Generation Ethanol distillation Graphene oxide membranes allow water vapor to pass through, but are impermeable to other liquids and gases. This phenomenon has been used for further distilling of
vodka to higher alcohol concentrations, in a room-temperature laboratory, without the application of heat or vacuum as used in traditional
distillation methods. Further development and commercialization of such membranes could revolutionize the economics of
biofuel production and the
alcoholic beverage industry.
Solar cells Graphene has been used on different substrates such as Si, CdS and CdSe to produce Schottky junction solar cells. Through the properties of graphene, such as graphene's work function, solar cell efficiency can be optimized. An advantage of graphene electrodes is the ability to produce inexpensive Schottky junction solar cells.
Charge conductor Graphene solar cells use graphene's unique combination of high electrical conductivity and optical transparency. This material absorbs only 2.6% of green light and 2.3% of red light. Graphene can be assembled into a film electrode with low roughness. These films must be made thicker than one atomic layer to obtain useful sheet resistances. This added resistance can be offset by incorporating conductive filler materials, such as a
silica matrix. Reduced conductivity can be offset by attaching large
aromatic molecules such as
pyrene-1-sulfonic acid sodium salt (PyS) and the disodium salt of 3,4,9,10-perylenetetracarboxylic diimide bisbenzenesulfonic acid (PDI). These molecules, under high temperatures, facilitate better π-conjugation of the graphene basal plane.
Light collector Using graphene as a photoactive material requires its bandgap to be 1.4–1.9 eV. In 2010, single cell efficiencies of nanostructured graphene-based PVs of over 12% were achieved. According to P. Mukhopadhyay and R. K. Gupta
organic photovoltaics could be "devices in which semiconducting graphene is used as the photoactive material and metallic graphene is used as the conductive electrodes". Silicon generates only one current-driving electron for each photon it absorbs, while graphene can produce multiple electrons. Solar cells made with graphene could offer 60% conversion efficiency.
Fuel cells Appropriately perforated graphene (and hexagonal
boron nitride hBN) can allow
protons to pass through it, offering the potential for using graphene monolayers as a barrier that blocks hydrogen atoms but not protons/ionized hydrogen (hydrogen atoms with their electrons stripped off). They could even be used to extract hydrogen gas out of the atmosphere that could power electric generators with ambient air. The membranes are more effective at elevated temperatures and when covered with catalytic nanoparticles such as
platinum. At room temperature, proton conductivity with monolayer hBN, outperforms graphene, with resistivity to proton flow of about 10 Ω cm2 and a low
activation energy of about 0.3 electronvolts. At higher temperatures, graphene outperforms with resistivity estimated to fall below 10−3 Ω cm2 above 250 degrees Celsius. In another project, protons easily pass through slightly imperfect graphene membranes on fused
silica in water.
Condenser coating In 2015 a graphene coating on steam condensers quadrupled condensation efficiency, increasing overall plant efficiency by 2–3 percent.
Storage Supercapacitor Due to graphene's high
surface-area-to-mass ratio, one potential application is in the conductive plates of
supercapacitors. In February 2013 researchers announced a novel technique to produce graphene
supercapacitors based on the DVD burner reduction approach. In 2014 a supercapacitor was announced that was claimed to achieve energy density comparable to current lithium-ion batteries. The resulting devices were mechanically flexible, surviving 8,000 bending cycles. This makes them potentially suitable for rolling in a cylindrical configuration. Solid-state polymeric electrolyte-based devices exhibit areal capacitance of >9 mF/cm2 at a current density of 0.02 mA/cm2, over twice that of conventional aqueous electrolytes. Also in 2015 another project announced a microsupercapacitor that is small enough to fit in wearable or implantable devices. Just one-fifth the thickness of a sheet of paper, it is capable of holding more than twice as much charge as a comparable thin-film lithium battery. The design employed laser-scribed graphene, or LSG with
manganese dioxide. They can be fabricated without extreme temperatures or expensive "dry rooms". Their capacity is six times that of commercially available supercapacitors. The device reached volumetric capacitance of over 1,100 F/cm3. This corresponds to a specific capacitance of the constituent
MnO2 of 1,145 F/g, close to the theoretical maximum of 1,380 F/g.
Energy density varies between 22 and 42 Wh/L depending on device configuration. In May 2015 a
boric acid-infused, laser-induced graphene supercapacitor tripled its areal energy density and increased its volumetric energy density 5-10 fold. The new devices proved stable over 12,000 charge-discharge cycles, retaining 90 percent of their capacitance. In stress tests, they survived 8,000 bending cycles.
Batteries Silicon-graphene anode lithium ion batteries were demonstrated in 2012. Stable
lithium ion cycling was demonstrated in bi- and few layer graphene films grown on
nickel substrates, while single layer graphene films have been demonstrated as a protective layer against corrosion in battery components such as the battery case. This creates possibilities for flexible electrodes for microscale Li-ion batteries, where the anode acts as the active material and the current collector. In 2014 researchers built a
lithium-ion battery made of graphene and
silicon, claiming took only 15 minutes to charge. In 2014, graphene with controlled topological defects was demonstrated to adsorb more ions, resulting in high-efficiency batteries. In 2015
argon-ion based plasma processing was used to bombard graphene samples with argon ions. That knocked out some carbon atoms and increased the
capacitance of the materials three-fold. These "armchair" and "zigzag" defects reflect the configurations of the carbon atoms that surround the holes. In 2016,
Huawei announced graphene-assisted
lithium-ion batteries with greater heat tolerance and twice the life span of
traditional Lithium-Ion batteries, the component with the shortest life span in
mobile phones.
Electrode In 2010, researchers first reported creating a graphene-silicon heterojunction solar cell, where graphene served as a transparent electrode and introduced a built-in electric field near the interface between the graphene and n-type silicon to help collect charge carriers. In 2012 researchers reported efficiency of 8.6% for a prototype consisting of a silicon wafer coated with trifluoromethanesulfonyl-amide (TFSA) doped graphene. Doping increased efficiency to 9.6% in 2013. In 2015 researchers reported efficiency of 15.6% by choosing the optimal oxide thickness on the silicon. This combination of carbon materials with traditional silicon semiconductors to fabricate solar cells has been a promising field of carbon science. In 2013, another team reported 15.6% percent by combining
titanium oxide and graphene as a charge collector and
perovskite as a sunlight absorber. The device is manufacturable at temperatures under using solution-based deposition. This lowers production costs and offers the potential using flexible plastics. In 2015, researchers developed a prototype cell that used semitransparent perovskite with graphene electrodes. The design allowed light to be absorbed from both sides. It offered efficiency of around 12 percent with estimated production costs of less than $0.06/watt. The graphene was coated with PEDOT:PSS conductive polymer (
polythiophene) polystyrene sulfonate). Multilayering graphene via CVD created transparent electrodes reducing sheet resistance. Performance was further improved by increasing contact between the top electrodes and the hole transport layer.
Transmission Conducting Wire Due to
Graphene's high electrical and
thermal conductivity,
mechanical strength, and
corrosion resistance, one potential application is in high-power energy transmission.
Copper wire has long been used for power transmission for its high conductivity, ductility, and low costs. However, traditional wire fails to meet the transmission requirements of many new technologies. Thermally dependent
resistivity in
mesoscopic copper wire limits efficiency and
current carrying capacity in small-scale electronics. Additionally, copper wire exhibits internal failure by
electromigration at high current density, limiting miniaturization of wire. Copper's high weight and low temperature oxidation also limit its applications in high-power transmission. Increasing demand for high ampacity transmission in electronics and electric vehicle applications necessitate improvements in conductor technology. Graphene-copper composite conductors are a promising alternative to standard conductors in high-power applications. In 2013, researchers demonstrated a one-hundred-fold increase in current carrying capacity with
carbon nanotube-copper composite wires when compared to traditional copper wire. These composite wires exhibited a temperature coefficient of resistivity an order of magnitude smaller than copper wires, an important feature for high load applications.
Graphene-clad wire Additionally, in 2021, researchers demonstrated a 4.5 times increase in the current density breakdown limit of copper wire with an axially continuous graphene shell. The copper wire was coated by a continuous graphene sheet through
chemical vapor deposition. The coated wire exhibited reduced
oxidation of the wire during
joule heating, increased
heat dissipation (224% higher), and increased conductivity (41% higher). == Sensors ==