[1] XR Zheng, BH Jia, H Lin, L Qiu, D Li et al. Highly efficient and ultra-broadband graphene oxide ultrathin lenses with three-dimensional subwavelength focusing. Nat Commun, 6, 8433(2015).

[2] XW Yun, ZY Xiong, L Tu, LQ Bai, XG Wang. Hierarchical porous graphene film: an ideal material for laser-carving fabrication of flexible micro-supercapacitors with high specific capacitance. Carbon, 125, 308-317(2017).

[3] S Bellani, B Martín-García, R Oropesa-Nuñez, V Romano, L Najafi et al. “Ion sliding” on graphene: a novel concept to boost supercapacitor performance. Nanoscale Horiz, 4, 1077-1091(2019).

[4] MM Wu, YR Li, BW Yao, J Chen, C Li et al. A high-performance current collector-free flexible in-plane micro-supercapacitor based on a highly conductive reduced graphene oxide film. J Mater Chem A, 4, 16213-16218(2016).

[5] CM Chen, Q Zhang, MG Yang, CH Huang, YG Yang et al. Structural evolution during annealing of thermally reduced graphene nanosheets for application in supercapacitors. Carbon, 50, 3572-3584(2012).

[6] GW Huang, N Li, Y Du, QP Feng, HM Xiao et al. Laser-printed in-plane micro-supercapacitors: from symmetric to asymmetric structure. ACS Appl Mater Interfaces, 10, 723-732(2018).

[7] B Zhao, P Liu, Y Jiang, DY Pan, HH Tao et al. Supercapacitor performances of thermally reduced graphene oxide. J Power Sources, 198, 423-427(2012).

[8] YM Chen, MH Guo, L He, W Yang, L Xu et al. Scalable microfabrication of three-dimensional porous interconnected graphene scaffolds with carbon spheres for high-performance all carbon-based micro-supercapacitors. J Mater, 5, 303-312(2019).

[9] AK Geim, KS Novoselov. The rise of graphene. Nat Mater, 6, 183-191(2007).

[10] GJ Li. Direct laser writing of graphene electrodes. J Appl Phys, 127, 010901(2020).

[11] Y Zhao, Q Han, ZH Cheng, L Jiang, LT Qu. Integrated graphene systems by laser irradiation for advanced devices. Nano Today, 12, 14-30(2017).

[12] KS Novoselov, AK Geim, SV Morozov, D Jiang, Y Zhang et al. Electric field effect in atomically thin carbon films. Science, 306, 666-669(2004).

[13] S Bae, H Kim, Y Lee, XF Xu, JS Park et al. Roll-to-roll production of 30-inch graphene films for transparent electrodes. Nat Nanotech, 5, 574-578(2010).

[14] SJ Wang, Y Geng, QB Zheng, JK Kim. Fabrication of highly conducting and transparent graphene films. Carbon, 48, 1815-1823(2010).

[15] ZF Wan, EW Streed, M Lobino, SJ Wang, RT Sang et al. Laser-reduced graphene: synthesis, properties, and applications. Adv Mater Technol, 3, 1700315(2018).

[16] DS Bergsman, BA Getachew, CB Cooper, JC Grossman. Preserving nanoscale features in polymers during laser induced graphene formation using sequential infiltration synthesis. Nat Commun, 11, 3636(2020).

[17] L Guo, HB Jiang, RQ Shao, YL Zhang, SY Xie et al. Two-beam-laser interference mediated reduction, patterning and nanostructuring of graphene oxide for the production of a flexible humidity sensing device. Carbon, 50, 1667-1673(2012).

[18] XP Li, HR Ren, X Chen, J Liu, Q Li et al. Athermally photoreduced graphene oxides for three-dimensional holographic images. Nat Commun, 6, 6984(2015).

[19] MS Loeian, SM Aghaei, F Farhadi, V Rai, HW Yang et al. Liquid biopsy using the nanotube-ctc-chip: capture of invasive ctcs with high purity using preferential adherence in breast cancer patients. Lab Chip, 19, 1899-1915(2019).

[20] W Gao, N Singh, L Song, Z Liu, ALM Reddy et al. Direct laser writing of micro-supercapacitors on hydrated graphite oxide films. Nat Nanotech, 6, 496-500(2011).

[21] T Kavinkumar, P Kavitha, N Naresh, S Manivannan, M Muneeswaran et al. High performance flexible solid-state symmetric supercapacitors based on laser induced porous reduced graphene oxide-graphene oxide hybrid nanostructure devices. Appl Surf Sci, 480, 671-679(2019).

[22] SD Luo, PT Hoang, T Liu. Direct laser writing for creating porous graphitic structures and their use for flexible and highly sensitive sensor and sensor arrays. Carbon, 96, 522-531(2016).

[23] AF Carvalho, AJS Fernandes, C Leitão, J Deuermeier, AC Marques et al. Laser-induced graphene strain sensors produced by ultraviolet irradiation of polyimide. Adv Funct Mater, 28, 1805271(2018).

[24] ZF Wan, M Umer, M Lobino, D Thiel, NT Nguyen et al. Laser induced self-n-doped porous graphene as an electrochemical biosensor for femtomolar miRNA detection. Carbon, 163, 385-394(2020).

[25] ZF Wan, NT Nguyen, YS Gao, Q Li. Laser induced graphene for biosensors. Sustain Mater Technol, 25, e00205(2020).

[26] RZ Li, J Yan, YM Fang, XY Fan, LK Sheng et al. Laser-scribed lossy microstrip lines for radio frequency applications. Appl Sci, 9, 415(2019).

[27] SM Kang, K Lim, H Park, JB Park, SC Park et al. Roll-to-roll laser-printed graphene-graphitic carbon electrodes for high-performance supercapacitors. ACS Appl Mater Interfaces, 10, 1033-1038(2018).

[28] L Zhang, D DeArmond, NT Alvarez, R Malik, N Oslin et al. Flexible micro-supercapacitor based on graphene with 3D structure. Small, 13, 1603114(2017).

[29] JL Ye, HB Tan, SL Wu, K Ni, F Pan et al. Direct laser writing of graphene made from chemical vapor deposition for flexible, integratable micro-supercapacitors with ultrahigh power output. Adva Mater, 30, e1801384(2018).

[30] YN Zhang, L Shi, DJ Hu, SR Chen, SY Xie et al. Full-visible multifunctional aluminium metasurfaces by in situ anisotropic thermoplasmonic laser printing. Nanoscale Horiz, 4, 601-609(2019).

[31] H Lin, BH Jia, M Gu. Dynamic generation of debye diffraction-limited multifocal arrays for direct laser printing nanofabrication. Opt Lett, 36, 406-408(2011).

[32] YC Jia, SX Wang, F Chen. Femtosecond laser direct writing of flexibly configured waveguide geometries in optical crystals: fabrica-tion and application. Opto-Electron Adv, 3, 190042(2020).

[33] YL Zhang, L Guo, S Wei, YY He, H Xia et al. Direct imprinting of microcircuits on graphene oxides film by femtosecond laser reduction. Nano Today, 5, 15-20(2010).

[34] ZW Peng, J Lin, RQ Ye, ELG Samuel, JM Tour. Flexible and stackable laser-induced graphene supercapacitors. ACS Appl Mater Interfaces, 7, 3414-3419(2015).

[35] H Wu, WL Zhang, S Kandambeth, O Shekhah, M Eddaoudi et al. Conductive metal–organic frameworks selectively grown on laser‐scribed graphene for electrochemical microsupercapacitors. Adv Energy Mater, 9, 1900482(2019).

[36] R Rahimi, M Ochoa, WY Yu, B Ziaie. Highly stretchable and sensitive unidirectional strain sensor via laser carbonization. ACS Appl Mater Interfaces, 7, 4463-4470(2015).

[37] RK Singh, R Kumar, DP Singh. Graphene oxide: strategies for synthesis, reduction and frontier applications. RSC Adv, 6, 64993-65011(2016).

[38] NQ Deng, H Tian, ZY Ju, HM Zhao, C Li et al. Tunable graphene oxide reduction and graphene patterning at room temperature on arbitrary substrates. Carbon, 109, 173-181(2016).

[39] VA Smirnov, AA Arbuzov, YM Shul’ga, SA Baskakov, VM Martynenko et al. Photoreduction of graphite oxide. High Energy Chem, 45, 57-61(2011).

[40] GC Wang, ZY Yang, XW Li, CZ Li. Synthesis of poly(aniline-co-o-anisidine)-intercalated graphite oxide composite by delamination/reassembling method. Carbon, 43, 2564-2570(2005).

[41] ZF Wan, SJ Wang, B Haylock, J Kaur, P Tanner et al. Tuning the sub-processes in laser reduction of graphene oxide by adjusting the power and scanning speed of laser. Carbon, 141, 83-91(2019).

[42] DW Wang, YG Min, YH Yu, B Peng. Laser induced self-propagating reduction and exfoliation of graphite oxide as an electrode material for supercapacitors. Electrochim Acta, 141, 271-278(2014).

[43] L Huang, Y Liu, LC Ji, YQ Xie, T Wang et al. Pulsed laser assisted reduction of graphene oxide. Carbon, 49, 2431-2436(2011).

[44] Y Hu, HH Cheng, F Zhao, N Chen, L Jiang et al. All-in-one graphene fiber supercapacitor. Nanoscale, 6, 6448-6451(2014).

[45] HH Cheng, MH Ye, F Zhao, CG Hu, Y Zhao et al. A general and extremely simple remote approach toward graphene bulks with in situ multifunctionalization. Adv Mater, 28, 3305-3312(2016).

[46] HH Shi, S Jang, HE Naguib. Freestanding laser-assisted reduced graphene oxide microribbon textile electrode fabricated on a liquid surface for supercapacitors and breath sensors. ACS Appl Mater Interfaces, 11, 27183-27191(2019).

[47] KH Ibrahim, M Irannejad, M Hajialamdari, A Ramadhan, KP Musselman et al. A novel femtosecond laser-assisted method for the synthesis of reduced graphene oxide gels and thin films with tunable properties. Adv Mater Interfaces, 3, 1500864(2016).

[48] J Lin, ZW Peng, YY Liu, F Ruiz-Zepeda, RQ Ye et al. Laser-induced porous graphene films from commercial polymers. Nat Commun, 5, 5714(2014).

[49] ZC Zhang, MM Song, JX Hao, KB Wu, CY Li et al. Visible light laser-induced graphene from phenolic resin: a new approach for directly writing graphene-based electrochemical devices on various substrates. Carbon, 127, 287-296(2018).

[50] LJ Cao, SR Zhu, BB Pan, XY Dai, WW Zhao et al. Stable and durable laser-induced graphene patterns embedded in polymer substrates. Carbon, 163, 85-94(2020).

[51] A Lamberti, M Serrapede, G Ferraro, M Fontana, F Perrucci et al. All-SPEEK flexible supercapacitor exploiting laser-induced graphenization. 2D Mater, 4, 035012(2017).

[52] RQ Ye, Y Chyan, JB Zhang, YL Li, X Han et al. Laser-induced graphene formation on wood. Adv Mater, 29, 1702211(2017).

[53] Y Chyan, RQ Ye, YL Li, SP Singh, CJ Arnusch et al. Laser-induced graphene by multiple lasing: toward electronics on cloth, paper, and food. ACS Nano, 12, 2176-2183(2018).

[54] WL Zhang, YJ Lei, FW Ming, Q Jiang, PMFJ Costa et al. Lignin laser lithography: a direct-write method for fabricating 3D graphene electrodes for microsupercapacitors. Adv Energy Mater, 8, 1801840(2018).

[55] V Strauss, K Marsh, MD Kowal, M El-Kady, RB Kaner. A simple route to porous graphene from carbon nanodots for supercapacitor applications. Adv Mater, 30, 1704449(2018).

[56] JH Zhang, T Zhou, L Wen, AM Zhang. Fabricating metallic circuit patterns on polymer substrates through laser and selective metallization. ACS Appl Mater Interfaces, 8, 33999-34007(2016).

[57] JG Cai, C Lv, A Watanabe. Laser direct writing and selective metallization of metallic circuits for integrated wireless devices. ACS Appl Mater Interfaces, 10, 915-924(2018).

[58] HL Liu, Y Tang, YX Xie, LS Lu, ZP Wan et al. Effect of pulsed ND:YAG laser processing parameters on surface properties of polyimide films. Surf Coat Technol, 361, 102-111(2019).

[59] DF Yang, C Bock. Laser reduced graphene for supercapacitor applications. J Power Sources, 337, 73-81(2017).

[60] A Lamberti, F Perrucci, M Caprioli, M Serrapede, M Fontana et al. New insights on laser-induced graphene electrodes for flexible supercapacitors: tunable morphology and physical properties. Nanotechnology, 28, 174002(2017).

[61] A Tiliakos, C Ceaus, SM Iordache, E Vasile, I Stamatin. Morphic transitions of nanocarbons via laser pyrolysis of polyimide films. J Anal Appl Pyrolysis, 121, 275-286(2016).

[62] TX Tran, H Choi, CH Che, JH Sul, IG Kim et al. Laser-induced reduction of graphene oxide by intensity-modulated line beam for supercapacitor applications. ACS Appl Mater Interfaces, 10, 39777-39784(2018).

[63] XY Fu, YL Zhang, HB Jiang, DD Han, YQ Liu et al. Hierarchically structuring and synchronous photoreduction of graphene oxide films by laser holography for supercapacitors. Opt Lett, 44, 1714-1717(2019).

[64] YC Guan, YW Fang, GC Lim, HY Zheng, MH Hong. Fabrication of laser-reduced graphene oxide in liquid nitrogen environment. Sci Rep, 6, 28913(2016).

[65] YL Li, DX Luong, JB Zhang, YR Tarkunde, C Kittrell et al. Laser-induced graphene in controlled atmospheres: from superhydrophilic to superhydrophobic surfaces. Adv Mater, 29, 1700496(2017).

[66] Y Huang, JJ Liang, YS Chen. An overview of the applications of graphene-based materials in supercapacitors. Small, 8, 1805-1834(2012).

[67] GA Snook, P Kao, AS Best. Conducting-polymer-based supercapacitor devices and electrodes. J Power Sources, 196, 1-12(2011).

[68] LL Zhang, XS Zhao. Carbon-based materials as supercapacitor electrodes. Chem Soc Rev, 38, 2520-2531(2009).

[69] MF El-Kady, V Strong, S Dubin, RB Kaner. Laser scribing of high-performance and flexible graphene-based electrochemical capacitors. Science, 335, 1326-1330(2012).

[70] MF El-Kady, RB Kaner. Scalable fabrication of high-power graphene micro-supercapacitors for flexible and on-chip energy storage. Nat Commun, 4, 1475(2013).

[71] RZ Li, R Peng, KD Kihm, S Bai, D Bridges et al. High-rate in-plane micro-supercapacitors scribed onto photo paper using in situ femtolaser-reduced graphene oxide/Au nanoparticle microelectrodes. Energy Environ Sci, 9, 1458-1467(2016).

[72] ZW Peng, RQ Ye, JA Mann, D Zakhidov, YL Li et al. Flexible boron-doped laser-induced graphene microsupercapacitors. ACS Nano, 9, 5868-5875(2015).

[73] FS Wen, CX Hao, JY Xiang, LM Wang, H Hou et al. Enhanced laser scribed flexible graphene-based micro-supercapacitor performance with reduction of carbon nanotubes diameter. Carbon, 75, 236-243(2014).

[74] XQ Li, WH Cai, KS Teh, MJ Qi, XN Zang et al. High-voltage flexible microsupercapacitors based on laser-induced graphene. ACS Appl Mater Interfaces, 10, 26357-26364(2018).

[75] LV Thekkekara, M Gu. Bioinspired fractal electrodes for solar energy storages. Sci Rep, 7, 45585(2017).

[76] L Li, JB Zhang, ZW Peng, YL Li, CT Gao et al. High-performance pseudocapacitive microsupercapacitors from laser-induced graphene. Adv Mater, 28, 838-845(2016).

[77] HL Liu, KS Moon, JX Li, YX Xie, J Liu et al. Laser-oxidized Fe₃O₄ nanoparticles anchored on 3D macroporous graphene flexible electrodes for ultrahigh-energy in-plane hybrid micro-supercapacitors. Nano Energy, 77, 105058(2020).

[78] CL Liu, HW Liang, D Wu, XY Lu, Q Wang. Direct semiconductor laser writing of few-layer graphene polyhedra networks for flexible solid-state supercapacitor. Adv Electron Mater, 4, 1800092(2018).

[79] BH Xie, Y Wang, WH Lai, W Lin, ZY Lin et al. Laser-processed graphene based micro-supercapacitors for ultrathin, rollable, compact and designable energy storage components. Nano Energy, 26, 276-285(2016).

[80] DZ Shen, GS Zou, L Liu, WZ Zhao, AP Wu et al. Scalable high-performance ultraminiature graphene micro-supercapacitors by a hybrid technique combining direct writing and controllable microdroplet transfer. ACS Appl Mater Interfaces, 10, 5404-5412(2018).

[81] LV Thekkekara, X Chen, M Gu. Two-photon-induced stretchable graphene supercapacitors. Sci Rep, 8, 11722(2018).

[82] WL Zhang, YJ Lei, Q Jiang, FW Ming, PMFJ Costa et al. 3D laser scribed graphene derived from carbon nanospheres: an ultrahigh‐power electrode for supercapacitors. Small Methods, 3, 1900005(2019).

[83] S Kwon, Y Yoon, J Ahn, H Lim, G Kim et al. Facile laser fabrication of high quality graphene-based microsupercapacitors with large capacitance. Carbon, 137, 136-145(2018).

[84] N Kamboj, T Purkait, M Das, S Sarkar, KS Hazra et al. Ultralong cycle life and outstanding capacitive performance of a 10.8 V metal free micro-supercapacitor with highly conducting and robust laser-irradiated graphene for an integrated storage device. Energy Environ Sci, 12, 2507-2517(2019).

[85] ZW Liu, F Peng, HJ Wang, H Yu, WX Zheng et al. Phosphorus-doped graphite layers with high electrocatalytic activity for the O₂ reduction in an alkaline medium. Angew Chem Int Ed, 50, 3257-3261(2011).

[86] Z Yang, Z Yao, GF Li, GY Fang, HG Nie et al. Sulfur-doped graphene as an efficient metal-free cathode catalyst for oxygen reduction. ACS Nano, 6, 205-211(2012).

[87] ZS Wu, A Winter, L Chen, Y Sun, A Turchanin et al. Three-dimensional nitrogen and boron Co-doped graphene for high-performance all-solid-state supercapacitors. Adv Mater, 24, 5130-5135(2012).

[88] XY Fu, DL Chen, Y Liu, HB Jiang, H Xia et al. Laser reduction of nitrogen-rich carbon nanoparticles@graphene oxides composites for high rate performance supercapacitors. ACS Appl Nano Mater, 1, 777-784(2018).

[89] FC Wang, X Dong, KD Wang, WQ Duan, M Gao et al. Laser-induced nitrogen-doped hierarchically porous graphene for advanced electrochemical energy storage. Carbon, 150, 396-407(2019).

[90] HL Liu, YX Xie, JB Liu, KS Moon, LS Lu et al. Laser-induced and KOH-activated 3D graphene: a flexible activated electrode fabricated via direct laser writing for in-plane micro-supercapacitors. Chem Eng J, 393, 124672(2020).

[91] Y Fang, B Luo, YY Jia, XL Li, B Wang et al. Renewing functionalized graphene as electrodes for high‐performance supercapacitors. Adv Mater, 24, 6348-6355(2012).

[92] MH Amiri, N Namdar, A Mashayekhi, F Ghasemi, Z Sanaee et al. Flexible micro supercapacitors based on laser-scribed graphene/ZnO nanocomposite. J Nanopart Res, 18, 237(2016).

[93] SM Lee, YJ Park, JH Kim. Laser reduction of Zn-infiltrated multilayered graphene oxide as electrode materials for supercapacitors. ACS Appl Nano Mater, 2, 3711-3717(2019).

[94] XY Fu, ZD Chen, YL Zhang, DD Han, JN Ma et al. Direct laser writing of flexible planar supercapacitors based on GO and black phosphorus quantum dot nanocomposites. Nanoscale, 11, 9133-9140(2019).

[95] GJ Li, XY Mo, WC Law, KC Chan. 3D printed graphene/nickel electrodes for high areal capacitance electrochemical storage. J Mater Chem A, 7, 4055-4062(2019).

[96] WT Wang, LS Lu, YX Xie, WB Wu, RX Liang et al. Controlling the laser induction and cutting process on polyimide films for kirigami-inspired supercapacitor applications. Sci China Technol Sci, 64, 651-661(2020).

[97] RX Xu, A Zverev, A Hung, CW Shen, L Irie et al. Kirigami-inspired, highly stretchable micro-supercapacitor patches fabricated by laser conversion and cutting. Microsyst Nanoeng, 4, 36(2018).

[98] Y Liang, Z Wang, J Huang, HH Cheng, F Zhao et al. Series of in-fiber graphene supercapacitors for flexible wearable devices. J Mater Chem A, 3, 2547-2551(2015).

[99] Q Liu, QW Shi, HZ Wang, QH Zhang, YG Li. Laser irradiated self-supporting and flexible 3-dimentional graphene-based film electrode with promising electrochemical properties. RSC Adv, 5, 47074-47079(2015).

[100] A Borenstein, V Strauss, MD Kowal, M Yoonessi, M Muni et al. Laser-reduced graphene-oxide/ferrocene: a 3-D redox-active composite for supercapacitor electrodes. J Mater Chem A, 6, 20463-20472(2018).

[101] SH Yang, YY Liu, YF Hao, XP Yang, III Goddard et al. Oxygen-vacancy abundant ultrafine Co3O4/graphene composites for high-rate supercapacitor electrodes. Adv Sci (Weinh), 5, 1700659(2018).

[102] JA Hondred, IL Medintz, JC Claussen. Enhanced electrochemical biosensor and supercapacitor with 3D porous architectured graphene via salt impregnated inkjet maskless lithography. Nanoscale Horiz, 4, 735-746(2019).

[103] SH Yang, Y Li, J Sun, BQ Cao. Laser induced oxygen-deficient TiO₂/graphene hybrid for high-performance supercapacitor. J Power Sources, 431, 220-225(2019).

[104] A Ladrón-de-Guevara, A Boscá, J Pedrós, E Climent-Pascual, Andrés de et al. Reduced graphene oxide/polyaniline electrochemical supercapacitors fabricated by laser. Appl Surf Sci, 467–468, 691-697(2019).

[105] EC Cho, CW Chang-Jian, WL Syu, HS Tseng, KC Lee et al. PEDOT-modified laser-scribed graphene films as bginder-and metallic current collector-free electrodes for large-sized supercapacitors. Appl Surf Sci, 518, 146193(2020).

[106] K Naoi, S Ishimoto, JI Miyamoto, W Naoi. Second generation ‘nanohybrid supercapacitor’: evolution of capacitive energy storage devices. Energy Environ Sci, 5, 9363-9373(2012).

[107] Pino del, MA Ramadan, PG Lebière, R Ivan, C Logofatu et al. Fabrication of graphene-based electrochemical capacitors through reactive inverse matrix assisted pulsed laser evaporation. Appl Surf Sci, 484, 245-256(2019).

[108] YG Wang, ZD Wang, YY Xia. An asymmetric supercapacitor using RuO₂/TiO₂ nanotube composite and activated carbon electrodes. Electrochim Acta, 50, 5641-5646(2005).

[109] SH Lee, JH Kim, JR Yoon. Laser scribed graphene cathode for next generation of high performance hybrid supercapacitors. Sci Rep, 8, 8179(2018).

[110] SH Lee, KY Kim, JR Yoon. Binder- and conductive additive-free laser-induced graphene/LiNi_1/3Mn_1/3Co_1/3O₂ for advanced hybrid supercapacitors. NPG Asia Mater, 12, 28(2020).

[111] F Clerici, M Fontana, S Bianco, M Serrapede, F Perrucci et al. In situ MoS₂ decoration of laser-induced graphene as flexible supercapacitor electrodes. ACS Appl Mater Interfaces, 8, 10459-10465(2016).

[112] LV Thekkekara, M Gu. Large-scale waterproof and stretchable textile-integrated laser- printed graphene energy storages. Sci Rep, 9, 11822(2019).

[113] A Lamberti, F Clerici, M Fontana, L Scaltrito. A highly stretchable supercapacitor using laser-induced graphene electrodes onto elastomeric substrate. Adv Energy Mater, 6, 1600050(2016).

[114] M Parmeggiani, P Zaccagnini, S Stassi, M Fontana, S Bianco et al. PDMS/polyimide composite as an elastomeric substrate for multifunctional laser-induced graphene electrodes. ACS Appl Mater Interfaces, 11, 33221-33230(2019).

[115] CX Shao, T Xu, J Gao, Y Liang, Y Zhao et al. Flexible and integrated supercapacitor with tunable energy storage. Nanoscale, 9, 12324-12329(2017).

[116] J Gao, CX Shao, SX Shao, F Wan, C Gao et al. Laser-assisted large-scale fabrication of all-solid-state asymmetrical micro-supercapacitor array. Small, 14, e1801809(2018).

[117] MG Stanford, C Zhang, JD Fowlkes, A Hoffman, IN Ivanov et al. High-resolution laser-induced graphene. flexible electronics beyond the visible limit. ACS Appl Mater Interfaces, 12, 10902-10907(2020).

[118] R Kumar, R Savu, E Joanni, AR Vaz, MA Canesqui et al. Fabrication of interdigitated micro-supercapacitor devices by direct laser writing onto ultra-thin, flexible and free-standing graphite oxide films. RSC Adv, 6, 84769-84776(2016).

[119] JB In, B Hsia, JH Yoo, S Hyun, C Carraro et al. Facile fabrication of flexible all solid-state micro-supercapacitor by direct laser writing of porous carbon in polyimide. Carbon, 83, 144-151(2015).

[120] ST Wang, YC Yu, RZ Li, GY Feng, ZL Wu et al. High-performance stacked in-plane supercapacitors and supercapacitor array fabricated by femtosecond laser 3D direct writing on polyimide sheets. Electrochim Acta, 241, 153-161(2017).

[121] YJ Yuan, L Jiang, X Li, P Zuo, CY Xu et al. Laser photonic-reduction stamping for graphene-based micro-supercapacitors ultrafast fabrication. Nat Commun, 11, 6185(2020).

[122] LV Thekkekara, BH Jia, YN Zhang, L Qiu, DAN Li et al. On-chip energy storage integrated with solar cells using a laser scribed graphene oxide film. Appl Phys Lett, 107, 031105(2015).

[123] HH Liu, MP Li, RB Kaner, SY Chen, QB Pei. Monolithically integrated self-charging power pack consisting of a silicon nanowire array/conductive polymer hybrid solar cell and a laser-scribed graphene supercapacitor. ACS Appl Mater Interfaces, 10, 15609-15615(2018).

[124] JG Cai, C Lv, A Watanabe. Laser direct writing of high-performance flexible all-solid-state carbon micro-supercapacitors for an on-chip self-powered photodetection system. Nano Energy, 30, 790-800(2016).

[125] SL Kim, JH Hsu, C Yu. Intercalated graphene oxide for flexible and practically large thermoelectric voltage generation and simultaneous energy storage. Nano Energy, 48, 582-589(2018).

[126] Q Liu, ZM Hao, XB Liao, XL Pan, SX Li et al. Langmuir-blodgett nanowire devices for in situ probing of zinc-ion batteries. Small, 15, e1902141(2019).

[127] MM Hossain, M Gu. Radiative cooling: principles, progress, and potentials. Adv Sci (Weinh), 3, 1500360(2016).

[128] MM Hossain, BH Jia, M Gu. A metamaterial emitter for highly efficient radiative cooling. Adv Opt Mater, 3, 1047-1051(2015).

[129] YN Zhang, X Chen, BY Cai, HT Luan, QM Zhang et al. Photonics empowered passive radiative cooling. Adv Photonics Res, 2, 2000106(2020).

[130] W Li, Y Shi, KF Chen, LX Zhu, SH Fan. A comprehensive photonic approach for solar cell cooling. ACS Photonics, 4, 774-782(2017).

[131] M Gu, XY Fang, HR Ren, E Goi. Optically digitalized holography: a perspective for all-optical machine learning. Engineering, 5, 363-365(2019).

[132] E Goi, X Chen, QM Zhang, BP Cumming, S Schoenhardt et al. Nanoprinted high-neuron-density optical linear perceptrons performing near-infrared inference on a CMOS chip. Light: Sci Appl, 10, 40(2021).

[133] E Goi, QM Zhang, X Chen, HT Luan, M Gu. Perspective on photonic memristive neuromorphic computing. PhotoniX, 1, 3(2020).

[134] HR Ren, W Shao, Y Li, F Salim, M Gu. Three-dimensional vectorial holography based on machine learning inverse design. Sci Adv, 6, eaaz4261(2020).

[135] QM Zhang, HY Yu, M Barbiero, BK Wang, M Gu. Artificial neural networks enabled by nanophotonics. Light: Sci Appl, 8, 42(2019).