Table 2.

Graphene‐based paper‐like electrodes and their flexible energy storage devices

Electrodes	Synthesis methods	Device	Performance				Ref.
			Capacitance/Capacity	Power Density	Energy Density	Cycling Stability
Graphene paper	Laser scribing	SC	276 F g−1	20 W cm−3	1.36 mWh cm−3	96.5% after 10000 cycles	136
Graphene paper	Frozen and pressing	SC	172 F g−1	–	–	99% after 5000 cycles	134
		LIB	864 mAh g−1	–	–	65.7% after 100 cycles
Mesoporous graphene paper	Vacuum filtration	Li‐S*	1393 mAh g−1	–	–	49.5% after 50 cycles	157
Graphene hydrogel film	Hydrothermal reduction	SC	187 F g−1	0.37 kW kg−1	0.61 Wh kg−1	91.6% after 10000 cycles	158
	Pressing
Porous graphene film	Freeze‐casting	SC	284.2 F g−1	282 kW kg−1	9.9 Wh kg−1	97.6% after 10000 cycles	159
Holey graphene film	Hydrothermal etching	SC	298 F g−1	7.46 kW kg−1	35.1 Wh kg−1	95% after 20000 cycles	137
			212 F cm−3	10.6 kW L−1	49.2 Wh L−1
Nanoporous graphene film	Sacrificial template	SC	305 F g−1	20.8 W cm−3	2.65 mWh cm−3	94% after 10000 cycles	153
			95.4 F cm−3
Porous activated rGO film	Vacuum filtration	SC	120 F g−1	500 kW kg−1	26 Wh kg−1	95% after 2000 cycles	133
rGO film	Laser writing	SC	0.51 mF cm−2	1.7 W cm−3	0.43 mWh cm−3	70% after 10000 cycles	148
rGO film	Photo reduction	SC	275 F g−1	–	–	98% after 100 cycles	160
N‐doped graphene paper	Vacuum filtration	SC	280 F g−1	–	–	99.4% after 40000 cycles	139
N/S‐codoped graphene paper	Layer‐by‐layer Self‐assembly	SC	305 F g−1	17.76 Wh kg−1	28.44 Wh kg−1	95.4% after 10000 cycles	140
			188 F cm−3
PPy‐graphene film	Pulse‐electropolymerization	SC	237 F g−1	1.18 kW kg−1	33 Wh kg−1	–	156
PANI‐graphene paper	Vacuum filtration Electrodeposition	SC	233 F g−1	–	–	109% after 1500 cycles	129
			135 F cm−3
PANI nanofiber‐graphene paper	Vacuum filtration	SC	210 F g−1	3.3 kW kg−1	18.8 Wh kg−1	79% after 800 cycles	146
PANI‐graphene paper	Vacuum filtration	SC	489 F g−1	–	–	96% after 500 cycles	161
	Chemical polymerization
PANI‐graphene film	Screen printing	SC	269 F g−1	454 kW kg−1	9.3 Wh kg−1	203% after 1000 cycles	118
Graphene‐PANI‐graphene film	Vacuum filtration	SC	390 F g−1	2.4 kW kg−1	10.4 Wh kg−1	82% after 5000 cycles	162
PANI‐MnO2‐graphene	Vacuum filtration	SC	636.5 F g−1	–	–	85% after 10000 cycles	131
	Electrodeposition polymerization
PANI‐3D‐graphene film	Sacrificial template polymerization	SC	385 F g−1	–	–	90% after 5000 cycles	152
PEDOT‐graphene film	Bar‐coating	SC	448 mF cm−2	3.59 kW kg−1	2.83 Wh kg−1	95% after 10000 cycles	151
			81.9 F g−1
Si‐graphene paper	Vacuum filtration	LIB	3200 mAh g−1	–	–	83% after 150 cycles	163
Co3O4‐graphene paper	Vacuum filtration	LIB	1356 mAh g−1	–	–	61.9% after 40 cycles	164
Fe2O3‐graphene paper	Vacuum filtration	SC	178.3 F cm−3	6.21 W cm−3	56 mWh cm−3	83.1% after 10000 cycles	165
Fe3O4‐graphene paper	Vacuum filtration	LIB	1555 mAh g−1	–	–	85% after 50 cycles	166
MnO2‐graphene paper	Vacuum filtration annealing	SC	256 F g−1	–	–	74% after 1000 cycles	167
MnO2‐graphene paper	Vacuum filtration	SC	897 mF cm−2	3.8 mW cm−2	35.1 µWh cm−2	78% after 3600 cycles	168
Mn3O4‐graphene paper	Vacuum filtration	SC	54.6 F cm−3	10.95 W cm−3	5.5 mWh cm−3	95% after 6000 cycles	145
SnO2‐graphene paper	Vacuum filtration	LIB	526 mAh g−1	–	–	83.4% after 25 cycles	169
SnO2‐N‐graphene paper	Vacuum filtration	LIB	918 mAh g−1	–	–	63% after 50 cycles	170
MoO3‐graphene film	Vacuum filtration	LIB	291 mAh g−1	–	–	59.1% after 100 cycles	171
Mo2N‐graphene paper	Vacuum filtration NH3 annealing	SC	142 mF cm−2	0.035 W cm−3	1.05 mWh cm−3	85.7% after 4000 cycles	172
MoS2‐graphene paper	Vacuum filtration	SIB	347 mAh g−1	–	–	90% after 15 cycles	173
V2O5‐graphene paper	Hydrothermal reaction vacuum filtration	SC	21.3 F g−1	425 W kg−1	8.5 Wh kg−1	60% after 50 cycles	174
V2O5‐graphene paper	Vacuum filtration	SC	512 mF cm−2	625 W kg−1	13.3 Wh kg−1	90% after 8000 cycles	175
				4.17 mW cm−2	89 µWh cm−2
V2O5·H2O‐graphene film	Vacuum filtration	SC	11.7 mF cm−2	10 µW cm−2	1.13 µWh cm−2	95% after 2000 cycles	176
VOPO4‐graphene film	Layer‐by‐layer	SC	8.36 mF cm−2	5.2 mW cm−2	1.7 mWh cm−2	96% after 2000 cycles	177
TiO2‐graphene paper	Vacuum filtration	LIB*	236 mAh g−1	–	–	99% after 90 cycles	178
Nb2O5‐graphene paper	Vacuum filtration	LIC*	160 mAh g−1	32 W kg−1	106 Wh kg−1	110.8% after 1000 cycles	179
T‐Nb2O5‐graphene paper	Hydrothermal reaction	SC	620.5 F g−1	18 W kg−1	47 Wh kg−1	94.8% after 1700 cycles	180
	Vacuum filtration		961.8 F cm−3
CuO‐graphene paper	Vacuum filtration	LIB	782.3 mAh g−1	–	–	94.2% after 50 cycles	181
MnO2‐PPy‐graphene film	Electrodeposition	SC	600 F g−1	13 kW kg−1	28 Wh kg−1	92% after 5000 cycles	182
RuO2‐graphene film	Laser‐scribing	SC	1139 F g−1	81.4 kW kg−1	55.3 Wh kg−1	93% after 4000 cycles	147
			158 F cm−3
Ni(OH)2‐grapheen paper	Vacuum filtration	SC	573 F g−1	17 kW kg−1	18 Wh kg−1	158% after 20000 cycles	183
			655 F cm−3
β‐Ni(OH)2‐graphene film	Vacuum filtration	SC	660.8 F cm−3	–	–	100% after 2000 cycles	184
			3.3 mF cm−2
Co(OH)2‐graphene film	Vacuum filtration	SC	20 F g−1	–	–	100% after 5000 cycles	185
		LIB	520 mAh g−1	–	–	23.1% after 200 cycles
Li‐rGO film	Spark reaction	LIB	3390 mAh g−1	–	–	90% after 100 cycles	186
Carbon black‐graphene paper	Vacuum filtration	SC	112 F g−1	–	–	94% after 3000 cycles	187
3D CNT‐graphene film	CVD	SC	–	10.3 kW kg−1	22.8 Wh kg−1	90.2% after 10000 cycles	188

*Notes: Lithium‐ion capacitor (LIC), Lithium‐sulfur batteries (Li‐S), Sodium‐ion batteries (SIB).