EP3418429A1 - Gas diffusion electrode for reducing carbon dioxide - Google Patents

Abstract

A gas diffusion electrode for the reduction of carbon dioxide with a special catalyst morphology (silver in the form of agglomerated nanoparticles with a BET surface area of at least 2 m 2 / g) and an electrolysis device are described. The gas diffusion electrode comprises at least one support and a porous coating based on an electrochemically active porous silver catalyst and a hydrophobic material. There is further provided a method of producing the gas diffusion electrode and its use as carbon dioxide GDE in e.g. the chlorine electrolysis described.

Description

The invention relates to a gas diffusion electrode (GDE) for the reduction of carbon dioxide based on porous silver powder as an electrocatalyst and their use as for the electrochemical reduction of carbon dioxide (CO ₂ ) to CO.

The invention is based on known per se gas diffusion electrodes, which usually comprise an electrically conductive support and a gas diffusion layer and a catalytically active component and are used in the chlor-alkali electrolysis. The known electrodes are used for cathodic oxygen reduction.

Gas diffusion electrodes are electrodes in which the three states of matter - solid, liquid and gaseous - are in contact with each other and the solid, electron-conducting catalyst catalyzes an electrochemical reaction between the liquid and the gaseous phase.

Various proposals for the reduction of carbon dioxide in electrolysis cells are basically known from the prior art on a laboratory scale. The basic idea is to replace the hydrogen-developing cathode of the electrolysis (for example, in the chloralkali electrolysis) by the carbon dioxide GDE.

The carbon dioxide GDE must fulfill a number of basic requirements in order to be usable in technical electrolysers. Thus, the catalyst and all other materials used must be chemically stable. Likewise, a high degree of mechanical stability is required because the electrodes are installed and operated in electrolyzers of a size of usually more than 2 m ² surface (technical size). Further properties are: a high electrical conductivity, a small layer thickness, a high internal surface and a high electrochemical activity of the electrocatalyst. Suitable hydrophobic and hydrophilic pores and a corresponding pore structure for the conduction of gas and electrolyte are just as necessary as a tightness, so that gas and liquid space remain separated from each other. The long-term stability and low production costs are further special requirements for a technically usable oxygen-consuming electrode.

Another important property is a low potential at high current density as large as possible 4kA / m ² and a high selectivity to carbon monoxide. In addition to standard silver particles as a catalyst, different silver morphologies and gold and carbon based catalysts are known for the electrochemical reduction of carbon dioxide to carbon monoxide.

Hori et al. describes that a polycrystalline gold catalyst with a current strength of 5mA / cm ² achieves a selectivity of 87% carbon monoxide.

Chen, Y. et al. (JACS (2012) 19969 ) developed gold nanoparticles having a selectivity of 98% at a current density of 6mA / cm ² and a potential of -0.4 volts. Besides gold, silver is also known as a catalyst for carbon dioxide to carbon monoxide reduction.

Lu et al. showed that nanoporous silver as an electrocatalyst for carbon dioxide to carbon monoxide production has a selectivity of 90% at a current density of 20 mA / cm ² and - 0.6 volts. ( Nat. Com. 5 (2014 ))

In the article by Lu and Jiao (Nanoenergy 2016), further nanoporous silver systems are described. All with a similar performance (selectivity of 90% at a current density of 20 mA / cm ² ). The preparation of these nanoporous systems is very expensive, difficult to transfer to industrial scale and it is difficult to increase the porosity.

For industrial applications, significantly higher current densities of at least 200 to 400 mA / cm ^{2 must be} achieved. This has not been shown in the literature for any catalyst.

The production of metallic silver and very finely divided silver nanoparticles is well known and described in a variety of publications and patents. Porous silver materials can be generated via a colloidal approach, for example, by crystallizing monodisperse polystyrene particles, the interstices between the particles are filled with silver and then the polystyrene particles are dissolved out. This process is very complex and not suitable for industrial use ( Chem. Mater. 2002, 14, 2199-2208 ). In another process, instead of the colloidal particles, a polymer gel is used as a template ( Chem. Mater. 2001, 13, 1114-1123 ), which is similarly expensive. In addition, all of these processes also require high sintering temperatures of up to 800 ° C in order to represent multistage processes.

In other processes, an AlAg or CuAg alloy is first elaborately prepared to dissolve the copper or aluminum, and high temperatures are required to produce the alloy (Nanoenergy 2016). In addition, monoliths, i. get very large particles that are not suitable for further processing in a GDE.

Less harsh conditions are in Chem. Commun., 2009, 301-303 described. Here, the porous particles are generated under pressure in an ionic liquid. However, ionic liquids are expensive, so this approach will not lead to low-cost catalysts.

The object was therefore to provide a gas diffusion electrode and a process for their preparation, with which the carbon dioxide reduction at high current density (> 2kA / m ² ) and high selectivity (> 50%) takes place.

Surprisingly, it has been found that one obtains a selective electrocatalyst based on a porous powder which can be successfully used in a GDE for carbon dioxide reduction by modifying the syntheses of silver nanoparticles by increasing the concentration of silver nitrate and onto a stabilizer waived. The preparation of micrometer-sized silver particles should be created by increasing the concentration of the products such as silver nitrate, sodium citrate and sodium borohydride by growing silver seeds. Surprisingly, however, no bulk particles are formed, but porous particles which, depending on the process salts used, sometimes have surprisingly high BET surface areas, for example of up to 8 g / m ² . The porous particles consist of agglomerated nanoparticles. The size of the nanoparticles and thus also the porosity can be controlled by the type of addition, the mixing and the concentration of the starting materials. Preferably, the primary particles have a diameter less than 100 nm. For the preparation of the porous catalyst, silver nitrate and trisodium citrate are dissolved in water. For this purpose, a solution consisting of a reducing agent such as NaBH4, KBH4 or formaldehyde dissolved in water is added with stirring. The porous particles are formed in a particle size greater than 1 micron, are then filtered off, washed and dried.

By means of these porous particles to obtain selective GDEn, when these porous particles are mixed with a fluoropolymer according to the present inventive method and then pressed the powder mixture obtained with a support member.

The invention relates to a gas diffusion electrode for the reduction of carbon dioxide, wherein the gas diffusion electrode comprises at least one planar, electrically conductive support and an applied on the support gas diffusion layer and applied electrocatalyst, wherein the gas diffusion layer consists of at least a mixture of electrocatalyst and a hydrophobic polymer, and wherein the silver acts as an electrocatalyst, characterized in that the electrocatalyst contains silver in the form of highly porous agglomerated nanoparticles and the nanoparticles have a BET surface area of at least 2 m ² /.

The thickness of the catalytically active coating consisting of PTFE and silver of the gas diffusion electrode is preferably from 20 to 1000 μm, particularly preferably from 100 to 800 μm, very particularly preferably from 200 to 600 μm.

The proportion of electrocatalyst is preferably from 80 to 97 wt .-%, particularly preferably from 90 to 95 wt .-% based on the total weight of electrocatalyst and hydrophobic polymer.

The proportion of hydrophobic polymer is preferably from 20 to 3 wt .-%, particularly preferably from 10 to 5 wt .-% based on the total weight of electrocatalyst and hydrophobic polymer.

More preferred is an embodiment of the novel gas diffusion electrode in which the hydrophobic polymer is a fluorine-substituted polymer, more preferably polytetrafluoroethylene (PTFE).

A further preferred embodiment of the gas diffusion electrode is characterized in that the electrode has a total loading of catalytically active component in a range from 5 mg / cm ² to 300 mg / cm ² , preferably from 10 mg / cm ² to 250 mg / cm ² .

Preferred is an embodiment of the gas diffusion electrode, which is characterized in that the silver particles are present as an agglomerate of silver nanoparticles with a mean agglomerate diameter (d ₅₀ measured by laser diffraction) in the range of 1 to 100 .mu.m, preferably in the range of 2 to 90 .mu.m.

A gas diffusion electrode in which the silver nanoparticles have an average diameter in the range from 50 to 150 nm was also determined by means of scanning electron microscopy with image evaluation.

The new gas diffusion electrode preferably comprises a support consisting of a material selected from the group consisting of silver, nickel, coated nickel, e.g. with silver, plastic, nickel-copper alloys or coated nickel-copper alloys, e.g. Silver-plated nickel-copper alloys on which flat textile structures were produced.

The electrically conductive carrier may in principle be a net, fleece, foam, woven fabric, braid, expanded metal. The support is preferably made of metal, more preferably nickel, silver or silver-plated nickel. The carrier may be single-layered or multi-layered. A multilayer carrier may be constructed of two or more superposed nets, nonwovens, foams, woven fabrics, braids, expanded metals. The nets, nonwovens, foams, fabrics, braids, expanded metals can be different. They may, for example, be different thicknesses or different porosity or have a different mesh size. Two or more nets, nonwovens, foams, woven fabrics, braids, expanded metals can be connected to one another, for example, by sintering or welding. Preferably, a net of nickel with a wire diameter of 0.04 to 0.4 mm and a mesh size of 0.2 to 1.2 mm is used.

Preferably, the carrier of the gas diffusion electrode is based on nickel, silver or a combination of nickel and silver.

Preference is also given to a form of the gas diffusion electrode in which the carrier is in the form of a net, woven fabric, knitted fabric, knitted fabric, fleece, expanded metal or foam, preferably a woven fabric.

In principle, the different forms of carbon dioxide electrolysis can be distinguished by how the GDE is incorporated and how this establishes the distance between the ion exchange membrane and the GDE. Many cell designs allow a gap between the ion exchange membrane and the GDE, the so-called finite-gap arrangement. The gap can be 1 to 3mm, the gap is traversed by eg KHCO3. The flow can be carried out in an upright arrangement of the electrode from top to bottom (principle of the falling film cell see eg WO 2001 / 057290A2 ) or from bottom to top (gas pocket principle, see eg DE 4,444,114A2 )

A particular embodiment of the invention represent plastic-bonded electrodes, wherein the gas diffusion electrode are provided with both hydrophilic and hydrophobic areas. These gas diffusion electrodes are chemically very resistant, especially when PTFE (polytetrafluoroethylene) is used.

Areas with a high proportion of PTFE are hydrophobic, no electrolyte can penetrate here, but in places with low PTFE content or no PTFE. The catalyst itself must be hydrophilic.

The preparation of such PTFE catalyst mixtures takes place in principle, for example, by using dispersions of water, PTFE and catalyst. To stabilize PTFE particles in the aqueous solution, emulsifiers are added in particular, and thickeners are preferably used to process the dispersion. Alternative to this wet production process is the production by dry mixing of PTFE powder and catalyst powder.

The gas diffusion electrodes according to the invention can be prepared as described above, by wet or dispersion and drying process. Particularly preferred is the dry production process.

Dispersion methods are chosen mainly for electrodes with polymeric electrolyte - such. B. successfully introduced in the PEM (polymer electrolyte membrane) fuel cell or the HCl-GDE membrane electrolysis ( WO2002 / 18675 ).

When using the GDE in liquid electrolytes, the dry process provides more suitable GDEn. When wet / resp. Dispersion process can be dispensed by strong evaporation of the water and sintering of the PTFE at 340 ° C on a strong mechanical pressing. These electrodes are usually very porous. But on the other hand, if the drying conditions are wrong, cracks can quickly form in the electrode that can penetrate liquid electrolyte. Therefore, for dry electrolyte applications such as the zinc-air battery or the alkaline fuel cell, the dry method has become established.

In dry processes, the catalyst is intensively mixed with a polymer component (preferably PTFE). The powder mixture can be formed by pressing, preferably by pressing by means of rolling process, to form a sheet-like structure, which is then applied to the carrier (see, for example, US Pat DE 3,710,168 A2 ; EP 144.002 A2 ). A likewise applicable preferred alternative describes the DE 102005023615 A2 ; In this case, the powder mixture is sprinkled on a support and pressed together with this.

In the dry process, in a particularly preferred embodiment, the electrode is made of a powder mixture consisting of silver and / or its oxides and PTFE. It is likewise possible to use doped silver and / or its oxides or mixtures of silver and / or its oxides with silver and PTFE. The catalysts and PTFE, for example, as in US 6,838,408 described in a dry mixing process and the powder compacted into a coat.

The coat is then pressed together with a mechanical support. Both the fur-forming process as well as the compression of fur and carrier can be done for example by a rolling process. Among other things, the pressing force has an influence on the pore diameter and the porosity of the GDE. Pore diameter and porosity influence the performance of the GDE.

Alternatively, the preparation of the GDE invention analogous to the DE 10.148.599A1 be carried out by applying the catalyst-powder mixture directly on a support.

The powder mixture is produced in a particularly preferred embodiment by mixing the catalyst powder and the binder and optionally other components. The mixing is preferably done in a mixing device which has fast rotating mixing elements, such as beater knives. To mix the components of the powder mixture, the mixing elements rotate preferably at a speed of 10 to 30 m / s or at a speed of 4000 to 8000 U / min. After mixing, the powder mixture is preferably sieved. The sieving is preferably carried out with a sieve device or the like with nets. equipped, whose mesh size 0.04 to 2 mm.

By mixing in the mixing device with rotating mixing elements energy is introduced into the powder mixture, whereby the powder mixture heats up strongly. If the powder is heated too much, a deterioration of the GDE performance is observed, so that the temperature during the mixing process is preferably 35 to 80 ° C. This can be done by cooling during mixing, e.g. by adding a coolant, e.g. liquid nitrogen or other inert heat-absorbing substances. Another way of controlling the temperature may be that the mixing is interrupted to allow the powder mixture to cool or by selecting suitable mixing units or changing the fill in the mixer.

The application of the powder mixture to the electrically conductive carrier takes place, for example, by scattering. The spreading of the powder mixture onto the carrier can e.g. done by a sieve. Particularly advantageously, a frame-shaped template is placed on the carrier, wherein the template is preferably selected so that it just covers the carrier. Alternatively, the template can also be chosen smaller than the surface of the carrier. In this case remains after sprinkling the powder mixture and the pressing with the carrier an uncoated edge of the carrier free of electrochemically active coating. The thickness of the template can be selected according to the amount of powder mixture to be applied to the carrier. The template is filled with the powder mixture. Excess powder can be removed by means of a scraper. Then the template is removed.

In the subsequent step, the powder mixture is pressed in a particularly preferred embodiment with the carrier. The pressing can be done in particular by means of rollers. Preferably, a pair of rollers is used. However, it is also possible to use a roller on a substantially flat base, wherein either the roller or the base is moved. Furthermore, the pressing can be done by a ram. The forces during pressing are in particular 0.01 to 7 kN / cm.

A GDE according to the invention can basically be constructed as a single layer or as a multilayer. In order to produce multilayered GDEn, powder mixtures having different compositions and different properties are applied to the carrier in layers. The layers of different powder mixtures are preferably not pressed individually with the carrier, but first applied successively and then pressed together in one step together with the carrier. For example, a layer of a powder mixture can be applied, which has a higher content of the binder, in particular a higher content of PTFE, than the electrochemically active layer. Such a layer with a high PTFE content of 6 to 100%. can act as a gas diffusion layer.

Alternatively or additionally, a gas diffusion layer made of PTFE can also be applied. For example, a layer with a high content of PTFE can be applied directly to the support as the lowest layer. Other layers of different composition can be applied for the preparation of the gas diffusion electrode. In the case of multi-layered GDEs, the desired physical and / or chemical properties can be specifically adjusted. These include u.a. the hydrophobicity or hydrophilicity of the layer, the electrical conductivity, the gas permeability. For example, a gradient of a property can be built up by increasing or decreasing the measure of the property from layer to layer.

The thickness of the individual layers of the GDE can be adjusted by the amount of powder mixture applied to the carrier and by the pressing forces during pressing. The amount of the applied powder mixture can be adjusted, for example, by the thickness of the template which is placed on the carrier to spread the powder mixture on the carrier. After the procedure of DE 10.148.599 A1 a coat is produced from the powder mixture. In this case, the thickness or density of the coat can not be set independently of one another, since the parameters of the rolls, such as roll diameter, roll spacing, roll material, tensile holding force and peripheral speed, have a decisive influence on these sizes.

The pressing force when pressing the powder mixture or layers of different powder mixtures with the carrier takes place e.g. by roll pressing with a line pressing force in the range of 0.01 to 7 kN / cm.

The carbon dioxide GDE is preferably connected as a cathode, in particular in an electrolytic cell for the electrolysis of alkali metal chlorides, preferably of sodium chloride or potassium chloride, more preferably of sodium chloride, or of hydrochloric acid.

The carbon dioxide GDE is particularly preferably used as a cathode in the chlorine electrolysis or 02 electrolysis.

Another object of the invention is therefore the use of the new gas diffusion electrode for the electrolysis of carbon dioxide to carbon monoxide, especially in the chloralkali electrolysis,
The invention also provides a process for the electrochemical conversion of carbon dioxide to carbon monoxide, characterized in that the carbon dioxide is converted cathodically to carbon monoxide at a new gas diffusion electrode as described above and chlorine or oxygen is simultaneously produced at the anode side.

In a preferred method, the current density in the reaction is at least 2 kA / m ^2, preferably at least 4 kA / m ² .

The invention is also an electrolysis device having a new gas diffusion electrode as a carbon dioxide consuming cathode.

The invention furthermore relates to a gas diffusion electrode, characterized in that the gas diffusion electrode has at least one planar electrically conductive carrier element and a gas diffusion layer applied to the carrier element and an electrocatalyst, characterized in that the gas diffusion layer consists of a mixture of silver particles and PTFE, wherein the silver particles and the fluoropolymer is applied and compacted in powder form on the carrier element, wherein the silver particles form the electrocatalyst.

Preferred is a gas diffusion electrode obtained from a manufacturing method of the invention described above.

Examples

The GDEn prepared according to the following examples were used in the oxygen electrolysis. For this purpose, a laboratory cell was used, which consisted of an anode compartment and separated by an ion exchange membrane, a cathode compartment. In the anode compartment, a KHCO ₃ solution with a concentration of 300 g / l was used, in which oxygen was produced on a commercially available DSA with iridium-coated titanium electrode. The cathode compartment was separated from the anode compartment by a commercially available Asahi Glass type F133 cation exchange membrane. Between GDE and the cation exchange membrane there was an electrolyte gap in which a NaHCO ₃ solution of the concentration of 300 g / l was circulated. The GDE was supplied via a gas space with carbon dioxide whose concentration was greater than 99.5 vol%. Anodes, membrane and gas diffusion electrode area were 3 cm ² each. The temperature of the electrolytes was 25 ° C. The current density of the electrolysis was 4 kA / m ² in all experiments.

The GDEn were prepared as follows: 3.5 kg of a powder mixture consisting of 7% by weight of PTFE powder, 93% by weight of silver powder (eg type 331 from Ferro) were mixed in an Ika mill A11 basic such that the temperature of the powder mixture did not exceed 55 ° C. This was achieved by stopping the mixing and cooling the powder mixture. Overall, mixing was performed three times with a mixing time of 10 seconds. After mixing, the powder mixture was screened with a 1.0 mm mesh screen. The sieved powder mixture was subsequently applied to an electrically conductive carrier element. The support element was a nickel mesh with a wire thickness of 0.14 mm and a mesh size of 0.5 mm. The application was carried out using a 1 mm thick template, wherein the powder was applied with a sieve with a mesh size of 1.0 mm. Excess powder extending beyond the thickness of the stencil was removed by means of a wiper. After removing the template, the carrier with the applied powder mixture is pressed by means of a roller press with a pressing force of 0.4 to 1.7 kN / cm. The roller press was removed from the gas diffusion electrode.

Example 1 Production of porous silver catalyst (Errindungsgemäß)

400 ml of a 0.1 molar AgNO ₃ solution (6.776 g of AgNO ₃ ) were mixed with 0.8 g of trisodium citrate. 400 ml of 0.2 molar sodium borohydride (3.024 g NaBH ₄ ) were added rapidly with stirring to the first solution (about 15 seconds, Re> 10000) and allowed to stir for 1 hour. The precipitate was filtered off, washed with water and dried overnight at 50 ° C.

The powder was characterized by BET, laser diffraction and scanning electron microscopy.

Particle size is about 145 nm in diameter and the BET 2.23 m2 / g (N ₂ adsorption).

Example 2 Preparation of Less Porous Silver Catalyst

400 ml of a 0.1 molar AgNO ₃ solution (6.776 g of AgNO ₃ ) are mixed with 0.8 g of trisodium citrate. 400 ml of a 0.2 molar sodium borohydride (3.024 g of NaBH ₄ ) are slowly added dropwise with stirring to the first solution (about 1 h) and allowed to stir for 1 h. The precipitate was filtered off, washed with water and dried overnight at 50 ° C. The powder is characterized by BET, laser diffraction and scanning electron microscopy.

Particle size is about 290 nm in diameter and the BET 0.99 m2 / g (N ₂ adsorption).

Producing GDE with porous silver

The GDE was prepared by the dry process, wherein 93 wt .-% silver powder according to Example 1 and 2 and silver LCP-1 Ames Goldsmith, 7 wt .-% PTFE from DYNEON TF2053 mixed in an IKA mill A11 basic and then was pressed with roller press at a force of 0.5 kN / cm. The electrode was used in the above electrolytic cell and operated at 2 and 4 kA / m ² . The Faraday efficiency for CO is shown in the table below. example BET m2 / g Current density 2 kA / m2 Current density 4kA / m2 1 2.23 66 43 2 0.99 19 7 LCP-1 0.5-0.9 0 0

The examples show that both carbon dioxide GDEn produce carbon monoxide even at high current densities. However, it can be seen very clearly that the electrode with more porous silver has a much higher selectivity to carbon monoxide than conventional silver. The selectivities at 2 kA / m2 are on the order of magnitude which is very interesting for a technical application. If silver particles LCP-1 are used, whose porosity is lower by default, no CO is produced, only hydrogen.

The BET measurements were carried out under the following conditions.
The physisorption of gases at cryogenic temperature conditions is used to determine the specific surface area (SSA) of compact finely dispersed or porous solids. Nitrogen is used as the gas at 77K in the pressure range between 0.05 to 0.30 p / p0 (p0 = saturation pressure of nitrogen at the measurement temperature) to determine the SSA of a sample. The amount of nitrogen that physiorizes on the accessible surface of the sample, is measured in a static volumetric analyzer by adding a well-defined amount of nitrogen gas to the sample cell. At the same time, the pressure increase due to the added gas is recorded after the equilibrium state is reached. The larger the total area in the measuring cell, the smaller the increase in pressure (in equilibrium), since the nitrogen content adsorbed on the surface can not contribute to the increase in pressure. Form the adsorbed molar amount of nitrogen on a sample, the total area of the sample can be calculated by multiplying the molar amount with the known adsorbent gas adsorption area.
Before adsorption measurement at 77 K, all desorbable molecules must be evaporated from the sample surface. Thus, the sample was kept under vacuum conditions at 200 ° C for several hours.
The measurement is then carried out analogously to DIN ISO standard 9277 with nitrogen of purity class 5.0 Preparation device: SmartVacPrep (Micromeritics) and gas adsorption analyzer: Gemini 2360.
Particle sizes were obtained by laser diffraction on a Malvern Mastersizer MS2000 Hydro MU instrument.

Claims (14)

A gas diffusion electrode for reducing carbon dioxide, the gas diffusion electrode having at least one planar, electrically conductive support and a gas diffusion layer and electrocatalyst deposited on the support, the gas diffusion layer consisting of at least a mixture of electrocatalyst and a hydrophobic polymer, and wherein the silver acts as an electrocatalyst , characterized in that the electrocatalyst contains silver in the form of highly porous agglomerated nanoparticles and the nanoparticles has a surface measured by BET of at least 2 m ² / g. Gas diffusion electrode according to claim 1, characterized in that the proportion of electrocatalyst of 80 to 97 wt .-%, preferably 90 to 95 wt .-% is based on the total weight of electrocatalyst and hydrophobic polymer. Gas diffusion electrode according to claim 1 or 2, characterized in that the proportion of hydrophobic polymer of 20 to 3 wt .-%, preferably 10 to 5 wt .-%, based on the total weight of electrocatalyst and hydrophobic polymer. Gas diffusion electrode according to one of claims 1 to 3, characterized in that the silver particles are present as agglomerate with a mean agglomerate diameter in the range of 1 to 100 microns, preferably in the range of 2 to 90 microns. Gas diffusion electrode according to one of claims 1 to 4, characterized in that the silver nanoparticles have an average diameter in the range of 50 to 150 nm. Gas diffusion electrode according to one of claims 1 to 5, characterized in that the electrocatalyst and hydrophobic polymer are applied in powder form on the support and compressed and form the gas diffusion layer. Gas diffusion electrode according to one of claims 1 to 6, characterized in that the hydrophobic polymer is a fluorine-substituted polymer, more preferably polytetrafluoroethylene (PTFE). Gas diffusion electrode according to one of claims 1 to 7, characterized in that the electrode has a total loading of catalytically active component in a range of 5 mg / cm ² to 300 mg / cm ² , preferably from 10 mg / cm ² to 250 mg / cm ² having. Gas diffusion electrode according to one of claims 1 to 8, characterized in that the carrier is based on nickel, silver or a combination of nickel and silver. Gas diffusion electrode according to one of claims 1 to 9, characterized in that the carrier is in the form of a network, woven, knitted, knitted, nonwoven, expanded metal or foam, preferably a fabric. Use of the gas diffusion electrode according to one of claims 1 to 10 for the electrolysis of carbon dioxide to carbon monoxide, in particular in the chloralkali electrolysis or oxygen electrolysis. A method for the electrochemical conversion of carbon dioxide to carbon monoxide, characterized in that the carbon dioxide is reacted cathodically to CO at a gas diffusion electrode according to one of claims 1 to 10 and simultaneously produced on the anode side of chlorine or oxygen. Process according to Claim 12, characterized in that the current density in the reaction is at least 2 kA / m ^2, preferably at least 4 kA / m ² . Electrolysis apparatus comprising a gas diffusion electrode according to one of claims 1 to 10 as a carbon dioxide-consuming cathode.