DE102014109030A1 - Conductive polymer deicing films and device - Google Patents

Abstract

A de-icing film for a window or surfaces of vehicles, including automobiles and aircraft. The deicing film is a transparent, conductive polymer formed from a mixture of PEDOT: PSS and graphene.

Description

AREA:

The present invention relates to a deicing film for windows and surfaces of vehicles or an aircraft. Special deicing films formed from conductive polymers and in particular from transparent conductive polymers.

BACKGROUND:

When a vehicle or aircraft is exposed to freezing temperatures outside, ice may form on the surface of the vehicle or aircraft. Ice may form due to freezing rain, sleet or snow falling on the windows and surfaces of the vehicle or aircraft, or may result from the condensation of water from the air when the temperatures fall overnight. Frost or ice can form in several layers, which can be difficult to remove.

Ice on vehicle or airplane windows can affect the driver's view, resulting in dangerous or impossible driving conditions. Ice on other aircraft surfaces can affect both the safety and performance of the aircraft as the ice can hinder the functioning of moving parts, increase the weight of an aircraft, and affect airflow, which increases air resistance.

Various tools and methods have been used to remove ice from the windows of cars and other similar vehicles. Mechanical ice scrapers in the form of plastic blades have been used, but these are often unable to successfully penetrate the layers of cured ice, particularly at very cold temperatures. Hot air blowers are a common feature in many vehicles, however, these blowers often depend on the heat from the engine, resulting in long waiting times for the engine to heat up and deliver warm air to the windows. Rear window heaters have also been used, but these have the disadvantage that they obscure the window glass and, while the ice melts quickly adjacent to the electric heating wires, the area between the electric wires takes longer to thaw. This can lead to lengthy delays for those who spend time cleaning their windows properly, and can lead to unsafe conditions if the windows remain incomplete.

In the aviation industry, ice or frost formation on aircraft surfaces can be both costly and dangerous. Ice formation on surfaces can add weight to aircraft, which increases fuel costs, but, more significantly, ice on the surfaces can hinder the smooth flow of air, which increases air resistance, while the wing's ability to build up buoyancy increases. In addition, when large ice pieces are released while the aircraft is in motion, they can be sucked into the engines or hit the propellers, causing damage or even failure of those parts. Frozen contaminants can also block control surfaces, preventing them from moving properly. Because of these potentially serious consequences, deicing the aircraft's outer surfaces is important when temperatures are likely to be near or below 0 ° C (32 ° F).

The use of chemical deicing solutions containing ethylene glycol or polyethylene glycol is common in cold climates. However, this de-icing method is costly, both because of the chemical materials used and because of the time spent waiting for a de-icing station at busy airports. In addition, there are environmental costs associated with the use and disposal of these toxic chemicals.

Recognizing these problems, numerous defrosting and defrosting methods have been proposed, including: US Pat. No. 4,904,844 to Dale L. Chemberlin; Japanese Laid-Open Patent 58-17046 ; US Pat. No. 5,447,272 to Bernard J. Ask; US Pat. No. 2,223,145 to Wise; US Pat. No. 3,964,780 to Naidu and others. However, these methods suffer from various weaknesses, such as being designed only for the front windshield, are relatively bulky and difficult to install.

Transparent conductor oxides.

Transparent conductive films (TCFS) are materials that are transparent to optical light and are also electrically conductive. Inorganic TCFs, such as indium-tin oxide (ITO), are used in a variety of applications, including deicing, such as those in U.S. Patent Nos. 5,467,866, 4,869,866, 5,429,866, and 5,629,866 CA 548939 disclosed invention. However, the use of ITO is limited by the fact that ITO is a relatively brittle material which can crack or break after repeated bending or straining. In addition, indium compounds are relatively toxic and are becoming increasingly expensive because of the limited availability of indium. To these technical problems Researchers are looking for alternative materials characterized by improved stability, environmental friendliness, high conductivity, good transparency, and the ability to be processed in solution.

Transparent conductive polymers.

Polythiophenes are conjugated polymers that can be used to form environmentally and thermally stable materials. These materials are known for their electrical conductivity and optical properties and have been used in electrochromic displays, smart windows, photoresists and solar cells. Polythiophene, like many polyaromatic compounds, is insoluble in organic solvents due to the presence of a rigid backbone. Substitution at the 3- and / or 4-position of the polythiophene provides a higher solubility. An example of a substituted polythiophene is poly (3,4-ethylenedioxythiophene) (PEDOT).

PEDOT is an intrinsically conductive polymer that can be used as an active material in flexible organic electronics due to its remarkably high conductivity, transparency and environmental stability. PEDOT is one of the most widely used π-conjugated polymers. Solution processability, electrical conductivity, and presumably its relatively low thermal conductivity, are properties that make this organic semiconductor an interesting material for thermoelectricity. Films of this conductive polymer are optically transparent in their conductive state. However, it suffers from being insoluble in water, how it is processed and restricting its use in certain devices. When the polymer is doped, it is quite stable. PEDOT and doped PEDOT have been used as transparent plastic electrodes in organic-based optoelectronic applications and also in antistatic films.

PEDOT is compatible with water soluble polymers such as poly (styrenesulfonic acid) (PSS) (see 2 ) to improve its solubility. PEDOT / PSS combines high conductivity and good transparency in the visible range with excellent stability under ambient conditions and can be easily processed in aqueous dispersions by spin coating. PEDOT / PSS is industrially synthesized from the ethylene dioxythiophene (EDOT) monomer and PSS using sodium peroxodisulfate as the oxidant. This is what PEDOT delivers in its highly conductive, cationic form. The degree of polymerization of PEDOT is limited and it is believed that PEDOT is a collection of oligomers with lengths of up to ~ 20 repeat units. The role of PSS, which has a significantly higher molecular weight, is to serve as a counterion and to keep the PEDOT chain segments dispersed in the aqueous medium. In general, the PEDOT / PSS hydrogel particles have excellent processing properties to produce thin, transparent, conductive films.

Graphene is a two-dimensional monolayer that has been the focus of much research because of its unique properties. Two particular properties of interest are the conductivity and optical transparency of graphene. In comparison with other transparent conductive films such as ITO, graphene exhibits high mechanical strength, flexibility and chemical stability. In addition to these properties, graphene can be functionalized with many different chemical groups to give it solubility, strength, and other desirable chemical properties. Graphene layers can be made by mechanical exfoliation of graphite and reduction of exfoliated graphite oxide.

The functionalization of graphene ensures that the graphene layers do not coagulate and allow the graphene to interact with other materials in a composite structure. During the production of exfoliated graphene layers, the graphene is oxidized to produce graphene oxide. This exfoliated graphene oxide can be further modified by the addition of various chemical groups to produce functionalized graphene. An example of a functionalized form of graphene is 1-pyrene butyrate functionalized graphene.

It has been found that the functionalization of graphene is important for improving the solubility of PEDOT: PSS, the self-assembly properties and application in devices.

The production of a transparent graphene / PEDOT: PSS composite film was carried out by W. Hong et al. in Electrochemistry Communications 10 (2008) 1555-1558 reported. The composite films prepared from 1-pyrene butyrate functionalized graphene exhibited high permeability and were found to possess the high electrocatalytic activity of graphene and the high conductivity of PEDOT: PSS.

PEDOT: PSS-graphene nanocomposite structures with specific doping concentrations have been obtained by thermally reducing graphene oxides to graphene. The graphene film has a relatively low Conductivity, which PEDOT: PSS has a higher conductivity and much better film-forming ability. Composite structures that combine graphene and PEDOT: PSS provide both good conductivity and transparency properties.

SUMMARY:

In one aspect of the invention, a deicing film is provided for an exterior surface of a vehicle or aircraft comprising a transparent, conductive polymer, wherein the transparent, conductive polymer film is a mixture of poly (3,4-ethylenedioxythiophene) (PEDOT): poly (styrenesulfonic acid). (PSS) with graphene or a functional derivative of graphene.

In one embodiment of the invention, a deicing film is provided which is applied to the outer surface of the vehicle or aircraft, alternatively, a deicing film is provided which is interposed between layers of the material of the outer surface.

In yet another embodiment, the outer surface is a window and the conductive polymer is a transparent, conductive polymer. In another embodiment, the transparent, conductive polymer is selected from poly (3,4-ethylenedioxythiophene) (PEDOT) combined with at least one of poly (styrenesulfonic acid) (PSS) and graphene. In yet another embodiment, the transparent, conductive polymer is a mixture of PEDOT: PSS with graphene or a functionalized derivative of graphene.

In another aspect of the invention, an apparatus is provided that includes a deicing film as described above that is connected to a power supply to provide energy to the conductive polymer.

In a further aspect of the invention, there is provided a method of applying the deicing film of claim 1 to the exterior surface of a vehicle or aircraft comprising coating the surface by a slot die, spin coating or screen printing process.

In a further aspect of the invention, there is provided a use of a transparent, conductive polymer as a deicing film for vehicle or aircraft surfaces, wherein the transparent, conductive polymer is a mixture of poly (3,4-ethylenedioxythiophene) (PEDOT): poly (styrenesulfonic acid) ( PSS) with graphs.

In another aspect of the invention, there is provided a deicing film as described above, wherein the transparent conductive film is a mixture comprising a PEDOT: PSS solution, wherein the PEDOT: PSS solution is about 0.5-1.5% by weight. PEDOT and about 1-3 wt% PSS is formed with a graphene solution wherein the graphene solution contains about 0.1-1.5 wt% graphene, and the PEDOT: PSS solution and the graphene solution in a ratio of 1: 2 to 2: 1.

In another aspect of the invention, there is provided a deicing film as described above, wherein the PEDOT: PSS solution contains about 1 wt% PEDOT and about 2.5 wt% PSS and the graphene solution contains about 0.25 wt%, 0.5 Wt%, 0.75 wt% or 1 wt% graphene.

In another aspect of the invention, there is provided a deicing film as described above, wherein the graphene solution comprises about 1% by weight of graphene and the PEDOT: PSS solution and the graphene solution are combined in a ratio of 1: 1.

BRIEF DESCRIPTION OF THE FIGURES:

The features of the embodiments of the invention will be described with reference to the attached drawings, in which:

1 shows the formation of a PEDOT polymer from an EDOT monomer,

2a Figure 4 is an illustration of a top view of the morphology of a thin film of PEDOT / PSS particles surrounded by a thin PSS-rich surface layer. The PEDOT chains are shown as short bars. 2 B is the chemical structure of the species present in the film (reproduced from M. M de Kok et al. )

3 is a representation of the chemical structure of a PEDOT: PSS polymer blend,

4 shows a sandwiched between two glass layers transparent thermoelectric conductive polymer film,

5 a layer of a transparent thermally conductive polymer film and a layer of a transparent, electrically conductive polymer film, which is inserted between glass layers shows,

6 shows a deicing device in an automobile,

7 shows a deicing device in an aircraft,

8th is a schematic representation of a deicing device,

9 is a graph showing the effect of the dry film thickness on the percentage of transmission at different wavelengths,

10 is a graph showing the current-voltage curves of the cells with PEDOT: PSS and Graphene-PEDOT: PSS,

11 is a graph showing the energy conversion efficiency in percent relative to the percentage of graphene content,

12 is a graph showing the thermal conductivity of graphene-PEDOT: PSS film on glass at increasing temperatures.

DETAILED DESCRIPTION:

The term "polymer" as used herein may refer to a single polymer species or a polymer blend.

The term "polymer blend" as used herein refers to a material composed of at least two polymer species.

The term "graphene" as used herein may refer to graphene or a functionalized derivative of graphene. An example of a functionalized graphene derivative is 1-pyrene butyrate (PB ^-) graphs. Other suitable functionalized graphene derivatives may also be used and would be known to one skilled in the art.

The features of the embodiments of the invention will become more apparent in the following detailed description, in which reference is made to the appended drawings, wherein like features are consistently defined by the same numbering.

The present invention relates to the use of conductive polymer films for deicing vehicle and aircraft surfaces. Vehicle and aircraft surfaces include, but are not limited to, windows, wings, propellers, windshields, aerials, vents, inlets, and panels. Vehicle surfaces and bodies are also contemplated, but are of lesser importance to the extent that deicing of these surfaces is not critical to performance or safety.

In the case where the surface to be frosted is a window, the use of optically transparent conductive films is desirable to allow coverage of the full window area or extended areas of the window area without compromising the ability of the driver or pilot to see the window.

Examples of suitable transparent conductive polymers or polymer blends include, but are not limited to, PEDOT: PSS, PEDOT / Graphene and Graphene / PEDOT: PSS. The 1 shows the chemical structure of PEDOT and the 2a and 2 B represent a PEDOT / PSS blend that forms a transparent, conductive polymer. The 3 is another illustration of the formation of a PEDOT: PSS blend that forms a transparent, conductive polymer.

In a particular embodiment, the polymer blend comprises PEDOT: PSS with graphene or a functionalized graphene. In another embodiment, the functionalized graph is PB ^- graph.

These materials not only offer high conductivities, but also a high degree of transparency, which makes them particularly suitable for vehicle and aircraft windows. The properties of these materials can be improved by the addition of additives, for example, a conductivity of 900-1000 S / cm (about 200 ohms / sq) can be achieved using PEDOT / PSS with a conductivity improver such as DMSO or ethylene glycol.

The conductive polymer formulations may be further modified by the addition of additives to optimize film deposition for a particular vehicle material. For example, coating formulations for individual substrates such as A-PET, PET, polycarbonate, and glass have been optimized for different wet film thicknesses and surface resistances.

The coating can be achieved by standard printing techniques, such as slot die, flexography, screen and gravure methods. Also, brushing, spraying, spin coating or roller coating can be used.

In a particular embodiment, aqueous dispersions of PEDOT: PSS (commercially available, for example, under the trade name Baytron ^™ P from HC Starck) can be used. With this material, thin, highly transparent and conductive surface coatings can be prepared by spin-coating or dip-coating on an almost arbitrary hydrophilic surface. HC Starck offers a selection of dispersions for different applications. Depending on the solids content, the doping concentration, particle size and additives, films with different properties can be produced become. The working function of Baytron P is about 5.2 eV. Because of the PSS content, the dispersion is acidic at a pH of 1.5 to 2.5 at room temperature. Other sources of PEDOT: PSS, such as CLEVIOS ^™ PH1000 or CLEVIOS ^™ PH500 from Heraeus can be used.

4 shows a cross-sectional view of a window 1 comprising a transparent thermoelectrically conductive polymer film 5 that is between a glass layer covering the inside of the window 2 forms, and a glass layer, which forms the outside of the window, is inserted.

5 shows a cross-sectional view of a window 1 with a transparent, electrically conductive polymer film coating a glass layer forming the inside of the window, and adjacent to it a transparent, thermally conductive polymer film covering a glass layer forming the outside of the window such that the transparent, electrically conductive polymer film and the transparent thermally conductive polymer film is interposed between the inner and outer glass layers.

In one particular embodiment, conductive polymers having the following technical specifications for use in the deicing film are proposed:
Viscosity: about 10-30 mPa.s at 20 ° C (100 s ^-1 )
Solids content: about 1.0-5.0%
Conductivity: about 150 S / cm
Surface tension: about 19-34 mN / m
Surface resistance: about 110-170 ohms / sq (coated layer with about 90% transmission at 550 nm, without substrate absorption and reflection losses)
pH: about 1.5-2.8
Method: slot die, spin coating, screen printing
Thermal conductivity: about 20 W / mK
Thermal conductivity: about 0.1 cmÇ / s
Specific heat: about 0.9 J / g ° C
Film thickness: about 6-12 microns
Density: about 0.900-0.959 g / cm ³

6 shows a device for defrosting windows of a vehicle, wherein one or more of the windows 1 has a deicing coating of a transparent, conductive material. The device further comprises a main wire 21 , a control box 22 and a wiring to each window 23 , 7 shows an apparatus for deicing windows of an aircraft, wherein one or more of the windows 1 has a deicing coating of a transparent, conductive material. The device further includes a main wire 21 , a control box 22 and a wiring to each window 23 ,

In a particular embodiment, the apparatus further includes an electrical circuit, including sensors for controlling the amount of current and voltage that must be supplied to each window or surface. 8th is a possible embodiment of the deicing device ( 30 ) as used in a windshield. The windshield 1 has a defrosting film comprising a conductive polymer as described above. The windshield 1 also has a negative connection 31 and a positive connection 32 on top of that with a conductive film in the windshield 1 are connected in such a way as to allow current to flow through the conductive film to the windshield 1 to heat and thereby melt the ice on the windshield. The windshield 1 is about the positive connection 31 and the negative connection 32 to an energy control system 33 Connected, which is responsible for controlling when power to the windshield 1 is supplied.

The energy control system 33 has a positive outcome 34 and a negative output 35 that with the positive connection 31 or the negative connection 32 the windshield are connected. The negative outcome 35 is also connected to an electrical ground. A relay 36 consists of a switching input 37 , a main entrance 38 , a grounding input 39 and a relay output 40 , The relay output 40 is with the positive outcome 34 of the control system 33 connected.

With the switching input 37 connected is an on / off switch 41 to the windshield heater 30 on and off when needed and not needed. With the on / off switch 41 connected is a fuse with low amperage 42 , which with a voltage source 43 connected to the relay 36 activated when the on / off switch 41 is in the on position.

In one embodiment, the voltage source 43 be a vehicle battery, in another embodiment, the voltage source 43 from a source that is only live when the engine of the vehicle is on, thereby preventing the battery of the vehicle from being discharged.

the main entrance 38 is with a high amperage fuse 44 connected, and the fuse with high amperage 44 is below with a positive battery connection 46 a battery 45 connected. The negative battery connection 47 the battery 45 is connected to the mass.

When the on / off switch 41 one is and the voltage source 41 is energized, then the relay 36 active and the relay output 40 comes with the main entrance 38 connected, which causes current from the relay output 40 through the positive outcome 34 , the positive connection 31 , the windshield 1 and the negative connection 32 flows to the mass.

When the on / off switch 41 off or the voltage source 43 is not live, then the switching input 37 grounded, and also the relay output 40 is grounded. This results in no current flowing through the windshield.

Examples

Graphene PEDOT: PSS compositions.

Compositions containing PEDOT: PSS and graphene were prepared using a commercial solution of PEDOT: PSS containing 1 wt% PEDOT and 2.5 wt% PSS, such as Clevious ^™ PH1000 from Heraeus. Commercially available graphene solutions of various concentrations were combined with the PEDOT: PSS in a 1: 1 ratio to obtain a PEDOT: PSS graphene solution. The solution was then sonicated for 15 minutes, whereupon a stable mixture is formed. Then the solution was filtered through a 0.2 μm filter membrane before use.

It was found that the solution prepared using 1% graphene had a vapor pressure of 23 hPa (17 mmHg) and a viscosity of between 15 and 50 mPAS at 20 ° C. It was found that the aqueous solution comprised more than 95% water and between 1% and 1.3% solids content. The pH range was measured to be 1.5 to 3.0, and the density was measured to be 0.9-1 g / cm ³ .

A film coating of the solution was prepared on a glass substrate. Before applying the film, the glass substrate was washed successively with a 1: 1 ethanol / acetone mixture followed by 5% NaOH solution and deionized water, successively, and then dried under vacuum in a clean room.

The solution was applied to the cleaned glass surface by spray coating. Although this example has been prepared by spray coating, it will be apparent to one skilled in the art that the film may be applied by a variety of methods, including, but not limited to, spin coating. The spin coating is performed at 7000 rpm [rpm] and 80-120 ° C for a minimum of 3 to 5 minutes.

The wet film thickness of the PEDOT: PSS graphene mixture was 6-12 μm. The surface resistance was <103 ohm / π and the specific conductivity was 1000 S / cm. The film was then dried under vacuum at room temperature. The dry film was measured to have a pencil hardness of 9H.

The thickness of the dried composite film was measured by atomic force microscopy (AFM) to be about 50 nm. Accordingly, the average thickness of the graphene layer can be derived as about 1.4 nm. This value is much higher than the interplanar spacing of graphene, which is about 0.34 nm. Without wishing to be bound by theory, it is postulated that the graphene layers in the PEDOT: PSS matrix were uniformly distributed and that they are smoothed during the coating process. This may be due to the static interaction of the negative charge on the surface of the graphene layer with the positively charged PEDOT chains.

It was found that the film formed from the composition prepared with the 1% graphene starting material has a transmittance of greater than 90% in the wavelength range of 500 nm ( 9 ). This is due to the fact that both the PEDOT: PSS and individual graphene layers have high transmission at the visible wavelengths. As 9 shows, the thicker the film, the less transparent it becomes.

10 shows the current-voltage curves of the cells with PEDOT: PSS or Graphene-PEDOT: PSS. Compared with the PEDOT: PSS film, the addition of a small amount of graphene layers effectively increased the short-circuit current densities. This is mainly due to the high specific surface area of ultrathin graphene layers. Meanwhile, PEDOT: PSS formed a highly conductive matrix around the graphene layers. To further investigate the effects of graphene content on the performance of PEDOT: PSS, a series of experiments were prepared from the mixtures with different graphene contents. When the graphene content in the mixture increased from 0% by weight to 1% by weight, the energy conversion efficiency of the mixture was increased from 2.3% to 4.5% ( 11 ). However, further increasing the weight of graphene had little effect on the energy conversion efficiency of the mixture. These results indicate that a small amount of graphene, for example 0.5% by weight, is sufficient for electrochemical catalyzation and can effectively improve cell performance.

Measurement of the thermal conductivity of PEDOT: PSS graphene

To measure the thermal conductivity, a window glass sample of 3 mm thickness is used. First, a half-millimeter thick layer of PEDOT: PSS graphene is applied to cover the surface of the glass substrate. The coating was then placed between a second piece of glass because PEDOT: PSS graphene is electrically conductive. (If it is not properly electrically isolated, then the AC signal from the heater would leak into the PEDOT: PSS graph and affect the result of the measurement). The sample is then placed in the climate chamber while being probed with two microprobes. Next, the cables are connected to a power supply (Keithley ^™ 2400) and the voltage and current are set to 0.1 V and 10 mA, respectively. It is necessary to note that the current flowing through should be kept as low as possible in order to prevent a temperature increase caused by Joule heating. In addition, in order to increase the accuracy of measurement, the power supply was just at the measuring times (for example, about every 15 minutes) operated.

In the climatic chamber and record the relevant voltage and current of heating for every two degrees Celsius, starting at 20 (° C / min) up to 50 (° C / min). The rate of temperature rise in the climate chamber was manually set to 0.5 (° C / min). The relative humidity is also set to the currently measured value (30-40%).

The thermal conductivity of PEDOT: PSS graphene was measured at various temperatures ranging from 223 K to 375 K ( 12 ). There was an increase in thermal conductivity as the temperature rose from 223K to ambient and remained constant, then it began to fall as the temperature further increased. Finally, it decomposed over a temperature range above 375 K (above 100 ° C). The thermal conductivity varies between 0.19-0.24 (Wm-1.K-1), with the minimum measured thermal conductivity at the starting point of the measurement (223 K) and the highest value at room temperature (295 K).

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 4904844 [0007]
• JP 58-17046 [0007]
• JP 5447272 [0007]
• US 2223145 [0007]
• US 3964780 [0007]
• CA 548939 [0008]

Cited non-patent literature

• W. Hong et al. in Electrochemistry Communications 10 (2008) 1555-1558 [0015]
• M. M de Kok et al. [0028]

Claims (19)

An anti-icing film for deicing an exterior surface of a vehicle or aircraft comprising a transparent conductive film, the transparent conductive film comprising a mixture of poly (3,4-ethylenedioxythiophene) (PEDOT): poly (styrenesulfonic acid) (PSS) with graphene or a Graphene derivative is. The deicing film of claim 1, wherein the conductive polymer is applied to an exterior surface of a vehicle or aircraft. The deicing film of claim 1, wherein the conductive polymer is sandwiched between layers of a material that forms an outer surface of a vehicle or aircraft. A deicing film according to any one of claims 1-3, wherein the outer surface is a window. A deicing film according to any one of claims 1-4, which has a conductivity of about 150 S / cm. A deicing film according to any one of claims 1-5, which has a thermal conductivity of about 20 W / mk. A deicing film according to any one of claims 1-6, having a film thickness of about 6-12 μm. A deicing film according to any of claims 1-7 which has a surface resistivity of about 110-170 ohms / sq and about 90% transmittance at 550 nm. Apparatus comprising the deicing film of any of claims 1-8, connected to a power supply for supplying electrical energy to the conductive polymer. The device of claim 9, wherein the power supply provides 12 volts of voltage. The device of claim 10, wherein the power supply is from a firing controlled supply. Use of a transparent, conductive polymer as a deicing film for vehicle or airplane surfaces, wherein the transparent, conductive polymer is a mixture of poly (3,4-ethylenedioxythiophene) (PEDOT): poly (styrenesulfonic acid) (PSS) with graphene or a graphene derivative is. Use according to claim 12, wherein the surface to be deiced is a window. Use according to claim 13, wherein the film is applied to the surface of a window or wherein the film is sandwiched between two glass layers forming the window. A method of applying the deicing film of any of claims 1-8 to a vehicle or aircraft surface, comprising coating the surface using a slot die, spin coating, spray coating, or screen printing process. A deicing film according to any of claims 1-8, wherein the transparent conductive film is formed from a mixture comprising a PEDOT: PSS solution, wherein the solution comprises about 0.5-1.5 wt% PEDOT and about 1-3 wt%. PSS comprises, with a graphene solution, wherein the graphene content of about 0.1-1.5 wt%, and the solutions are combined in a ratio of 1: 2 to 2: 1. The deicing film of claim 16, wherein the PEDOT: PSS solution contains about 1 wt% PEDOT and about 2.5 wt% PSS, and the graphene solution contains about 0.25 wt%, 0.5 wt%, 0.75 wt%, or 1 wt% graphene. The deicing film of claim 17, wherein the graphene solution comprises about 1 wt% graphene and the PEDOT: PSS solution and the graphene solution are combined in a ratio of about 1: 1. A deicing film according to any one of claims 16-18, wherein the deicing film is formed by applying the mixture to a glass substrate and allowing to dry to a film.

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