WO2004113222A1 - Method for the reversible storage of atomic hydrogen on/in carbon micromaterial and/or nanomaterial and hydrogen storage device - Google Patents

Abstract

The invention relates to a method for the reversible storage of atomic hydrogen on/in carbon micromaterial and/or nanomaterial and to a hydrogen storage device. The inventive method is characterised by the following steps: a) for the storage of atomic hydrogen: arrangement of atomic hydrogen on the carbon micromaterial and/or nanomaterial by means of adsorption, especially chemisorption; b) for the release of atomic hydrogen: heating the carbon micromaterial and/or nanomaterial for thermal desorption at a determined desorption temperature such that the atomic hydrogen is separated from the carbon micromaterial and/or nanomaterial and, subsequently, recombination of the released atomic hydrogen to form hydrogen molecules.

Description

description

Process for the reversible storage of atomic hydrogen on / in carbon micro- and / or nanomaterial as well as hydrogen storage

The present invention first relates to a method for the reversible storage of atomic hydrogen on / in carbon micro- and / or nanomaterial. The invention further relates to a corresponding hydrogen storage.

The present invention consequently relates to the technical field of hydrogen storage, which has recently gained considerably in importance.

Hydrogen is regarded as a zero-emission fuel (with regard to emissions of toxic or climate-influencing process gases) because only water is generated when it is used, for example in thermal internal combustion engines, in fuel cell applications or the like. Consequently, the creation of suitable storage means for the efficient storage of hydrogen is an important goal which must be achieved before widespread use of hydrogen as a fuel can occur.

From WO 01/53199 A2 it is already known that molecular hydrogen (H ₂ ) on carbon nanomaterial can be reversibly stored in the form of so-called single-walled nanotube material (SWNT material). In the light of the present description, “reversible” means that the hydrogen molecules can be attached to the carbon nanomaterial, that is to say stored, but that the hydrogen molecules can also be detached and released from the carbon nanomaterial. The known solution provides that that the molecular hydrogen attach to the surfaces of the SWNT material that means can adsorb, and that this is released again at certain temperature conditions, that is, desorbed.

Hydrogen storage in carbon nanotubes (carbon nanotubes) with molecular hydrogen as the medium to be stored comprises the steps that suitable carbon nanomaterial must first be produced and cleaned, that the carbon nanomaterial is subsequently exposed to molecular hydrogen at or above atmospheric pressure, that the external hydrogen pressure is increased and that the stored hydrogen molecules have to be kept in the carbon nanomaterial. To release the stored hydrogen molecules, the carbon nanomaterial is heated to an elevated temperature, the so-called desorption temperature.

A disadvantage of the known solution is, inter alia, that because of the low bond strength between the hydrogen molecules and the carbon nanomaterial, only a limited amount of hydrogen molecules can be stored in / on the carbon nanomaterial under normal ambient conditions. In addition, the bond strength between the hydrogen molecules and the carbon nanomaterial in the storage state is relatively low.

Proceeding from this, the present invention is based on the object of providing a method for the reversible storage of hydrogen on / in carbon micro- and / or nanomaterial and a hydrogen storage device with which the disadvantages described can be avoided.

This object is achieved according to the invention by the method having the features according to independent claim 1, the hydrogen storage according to independent claim 15 and the particular use according to independent claim 20. Further advantages, features, details, aspects and effects of the invention result from the Subclaims, the description and the drawings. Features and details in the Described in connection with the method according to the invention, of course also apply in connection with the hydrogen storage according to the invention, and vice versa. The same applies to the use according to the invention.

The present invention is based on the knowledge that it is no longer molecular hydrogen (H ₂ ) but atomic hydrogen (H) that is stored on / in the carbon micro- and / or nanomaterial. The storage of hydrogen is according to the generation of atomic hydrogen

H ₂ + 4.5eV → H + H

prefixed. This allows a maximum storage capacity of the hydrogen on the carbon micro- and / or nanomaterial. Likewise, the bond strength between the hydrogen atoms and carbon atoms is high, so that the hydrogen is stored stably in the carbon micro- and / or nanomaterial under normal ambient conditions and beyond up to the desorption temperature.

According to the first aspect of the invention, a method for the reversible storage of atomic hydrogen on / in carbon micro- and / or - nanomaterial is provided, which is characterized by the following steps:

a) for storing atomic hydrogen: attaching the atomic hydrogen to the carbon micro- and / or - nanomaterial by means of adsorption, in particular by means of chemisorption;

b) to release atomic hydrogen:

Heating the carbon micro- and / or nanomaterial for the purpose of thermal desorption to a certain desorption temperature so that the atomic Dissolves hydrogen from the carbon micro- and / or nanomaterial, and then recombines the released atomic hydrogen to form hydrogen molecules.

The method according to the invention initially provides that the atomic hydrogen is to be reversibly stored on / in the carbon micro- and / or nanomaterial. This means that the carbon can both be attached to the carbon micro- and / or nanomaterial, that is, stored, and detached from the carbon micro- and / or nanomaterial, that is, removed.

Carbon micromaterial is a material that has particles whose dimensions are in the range of micrometers. Carbon nanomaterial is a material that has particles whose dimensions are in the range of nanometers.

In a first step, the storage step, it is initially provided that atomic hydrogen is deposited on the carbon micro- and / or nanomaterial, which takes place according to the invention by means of adsorption, in particular by means of chemisorption. Adsorption generally means the accumulation of gases or solutes at the interface of a solid or liquid phase. Chemisorption is a special case of adsorption, in which the adsorbed atoms are held on the surface of a solid, here the carbon micro- and / or nanomaterial, by chemical bonds.

For this purpose, atomic hydrogen is generated from molecular hydrogen using energy.

In a further step, the dispensing step, the carbon micro and / or nanomaterial is heated to a certain temperature, the so-called desprotion temperature, for the purpose of thermal desorption, so that the stored atomic hydrogen is separated from the carbon micro and / or or nanomaterial. Desorption is generally the back reaction of the Adsorption / chemisorption, but usually with a much higher activation energy. In order to detach and recover the atomic hydrogen, which had accumulated on the surfaces of the carbon micro and / or nanomaterial in the first storage step, from the carbon micro and / or nanomaterial, the carbon micro and / or -Nanomaterial consequently heated to at least the desorption temperature at which the atomic hydrogen can be recovered.

The hydrogen atoms detach from the carbon micro- and / or nanomaterial, that is, they are released, and then recombine to form hydrogen molecules (H ₂ ). In addition, energy is released which can be used further, in particular for increasing the temperature of the storage medium itself. This will be discussed in more detail later in the description.

The present invention is based on the knowledge that hydrogen atoms can be adsorbed / chemisorbed on the surfaces of carbon micro- and / or nanomaterials. Hydrogen remains adsorbed on the surfaces of the carbon micro- and / or nanomaterials up to the desorption temperature. By heating the hydrogen-coated / coated carbon micro- and / or nanomaterials to elevated temperatures greater than / equal to the desorption temperature, atomic hydrogen can be recovered and recombined to molecular hydrogen.

By using the highly specific surface area of carbon-micro- and / or -nano material arrangements, large amounts of hydrogen can be stored.

It is advantageously provided that the method for the reversible storage of atomic hydrogen is in the form of hydrogen atoms (H) and / or deuterium atoms (D). The method can preferably be used to store atomic hydrogen on the carbon micro- and / or nanomaterial with a maximum storage capacity of one hydrogen atom per carbon atom, equivalent to 8% by weight.

If atomic hydrogen is stored on / in carbon nanomaterial, the present invention is not restricted to certain types of carbon nanomaterials. For example, the method can be used for the reversible storage of atomic hydrogen on / in carbon nanomaterial in the form of nanotubes, in particular single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or nanofibers (nanofibers). and / or nanoshells (nanoscale) can be used. The carbon nanomaterial can be in the form of a powder, for example.

The method for the reversible storage of atomic hydrogen on / in carbon micro- and / or nanomaterial in the form of oriented carbon micro- and / or nanomaterial can advantageously be used. In a further embodiment, the carbon micro- and / or nanomaterials can have a directional structure.

In a preferred embodiment, the carbon micro- and / or nanomaterials are helical. This helical structure can be described, for example, in the form of a “spiral staircase”. The helical nanostructures can advantageously be designed as helical carbon nanofibers, which thus initially have an outer structure in the longitudinal direction in the form of the helical line and additionally an inner structure Inner structure, which in the exemplary example of the "spiral staircase" would form the individual "stair steps", comprises individual carbon planes. Such a structure has considerable advantages because of its many edges.

To carry out the method, it can initially be provided that atomic hydrogen is generated in one production step. This can be due to happen in many different ways, so that the invention is not limited to certain embodiments. Some non-exclusive examples are described below.

In general, the atomic hydrogen can first be generated in at least one atomic source. The atomic hydrogen produced can be thermal (2000 K) hydrogen.

For example, it can be provided that the atomic hydrogen is generated in at least one atom source known as a plasma source. Suitable plasma sources include, for example, low temperature DC (low temperature DC), microwave, HF plasma sources and the like.

In a further embodiment, it is conceivable that the atomic hydrogen is generated in an atom source designed as a particularly heated tungsten capillary. In the solution with the tungsten capillary, molecular hydrogen flows through it, whereby the molecular hydrogen is split into atomic hydrogen.

It is advantageously provided that the carbon micro- and / or nanomaterial for depositing atomic hydrogen is exposed to a stream of gaseous atomic hydrogen. For example, it can be done that the carbon micro- and / or nanomaterial is bombarded with hydrogen atoms, which then attach to the carbon micro- and / or nanomaterial. It can also be provided that the carbon micro- and / or nanomaterial for depositing atomic hydrogen is immersed in the at least one atom source. In a further embodiment, it can also be provided that for the attachment of atomic hydrogen to the carbon micro- and / or nanomaterial, first a metal is applied to the carbon material and that the atomic hydrogen bound to the metal, for example by dissociative adsorption of molecular Hydrogen according to H ₂ + 2 * metal → 2Η metal

Is produced on which carbon micro- and / or nanomaterial is transferred. A process that is also referred to as a "spill-over phenomenon".

The atomic hydrogen can preferably be adsorbed on the carbon micro- and / or nanomaterial at a temperature between 150 and 300 K, in particular at a temperature around 200 K.

As already described above, the atomic hydrogen is recombined into hydrogen molecules after the desorption step. It is advantageously provided that the desorbed atomic hydrogen is recombined in the gas phase.

For the purpose of desorption, the carbon micro- and / or nanomaterial is advantageously heated to temperatures above 350 K, in particular to temperatures in the range from 350 to 1000 K, preferably to a range from 750 to 800 K. At these temperatures, the hydrogen atoms first detach from the carbon micro and / or nanomaterial. At the same time, the hydrogen atoms recombine to form hydrogen molecules at these temperatures.

This reaction releases energy. The energy released in the recombination of the atomic hydrogen can advantageously be made available to further processes or process steps.

The desorption of atomic hydrogen and the subsequent recombination lead to “hot” molecules. This allows the energy invested in the storage by producing gaseous atomic hydrogen to be used further. The recombination of hydrogen in the gas phase leads to the equation 2H -> H ₂ + 4.5 eV → hot gas

According to a second aspect of the invention, a hydrogen storage for the reversible storage of atomic hydrogen is provided, comprising a storage medium for storing the atomic hydrogen. According to the invention, this hydrogen storage device is characterized in that the storage medium is in the form of carbon micro- and / or nanomaterial. Regarding the advantages and effects of this solution according to the invention, reference is made to the above statements regarding the method according to the invention. It is advantageously provided that the hydrogen storage device has means for carrying out the method according to the invention as described above.

For example, it can be provided that the storage medium is arranged in a pressure container. This ensures particularly safe storage of hydrogen. For example, a solid filling can be formed from the storage medium in a storage container, but at least the storage medium can be part of such a filling.

The storage medium can be in any form, for example in the form of powder and / or conglomerates and / or pellets or the like.

In many applications in which stored hydrogen is to be used, it is important to be able to store as large a quantity of gas as possible with the smallest possible storage volume and storage weight of the storage device (highest possible specific storage capacity). This requirement applies in particular to mobile applications, for example in the case of hydrogen tanks for vehicles which are operated with fuel cells. There is therefore a need to further increase the storage capacity of storage devices for gases, in particular hydrogen, which was previously achievable. The carbon micro- and / or nanomaterial can therefore preferably be in the form of conglomerates, the invention not being restricted to certain forms of conglomerates. The conglomerates can be, for example, bundles of carbon micro- and / or nanomaterial, as described, for example, in the already mentioned WO 01/53199 A2, the disclosure content of which is included in the present description.

An increase in the storage capacity for the gas can also be generated if the carbon micro- and / or nanomaterials are designed as coherent conglomerates. As a result, more material can be introduced into a given storage volume of a storage container than would be possible by simply filling in carbon particles with a micro- and / or nanostructure.

As a result, such a hydrogen storage device can be used for both stationary and mobile applications.

At least individual conglomerates are advantageously compressed with an apparent density higher than the apparent density of the originally loose carbon micro- and / or nanomaterials. In this way, with a comparatively small storage volume of the storage container, a large amount of gas can be stored, since more storage mass is introduced into the predefined storage volume of the storage container than would be possible by simply filling in the storage mass. The apparent density refers to the weight based on the volume of the conglomerate. The apparent density of the conglomerates produced from the originally loose particles of the carbon micro- and / or nanomaterial can advantageously be increased to at least 1.5 times, preferably at least to twice the original apparent density. Usually lies the original apparent density is approximately 1.0 g / cm ³ , so that the values to be aimed for in the compression are preferably at minimum densities of 1.5 and 2.0 g / cm ³ .

A further advantage is associated by densifying the carbon micro- and / or nanomaterials. This consists in that the individual particles are inevitably held together, so that when the storage container is unloaded, an undesired discharge of the smallest particles with the gas stream removed is counteracted. The escape of particles into downstream aggregates or the environment could, under certain circumstances, lead to technical problems or violate emission regulations with regard to very small particles.

As already described above, the storage medium is advantageous in the form of carbon nanomaterials in the form of nanotubes, in particular single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or nanofibers and / or Nanoshells and / or oriented carbon nanomaterial. Of course, the storage medium can also be in the form of carbon micromaterials, which can advantageously also have a shape as described above.

According to a further aspect of the invention, a carbon micromaterial and / or a carbon nanomaterial, in particular in the form of nanotubes, in particular single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or nanofibers and / or nanoshells and / or oriented carbon nanomaterial can be used as a storage medium for atomic hydrogen.

In summary, the present invention is therefore characterized, inter alia, by the following features and aspects: Micromaterials and / or nanomaterials (for example single-wall carbon nanotubes - SWNT, multi-walled carbon nanotubes - MWNT or the like) are coated with chemisorbed atomic hydrogen H (deuterium D)

Micromaterials and / or nanomaterials (for example multi-walled carbon nanotubes - MWNT) with diameters, set according to a preferred bonding strength between the surface (tube surfaces) atoms and the chemisorbed atoms which are chemisorbed with atomic hydrogen H (deuterium D) are coated.

The production of H or D coated micromaterials and / or nanomaterials (such as SWNT, MWNT or the like), the micromaterials and / or nanomaterials being exposed to currents of H or D atoms on a suitable substrate.

The manufacture of H or D coated micromaterials and / or nanomaterials (such as SWNT, MWNT or the like), whereby the micromaterials and / or nanomaterials on a suitable substrate are exposed to streams of H or D atoms, the streams being in a suitable low temperature DC -, microwave - or HF plasma were generated.

• The production of H or D coated micromaterials and / or nanomaterials (such as SWNT, MWNT or the like), the micromaterials and / or nanomaterials in a suitable

Low temperature DC, microwave or HF plasma can be immersed.

The production of H or D coated micromaterials and / or nanomaterials (such as SWNT, MWNT or the like), the micromaterials and / or nanomaterials being used as a hydrogen electrode in an electrochemical cell. The production of H or D coated micromaterials and / or nanomaterials (such as SWNT, MWNT or the like), whereby metal is deposited / deposited on the micromaterials and / or nanomaterials and the so-called "spill-over phenomenon" (overflow phenomenon) is used to transfer H or D, which is dissociatively adsorbed on the metal component, to the surface of the micromaterials and / or nanomaterials.

• A method for storing hydrogen atoms on the outer and / or inner surfaces of micromaterials and / or

Nanomaterials.

• A method of recovering stored hydrogen atoms by desorbing hydrogen at elevated temperatures, as evidenced by desorption spectra.

The invention will now be explained in more detail using an exemplary embodiment with reference to the accompanying drawings. Figures 1 to 5 each show diagrams in which results of different spectroscopy measurements are shown.

In the exemplary embodiment, carbon nanomaterial in the form of single-walled carbon nanotubes (SWNT) was applied to a pyrolytic graphite sample (hereinafter referred to as the NT sample). The NT sample was used as a substrate for the interaction with thermal hydrogen atoms. The SWNT material had a purity of approximately 85 wt% (weight percent), the diameter of the nanotubes was between 1.2 to 1.4 nm, and their length was in the μm to a few 10 μm range. The main contaminants are small amounts of nickel and cobalt catalyst particles. The carbon nanomaterial showed a bundle structure. The purity was confirmed by EDX (in situ) and Auger electron spectroscopy (in situ) measurements, the results of which are shown in FIG. 1. After the NT sample was exposed to an increasing current of thermal (2000 K) hydrogen atoms at 200 K, desorption spectra were recorded and a disclosed desorption of molecular hydrogen at approximately 780 K (Figure 2a). This hydrogen arises from the recombined and atomic desorption of hydrogen atoms that are chemisorbed on the surfaces of the nanotubes in the NT sample.

Desorption spectra recorded after the NT sample was exposed to molecular hydrogen, on the other hand, only reveal a background signal, which may result from a small amount of metallic impurities that remained in the NT sample from its production (FIG. 2b).

A comparison of the hydrogen desorption spectra of pyrolytic graphite, which has a hydrogen desorption at 500 K (FIG. 2c), or HOPG surfaces (highly oriented pyrolytic graphite) with desorption spectra of hydrogen from the NT sample (FIG. 2a), shows a stronger bond of the hydrogen atoms on the surface of the NT sample.

Electron loss spectra, which detect the surface electron density by the π-plasmon excitation in the substrate, are in FIG. 3 for pure and D (deuterium) coated HOPG (FIG. 3a) and NT sample surfaces (Figure 3b). The decrease in the plasmon loss peak represents the formation of chemical C-D bonds on the sample surfaces.

Vibrational spectra, which were obtained by means of high-resolution electron-energy loss spectroscopy (HREELS), are shown in FIG. The HREELS spectrum of pure HOPG shows the graphite surface phonon losses (FIG. 4a). The HREELS spectrum of HOPG covered with hydrogen additionally shows the losses caused by normal and parallel oscillations (vibrations) of Originate chemisorbed hydrogen on HOPG (Figure 4b). The HREELS spectrum of HOPG covered with D additionally shows the losses which result from normal and parallel oscillations (vibrations) of chemisorbed D onto HOPG (FIG. 4c). The HREELS spectrum of pure NT sample surfaces shows only a broad background (FIG. 5a). The HREELS spectra measured on H or D coated NT samples (FIGS. 5b, 5c) show the normal vibrations of H or D adsorbed on the nanotubes in the NT sample, and the respective parallel vibration of H.

These spectra undoubtedly show that H (D) atoms are chemisorbed on the surfaces of the NT sample, which has already resulted from the desorption spectra.

Interestingly, the normal and parallel vibration frequencies of H (D) on the NT probe were shifted to higher frequencies compared to H (D) on HOPG. This makes it clear that H (D) is more strongly bound to the NT sample than is the case with HOPG. This is in agreement with the conclusions that can be drawn from the thermal desorption spectra.

From these experimental data it becomes clear that H and D atoms adsorb on the surfaces of SWNTs. After attachment of H (D) atoms to the SWNT surfaces, the measured spectra reveal recombinant molecular H ₂ (D ₂ ) and atomic H (D) desorption between 350 K (400 K) and 950 K (1000 K), with a main peak at about 760 K (790 K). The CH (D) bond strength is greater than that seen on the flat (0001) surfaces of graphite.

Claims

claims

1. A method for the reversible storage of atomic hydrogen on / in carbon micro- and / or nanomaterial, characterized by the following

Steps: a) for storing atomic hydrogen: attaching the atomic hydrogen to the carbon micro- and / or nanomaterial by means of adsorption, in particular by means of chemisorption; b) for the emission of atomic hydrogen: heating the carbon micro- and / or nanomaterial for the purpose of thermal desorption to a certain desorption temperature so that the atomic hydrogen separates from the carbon micro- and / or nanomaterial and subsequent recombination of the released atomic Hydrogen to hydrogen molecules.

2. The method according to claim 1 for the reversible storage of atomic hydrogen in the form of hydrogen atoms and / or deuterium atoms.

3. The method according to claim 1 or 2, characterized in that atomic

Hydrogen is stored on the carbon micro- and / or nanomaterial with a maximum storage capacity of one hydrogen atom per carbon atom, equivalent to 8% by weight.

4. The method according to any one of claims 1 to 3 for the reversible storage of atomic hydrogen on carbon nanomaterial in the form of nanotubes, particularly single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or nanofibers and / or nanoshells.

5. The method according to any one of claims 1 to 4 for the reversible storage of atomic hydrogen on carbon micro and / or nanomaterial in the form of oriented carbon micro and / or nanomaterial.

6. The method according to any one of claims 1 to 5, characterized in that initially atomic hydrogen is generated in at least one atomic source.

7. The method according to claim 6, characterized in that the atomic hydrogen is generated in at least one atom source designed as a plasma source and / or as a tungsten capillary.

8. The method according to any one of claims 1 to 7, characterized in that the carbon micro- and / or nanomaterial for depositing atomic hydrogen is exposed to a stream of gaseous atomic hydrogen

9. The method according to any one of claims 6 to 8, characterized in that the carbon micro and / or nanomaterial for depositing atomic hydrogen is immersed in the at least one atom source.

10. The method according to any one of claims 1 to 9, characterized in that for depositing atomic hydrogen on the carbon micro- and / or nanomaterial, a metal is first applied to the carbon micro- and / or nanomaterial and that atomic hydrogen adsorbed on the metal on the carbon micro and / or -

Nanomaterial is transferred.

11. The method according to any one of claims 1 to 10, characterized in that the atomic hydrogen is adsorbed at a temperature between 150 and 300 K, in particular at a temperature around 200 K, on the carbon micro- and / or nanomaterial.

12. The method according to any one of claims 1 to 11, characterized in that the desorbed atomic hydrogen is recombined in the gas phase.

13. The method according to any one of claims 1 to 12, characterized in that the desorption of the atomic hydrogen at temperatures above 350 K, in particular at temperatures in the range from 350 to 1000 K, preferably in the range from 750 to 800 K, takes place.

14. The method according to any one of claims 1 to 13, characterized in that the energy released during the recombination of the atomic hydrogen is made available to further processes or process steps.

15. Hydrogen storage for the reversible storage of atomic hydrogen, comprising a storage medium for storing the atomic hydrogen, characterized in that the storage medium is designed in the form of carbon micro- and / or nanomaterial.

16. Hydrogen storage device according to claim 15, characterized in that it has means for carrying out the method according to one of claims 1 to 14.

17. Hydrogen storage device according to claim 15 or 16, characterized in that the storage medium is arranged in a pressure vessel.

18. Hydrogen storage according to one of claims 15 to 17, characterized in that the storage medium is in the form of powder and / or agglomerates and / or pellets.

19. Hydrogen storage according to one of claims 15 to 18, characterized in that the storage medium as carbon nanomaterial in the form of nanotubes (nanotubes), in particular single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or Nanofibers and / or nanoshells and / or oriented carbon

Nanomaterial is formed.

20. Use of carbon micro- and / or nanomaterial, in particular in the form of nanotubes (nanotubes), in particular single-walled nanotubes (SWNT) or multi-walled nanotubes (MWNT) and / or

Nanofibers and / or nanoshells and / or oriented carbon nanomaterial, as a storage medium for atomic hydrogen.