Lignin　as　a　renewable　natural　resource　has　been　the　focus　of　numerical　interest　in　applications　ranging　from　pitch　to　porous　carbon　material.　Herein,　a　facile　approach　is　reported　to　transform　lignin　into　porous　conductive　carbon　structures　and　interdigitated　circuits　for　supercapacitor　devices　using　femtosecond　laser　direct　writing.　Comparative　studies　revealed　that　the　laser　irradiation　induced　tetrahedral　amorphous　carbon　while　only　graphitic　carbon　was　obtained　through　pyrolysis.　Meanwhile,　the　composite　membrane　was　easily　prepared　to　further　optimize　the　capacities　by　mixing　functional　materials　(MoS2)　into　the　lignin/polyacrylonitrile　(PAN)　composite　polymers.　A　MoS2　decorated　porous　carbon　network　material　could　be　fabricated　through　focused　femtosecond　pulsed　laser　irradiation　of　the　corresponding　composite　membranes.　The　microstructure　and　spectroscopic　features　of　these　laser　induced　hybrid　carbon　materials　have　been　deeply　investigated.　The　supercapacitor　based　on　lignin/PAN　has　high　areal　specific　capacitances　of　6.7　mF　cm(-2)　(0.9　F　cm(-3))　at　10mV　s(-1).　Moreover,　doped　microsupercapacitors　with　MoS2　demonstrated　enhanced　areal　capacitances　up　to　16　mF　cm(-2)　(2.2　F　cm(-3))　and　at　10mV　s(-1),　respectively.　The　relatively　high　areal　capacitances　indicate　that　the　proposed　method　is　potential　for　innovative　manufacturing　energy　storage　devices　based　on　natural　lignin.