro-supercapacitors［J］. Advanced Energy Materials， 2017， 7（17）：1700285. Cited in this article [1]

9	WANG Z， CHENG Z L， ZHANG Y， et al. Laser printing-based high-resolution metal patterns with customizable design and scalable fabrication of high-performance flexible planar micro energy storage devices［J］.Chemical Engineering Journal，2022，429：132512. Cited in this article [1]

10	LIU Z， WU Z S， YANG S， et al. Ultraflexible in-plane micro-supercapacitors by direct printing of solution-processable electrochemically exfoliated graphene［J］. Advanced Materials， 2016， 28（11）：2217-2222.

11	KYEREMATENG N A， KYEREMATENG N A， BROUSSE T， et al. Microsupercapacitors as miniaturized energy-storage components for on-chip electronics［J］. Nature Nanotechnology， 2017， 12（1）：7-15. Cited in this article [1]

12	LI S， CHUN L D， XU T J， et al. Pure aqueous planar microsupercapacitors with ultrahigh energy density under wide temperature ranges ［J］. Advanced Functional Materials， 2022，32（33）：2203270. Cited in this article [1]

13	GUI X W， NUO L J， ZHOU X Z， Free-standing 3D porous energy hydrogels enabled by ion-induced gelation strategy for high-performance supercapacitors［J］.Applied Surface Science， 2022， 604： 154636.

14	SUN X， CHEN K， LIANG F， et al. Perspective on micro-supercapacitors［J］. Frontiers in Chemistry， 2022， 9： 807500. Cited in this article [1]

15	LIU L， YE， D， YU Y， et al. Carbon-based flexible micro-supercapacitor fabrication via mask-free ambient micro-plasma-jet etching［J］. Carbon， 2017， 111：121-127. Cited in this article [1]

16	ZHANG C， LORCAN M， MATTHIAS P K， et al. Additive-free MXene inks and direct printing of micro-supercapacitors［J］. Nature Communications， 2019， 10（1）： 1795. Cited in this article [1]

17	LI X， LI H， FAN X， et al. 3D-printed stretchable micro-supercapacitor with remarkable areal performance［J］.Advanced Energy Materials， 2020， 10（14）： 1903794. Cited in this article [1]

18	ABDOLHOSSEINZADEH S， SCHNEIDER R， VERMA A， et al. Turning trash into treasure： additive free MXene sediment inks for screen-printed micro-supercapacitors［J］. Advanced Materials， 2020， 32：2000716. Cited in this article [1]

19	JOST K， DANIEL S， CARLOS R， et al. Knitted and screen printed carbon-fiber supercapacitors for applications in wearable electronics［J］. Energy Environmental Science， 2013， 6（9）： 2698-2705. Cited in this article [1]

20	WAN Z， CHEN X， GU M. Laser scribed graphene for supercapacitors［J］. Opto Electronic Advances， 2021， 4（7）： 200079. Cited in this article [1]

21	WANG Y， ZHAO Y， QU L， Laser fabrication of functional micro-supercapacitors［J］. Journal of Energy Chemistry， 2021， 59： 642-665. Cited in this article [1]

22	GIANNAKOU P， TAS M O， LE B， et al. Water-transferred， inkjet-printed supercapacitors toward conformal and epidermal energy storage［J］. ACS Applied Materials Interfaces， 2020， 12：8456-8465. Cited in this article [1]

23	LI J， YANG P H， LI X Y， et al. Ultrathin smart energy-storage devices for skin-interfaced wearable electronics［J］. ACS Energy Letters， 2023， 8： 1-8. Cited in this article [1]

24	LIU W， LU C， LI H， et al. Paper-based all-solid-state flexible micro-supercapacitors with ultra-high rate and rapid frequency response capabilities［J］. Journal of Materials Chemistry， 2016， 4（10）：3754-3764. Cited in this article [1]

25	ZHANG Y Z， WANG Y， CHENG T， et al. Flexible supercapacitors based on paper substrates： a new paradigm for low-cost energy storage ［J］. Chemical Society Reviews， 2015， 44（15）：5181-5199. Cited in this article [1]

26	SEONG K， JUNG J， KANG J， et al. Direct printing of high-performance micro-supercapacitors on flexible substrates using polymeric stencil masks with highly precise interdigitated patterns［J］. Journal of Materials Chemistry A， 2020：1-10. Cited in this article [1]

27	COELHO J， KREMER M P， PINILLAL S， et al. An outlook on printed microsupercapacitors： technology status， remaining challenges， and opportunities［J］. Current Opinion in Electrochemistry， 2020， 21：69-75. Cited in this article [1]

28	GAO W， NEELAM SINGH， SONG L， et al. Direct laser writing of micro-supercapacitors on hydrated graphite oxide films［J］. Nature Nanotechnology， 2011， 6（8）：496-500. Cited in this article [1]

29	PENG Z， LIN J， YE R， et al. Flexible and stackable laser-induced graphene supercapacitors［J］. ACS Applied Materials and Interfaces， 2015， 7： 3414-3419.

30	DEWHURST J， ELLIOTT P， SHALLCROSS S， et al. Laser-induced intersite spin transfer［J］. Nano Letters， 2018， 18（3）： 1842-1848.

31	XIONG Z， LIAO C， WANG X， Reduced graphene oxide diffraction gratings from duplication of photoinduced azo polymer surface-relief-gratings through soft-lithography［J］. Journal of Materials Chemistry， 2015， 3（24）： 6224-6231. Cited in this article [1]

32	ZHANG H， QIAO Y， LU Z. Fully printed ultraflexible supercapacitor supported by a single-textile substrate［J］. ACS Applied Materials and Interfaces， 2016， 8（47）： 32317-32323. Cited in this article [1]

33	CHANG Y， CHEN J X， JIA J C， et al. The fluorine-doped and defects engineered carbon nanosheets as advanced electrocatalysts for oxygen electroreduction［J］.Applied Catalysis B， 2021， 284：119721. Cited in this article [1]

34	WANG S， MA L， GAN M Y， et al. Polyaniline nano-wrinkles array on three-dimensional graphene film for high performance supercapacitors［J］. Synthetic Metals， 2015， 210： 367-375. Cited in this article [1]

35	STRELKO V， MALIK D J， STREAT M. Characterisation of the surface of oxidised carbon adsorbents［J］. Carbon， 2002， 40（1）： 95-104. Cited in this article [1]

36	GIL A， PUENTE G， GRANGE P. Evidence of textural modifications of an activated carbon on liquid-phase oxidation treatments［J］. Microporous Materials， 1997， 12（1/3）： 51-61. Cited in this article [1]