Login| Sign Up| Help| Contact|

Patent Searching and Data


Title:
A HYDROGEN-STORAGE-MATERIAL
Document Type and Number:
WIPO Patent Application WO/2014/096866
Kind Code:
A1
Abstract:
A hydrogen-storage-material comprising ammonia borane and poly(ethylene oxide), wherein the poly(ethylene oxide) has a weight average molecular weight of greater than or equal to 1MDa and of less than or equal to 9MDa.

Inventors:
BENNINGTON STEPHEN (GB)
LOVELL ARTHUR (GB)
HEADEN TOM (GB)
PLOSZAJSKI ANNA (GB)
COOK JOSEPH (GB)
KURBAN ZEYNEP (GB)
Application Number:
PCT/GB2013/053408
Publication Date:
June 26, 2014
Filing Date:
December 20, 2013
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
CELLA ENERGY LTD (GB)
International Classes:
C01B3/00; C01B3/04; C01B3/06
Domestic Patent References:
WO2013057588A22013-04-25
Foreign References:
CN102030313A2011-04-27
US20090302269A12009-12-10
EP2242140A12010-10-20
Other References:
ZEYNEP KURBAN ET AL: "A Solution Selection Model for Coaxial Electrospinning and Its Application to Nanostructured Hydrogen Storage Materials", JOURNAL OF PHYSICAL CHEMISTRY PART C: NANOMATERIALS AND INTERFACES, AMERICAN CHEMICAL SOCIETY, US, vol. 114, no. 49, 16 December 2010 (2010-12-16), pages 21201 - 21213, XP007918305, ISSN: 1932-7447, [retrieved on 20101116], DOI: 10.1021/JP107871V
Attorney, Agent or Firm:
BOULT WADE TENNANT (70 Grays Inn RoadLondon, Greater London WC1X 8BT, GB)
Download PDF:
Claims:
CLAIMS :

1. A hydrogen-storage-material comprising ammonia borane and poly ( ethylene oxide), wherein the poly ( ethylene oxide) has a weight average molecular weight of greater than or equal to lMDa and of less than or equal to 9MDa

2. The hydrogen-storage-material of claim 1 formed from a solidified solution comprising ammonia borane and poly ( ethylene oxide) dissolved therein.

3. The hydrogen-storage-material of claim 1 or 2 in the

form of a solid solution.

4. The hydrogen-storage-material of any one of the

preceding claims comprising 70% or less by weight of ammonia borane based on the total weight of the

material .

5. The hydrogen-storage-material of any of the preceding claims comprising less than 70%, more preferably 65% or less by weight of ammonia borane based on the total weight of the material.

6. The hydrogen-storage-material of any one of the

preceding claims comprising 20% or more by weight of ammonia borane based on the total weight of the

material .

7. The hydrogen-storage-material of any one of the

preceding claims wherein the poly ( ethylene oxide) has a weight average molecular weight of greater than or equal to 2MDa.

8. The hydrogen-storage-material of any one of the

preceding claims wherein the poly ( ethylene oxide) has a weight average molecular weight less than or equal to 8MDa.

9. The hydrogen-storage-material of any one of the

preceding claims comprising at least 30% by weight of poly ( ethylene oxide) based on the total weight of the material .

10. The hydrogen-storage-material of any of the preceding claims comprising 35% or more by weight of poly ( ethylene oxide) based on the total weight of the material.

11. The hydrogen-storage-material of any one of the

preceding claims in the form of a freeze-dried material; and/or in particulate form; and/or in the form of a solid of any desired shape or size.

12. The hydrogen-storage-material of any one of the

preceding claims consisting of ammonia borane and poly ( ethylene oxide) . 13. The hydrogen-storage-material of any of the preceding claims wherein the poly ( ethylene oxide) is a

homopolymer .

14. The hydrogen-storage-material of any of the preceding claims comprising or consisting of a mixture, preferably an intimate mixture, or homogeneous mixture of ammonia borane and poly ( ethylene oxide) . A method for releasing hydrogen stored within the hydrogen-storage-material as defined in any one of the preceding claims, the method comprising heating the material to release hydrogen from the ammonia borane.

16. The method of claim 15 wherein the hydrogen-storage- material is a fuel, or the hydrogen storage material of any of claims 1 to 14 which is a fuel.

17. A method of manufacturing of the hydrogen-storage- material as defined in any of the claims 1 to 14, the method comprising mixing a powder of ammonia borane with a powder of poly ( ethylene oxide) .

The method according to claim 17 further comprising extruding the ammonia borane and poly ( ethylene oxide), optionally including a plasticiser in the material. 19. The method of claim 18 wherein the powder of ammonia borane is mixed with the powder comprising poly ( ethylene oxide) before extruding the mixture.

20. A method of manufacturing of the hydrogen-storage- material as defined in any of the claims 1 to 14, the method comprising feeding a powder of ammonia borane and a powder of poly ( ethylene oxide) into an extruder as separate feeds and extruding to form the hydrogen- storage-material .

21. A method of manufacturing the hydrogen-storage-material as defined in any of claims 1 to 14, the method comprising dissolving ammonia borane and poly ( ethylene oxide) in a solvent to form a solution; and solidifying said solution and/or removing solvent to form the hydrogen-storage-material .

22. The method according to claim 21 wherein the hydrogen- storage-material is formed from a solution comprising ammonia borane and the poly ( ethylene oxide) by single phase electrospinning, coaxial electrospinning,

electrospraying, freeze drying or vacuum drying.

Use of poly ( ethylene oxide) in a hydrogen-storage- material comprising ammonia borane to reduce foaming and/or swelling of the hydrogen-storage-material when hydrogen is released from the ammonia borane.

Use of poly ( ethylene oxide) as a foaming-reducing and/or swelling-reducing additive in a fuel comprising ammonia borane to form a hydrogen-storage-material comprising ammonia borane and poly ( ethylene oxide) .

25. The use according to claim 23 or 24 wherein hydrogen- storage-material is defined as in anyone of claims 1 to 14.

26. The use of any one of claims 23 to 25 wherein the fuel is for use in a power source, engine and/or in a vehicle . 27. A method of generating energy/power by the thermolysis of a fuel comprising or consisting of the hydrogen- storage-material as defined in any of claims 1 to 14.

Description:
A hydrogen-storage-material

The present invention relates to a hydrogen-storage- material, to a method of releasing hydrogen from the

hydrogen-storage-material, to a method of manufacturing the hydrogen-storage-material and to the use of poly ( ethylene oxide) in a hydrogen-storage-material to reduce foaming and/or swelling of the hydrogen-storage-material when hydrogen is released from the ammonia borane.

The use of hydrogen as a fuel in portable applications holds many advantages due to the high gravimetric energy density of hydrogen and efficient conversion to electrical energy using a fuel cell with zero greenhouse gas emissions at the point of use. The main barrier to the adoption of hydrogen as a fuel is that storage remains difficult, with high pressure gas storage only achieving hydrogen capacity of ~5wt% for the fuel system. A potential solution to the storage problem is to use solid state chemical hydrides. In general these materials can contain upwards of 10wt%

hydrogen which is released upon heating of the materials. However for many of these materials the hydrogen release is non-reversible. Therefore, in order that the hydrogen release may be controlled, they have to be portioned so that only part of the hydrogen release occurs at any one time. This may be achieved for example by:

1. Moving the material as pellets or beads in batches into a hot cell for a certain period of time, where the gas is released and "empty" pellets moved to a waste container; or

2. Keeping the portions of the material static but

separated by a thermally insulating material. Each portion individually releases its hydrogen using an individual heating element.

One potential hydrogen storage material is ammonia borane (NH 3 BH 3 ) which contains approximately 12.5wt% of hydrogen that is releasable upon heating to 150°C. A major barrier to the take up of ammonia borane as a solid state hydrogen storage compound is that its melting point coincides with the first release of hydrogen at around 100°C. This causes the ammonia borane to foam, destroying its structural integrity. Thus, heating ammonia borane in its solid state, for example at temperatures of from about 100 to 250 °C in the absence of a suitable foam suppression reagent or additive, causes the ammonia borane to undergo a dramatic change in volume as it liberates hydrogen. If liquid ammonia borane exists in the material then this generates a waxy foam, it can also cause the material to swell and increase in volume sometimes by over 200% or by over 500%.

Furthermore, at lower hydrogen release temperatures, pure ammonia borane exhibits an incubation time before the hydrogen is released. For example, at 85°C pure ammonia borane may take up to 90 minutes to start releasing

significant quantities of hydrogen gas. Thus, the use of ammonia borane in hydrogen storage

materials may be problematic due to one or more of the following issues (1) relatively high reaction temperatures required for hydrogen release, (2) slow rates of hydrogen release (3) swelling and/or (4) foaming.

CN102030313 appears to describe a compound comprising ammonia borane and organic matter which is phthalic anhydride, polyethylene oxide, dextrose, mannitol or

hexaacetic ester. This document is silent on the molecular weight of polyethylene oxide used. Moreover, there is no disclosure in CN102030313 of the use of polyethylene oxide to reduce foaming and/or swelling of a hydrogen storage material upon thermolysis.

It is one object of the present invention to overcome or address the problems of prior art hydrogen storage materials or to at least provide a commercially useful alternative thereto. It is an alternative and/or additional object to provide a hydrogen storage material which is cheaper to make and/or more effective than known hydrogen storage materials. It is an alternative and/or additional object to provide hydrogen storage materials which exhibit shorter incubation times at low temperatures (for example at temperatures below 85°C) before hydrogen is released. It is an alternative and/or additional object to provide hydrogen storage

materials in which, upon heating, foaming and/or swelling is reduced.

In the first aspect there is provided a hydrogen-storage- material comprising ammonia borane and poly ( ethylene oxide), wherein the poly ( ethylene oxide) has a weight average molecular weight of greater than or equal to lMDa and of less than or equal to 9MDa. The hydrogen-storage-material may consist of ammonia borane and poly ( ethylene oxide) .

The present invention will now be further described. In the following passages different aspects of the invention are defined in more detail. Each aspect so defined may be combined with any other aspect or aspects unless clearly indicated to the contrary. In particular any feature indicated as being preferred or advantageous may be combined with any other feature or features indicated as being preferred or advantageous.

In a further aspect there is provided a method for releasing hydrogen stored within the hydrogen-storage-material as described herein, the method comprising heating the material to release hydrogen from the ammonia borane.

In a further aspect there is provided a method of

manufacturing the hydrogen-storage-material as described herein, the method comprising dissolving ammonia borane and poly ( ethylene oxide) in a solvent to form a solution; and solidifying said solution and/or removing solvent to form the hydrogen-storage-material.

In a further aspect there is provided the use of

poly ( ethylene oxide) in a hydrogen-storage-material

comprising ammonia borane to reduce foaming and/or swelling of the hydrogen-storage-material when hydrogen is released from the ammonia borane.

The inventors have surprisingly found that providing a hydrogen-storage-material comprising ammonia borane and a poly ( ethylene oxide), results in a material whose structural integrity can be substantially maintained during and after hydrogen release; and/or foaming is reduced during and/or after hydrogen release; and/or swelling is reduced during and/or after hydrogen release and/or wherein the material's incubation times can be reduced, preferably to zero. The term "foaming" refers to the mechanisms and/or processes whereby gas present in a hydrogen-storage-material generates bubbles therein as the gas is released. The term "foam" means the frothy material formed on a material as a result of gas bubbles forming inside a liquid medium.

The term "swelling" means the volume change that occurs when gas is trapped within a solid or viscous liquid which causes the material to expand or change dimensions or exceed its initial footprint or boundaries. The extent of expansion or dimension changes are typically determined by both the rate and the quantity of gas introduced to and released from the material . In one embodiment of the present invention, the hydrogen- storage-material comprises a mixture, preferably an intimate mixture, or homogeneous mixture of ammonia borane and poly ( ethylene oxide) . However, preferably, the hydrogen-storage-material is formed from a solidified solution comprising ammonia borane and poly ( ethylene oxide) dispersed, more preferably dissolved, or substantially dissolved, therein. More preferably still, the hydrogen-storage-material is in the form of a solid solution. As used herein the term solid solution includes a solid material which has been formed by dissolving ammonia borane and poly ( ethylene oxide) in a solvent, and then removing said solvent to form a solid.

Preferably, the hydrogen-storage-material has a single phase comprising ammonia borane and poly ( ethylene oxide) . The present inventors have prepared various hydrogen-storage- materials comprising ammonia borane (AB) and poly ( ethylene oxide) (PEO) and prepared an AB-PEO phase diagram using differential scanning calorimetry (details of the

experiments are provided below) . Advantageously, the present inventors have found that for materials comprising, or consisting of, poly ( ethylene oxide) up to 70% by weight, and preferably from 25 to 70% by weight, ammonia borane based on the total weight of the material, only a single melting curve is observed (with an appropriate heating regime) indicating that over this range, only a single phase is present. Moreover, advantageously, when such a material is heated to release hydrogen from the ammonia borane, no, or substantially no foaming and/or swelling is observed.

Moreover, advantageously, incubation periods at temperatures below the ammonia borane melting point (100°C) are reduced compared to when only ammonia borane is used.

The hydrogen-storage-material may comprise 95% or less, 90% or less, 85% or less, 80% or less, 75% or less by weight of ammonia borane based on the total weight of the material. Preferably, the hydrogen-storage-material comprises 70% or less, or less than 70%, by weight of ammonia borane based on the total weight of the material. The hydrogen-storage- material may comprise 65% or less, 60% or less, or 50% or less, by weight of ammonia borane based on the total weight of the material. The present inventors have found that although the amount of hydrogen present in the material increases as the ammonia borane increases, if it is present in amounts of greater than 70% by weight based on the total weight of the material then foaming and/or swelling is more likely. Advantageously for material comprising 70% or less by weight of ammonia borane based on the total weight of the material reduced, or no, foaming and/or swelling is

observed . Preferably, the hydrogen-storage-material comprises 20% or more by weight of ammonia borane based on the total weight of the material. More preferably, the hydrogen-storage- material comprises 25% or more, 30% or more, 35% or more, 40% or more, 50% or more by weight of ammonia borane based on the total weight of the material. Preferably the weight percentage of ammonia borane is kept above 20% by weight of the total weight of the material so that the hydrogen weight percentage in the material is reasonably high. It is advantageous for the weight of hydrogen to be as high as possible in order to ensure that the material is as

efficient a hydrogen storage material as possible per unit weight of material. However, this requirement needs to be balanced with the advantages associated with the effect of the poly ( ethylene oxide) on the properties of the ammonia borane upon hydrogen release.

Most preferably, the material comprises from 25% to 70%, or from 30% to 65%, or from 35% to 60%, by weight of ammonia borane based on the total weight of the material. These ranges are particularly preferred when the material has a single solid phase.

Preferably, the hydrogen-storage-material comprises 30% or more by weight of poly ( ethylene oxide) based on the total weight of the material. More preferably the hydrogen- storage-material comprises 35% or more, or 40% or more by weight of poly ( ethylene oxide) based on the total weight of the material .

The hydrogen storage material may comprise or consist of from 20 to 95% by weight of ammonia borane and from 5% to 80% by weight of poly ( ethylene oxide) based on the total weight of the material. The hydrogen storage material may comprise or consist of from 20 to 70%, by weight of ammonia borane and from 30% to 80% by weight of poly ( ethylene oxide) based on the total weight of the material. The hydrogen storage material may comprise or consist of from 30% to 68% by weight of ammonia borane and from 32% to 70% by weight of poly ( ethylene oxide) based on the total weight of the material. The hydrogen storage material may comprise or consist of from 35% to 65% by weight of ammonia borane and from 65% to 35% by weight of poly ( ethylene oxide) based on the total weight of the material.

Preferably, the hydrogen-storage-material has a weight ratio of ammonia borane to poly ( ethylene oxide) in the range of approximately 70:30 to 30:70, or from 65:35 to 40:60, or from 60:40 to 40:60. Preferably, the hydrogen-storage- material has a weight ratio of ammonia borane to

poly ( ethylene oxide) in the range of approximately 70:30 to 50:50, or 65:35 to 55:45.

As used herein the term poly ( ethylene oxide) describes a polymer having the repeat unit of :

-CH 2 -CH 2 -O- and a weight average molecular weight of greater than

20 , 00 Og/mol . Preferably, the poly ( ethylene oxide) has a weight average molecular weight of greater than or equal to lMDa (Megadalton, 1,000,000 Da), preferably greater than or equal to 1.5MDa and more preferably greater than or equal to 2MDa. It is preferable to use poly ( ethylene oxide) having weight average molecular weight of greater or equal to lMDa, preferably greater than or equal to 1.5MDa or greater than or equal to 2MDa as above these weight average molecular weights the present inventors have found that the

poly ( ethylene oxide) provides improved structural rigidity to the material compared to when lower molecular weights poly ( ethylene oxide) are used, particularly at higher temperatures. The present inventors have also found that low molecular weight poly ( ethylene oxide) s are less viscous upon melting compared to higher molecular weight poly ( ethylene oxide) s and therefore increased foaming and/or swelling is observed upon heating the material comprising the low molecular weight poly ( ethylene oxide) s (for example such as those having a molecular weight of 900, 000 Da and less) .

Examples of suitable weight average molecular weights for poly ( ethylene oxide) s include approximately 3MDa, 4MDa,

5MDa, 6MDa, 7MDa. Preferably, the poly ( ethylene oxide) has a weight average molecular weight in the range of less than or equal to 9MDa, preferably less than or equal to 8MDa. Poly ( ethylene oxide) suitable for use in the present

invention is available commercially. The higher the

molecular weight of the poly ( ethylene oxide) the more viscous the material. It may be advantageous to use higher molecular weight poly ( ethylene oxide) in order to provide a material having increased mechanical strength. However, in embodiments of the invention which require dissolution of the polymer into a solvent to form the material, it may be necessary to only use small quantities of the high molecular weight polymer so that it can be dissolved into a solvent. A mixture of one or more poly ( ethylene oxide) s having different molecular weights may be used in the present invention.

Preferably, the weight average molecular weight for

poly ( ethylene oxide) s is less than or equal to 9MDa, or less than or equal to 8MDa because above these molecular weights the poly ( ethylene oxide) becomes increasingly viscous. In particular for solution production methods this makes formation of the product more difficult.

Examples of ranges of suitable weight average molecular weights for poly ( ethylene oxide) s include from 1 MDa to

3MDa, 4MDa, 5MDa, 6MDa, 7MDa, or 8MDa; or from 1.5 MDa to 2MDa, 3MDa, 4MDa, 5MDa, 6MDa, 7MDa, or 8MDa; or from 3MDa to 4MDa, 5MDa, 6MDa, 7MDa, or 8MDa. The weight average

molecular weights for poly ( ethylene oxide) is preferably from 1 MDa to 5 MDa, particularly for freeze drying methods of forming the hydrogen storage material. High molecular weights may be more favourable for other methods.

The poly ( ethylene oxide) may be linear or branched. The poly ( ethylene oxide) may be functionalised on one or both of the carbon atoms in the CH 2 -CH 2 -0- repeat unit. The

poly ( ethylene oxide) may be functionalised on one or both of the carbon atoms in the CH 2 -CH 2 -0- repeat unit on a minority (for example less than 10%, more preferably less than 5%, more preferably still less than 2%) of the -CH 2 -CH 2 -0- repeat units such that the poly ( ethylene oxide)

substantially retains its properties. For sufficiently high molecular weight poly ( ethylene oxide) the properties are largely independent of the end functional groups therefore any end groups may be used.

The poly ( ethylene oxide) may form part of a copolymer.

Preferably the poly ( ethylene oxide) polymer comprises the repeat unit of: -CH 2 -CH 2 -O-. Preferably the

poly ( ethylene oxide)

wherein n is chosen to provide the required polymer

viscosity/chain length. Preferably the poly ( ethylene oxide) is a homopolymer. Typically it is a homopolymer formed of - CH 2 -CH 2 -O- monomer units.

The hydrogen-storage material may comprise less than 10%, or less than 5% by weight of one or more polymers other than poly ( ethylene oxide) based on the total amount of polymer present. Preferably the hydrogen-storage material does not comprise any polymers other than poly ( ethylene oxide) .

The term "weight average molecular weight" used herein is calculated as follows:

2

M

where N± is the number of molecules of molecular weight M±. Advantageously, the hydrogen-storage-material as described herein may be in the form of a freeze dried material.

The hydrogen-storage-material as described herein may be in powder or particulate form. Alternatively, the hydrogen- storage-material may be made into a solid of any desired size or shape that the application requires.

The hydrogen-storage-material may be formed into a variety of shapes including, but not limited to e.g. wafers, discs, tapes, pellets, monoliths, buttons, or other structured solid forms which preferably do not crumble or lose their initial shape. These shapes are advantageous as they can be easily transported and/or are readily moveable/portable and/or recyclable. In contrast to this, preferably, the hydrogen-storage-material is not in the form or a fibre or film, as such forms are not as easy: to transport, to move, and/or to recycle. The hydrogen-storage-material as

described herein, may be formed into a solid pre-defined shape by pressing, pelletising, casting, tableting,

extrusion, or by two or more thereof.

The incubation time of the material until hydrogen release may be measured by techniques such as thermogravimetric analysis combined with mass spectrometry, where the material is heated to a defined temperature such as 85°C and the mass loss and hydrogen release is measured as a function of time. Foaming and swelling may be measured by observing a material as it is being heated. One suitable method includes adding the material to a test tube suspended in an oil bath

maintained at a temperature such as 120 °C and measuring the foam height (if any) and pellet volume change before and after heating for long enough for hydrogen release to occur - usually 5 minutes.

Preferably the volume of the material, comparing it before hydrogen release to after hydrogen release therefrom, has changed in the range of from about 0% to about 200% by volume, more preferably, it changes in the range of from about 0% to about 100% by volume, or from about 0% to 50% or about 0% to about 10% by volume. Preferably, the volume of the material, comparing it before hydrogen release to after hydrogen release therefrom changes by less than 50% by volume, less than 20% by volume, more preferably by less than 10% by volume based on the total volume of the

material .

One qualitative test for measuring the change in volume of the hydrogen storage material is described as follows. Samples of the hydrogen storage material, for example in the form of a pellet, are placed in a test-tube or suitable container which in turn is placed in an oil-bath at 110°C. The state of the sample/pellet is monitored by visual inspection over a pre-determined period (for example 3 minutes) or after a pre-determined quantity of gas (preferably hydrogen gas) has been released (for example 80% by volume based on the total volume of gas available for release from the sample/pellet) . After this time/volume of gas release, a qualitative rating indicative of the degree of change can be accorded to the sample/pellet as follows: (It will be understood that if a sample is used in a form other than a pellet, then the term pellet in the table below will be replaced by the appropriate original form of the sample) : Qualitative Rating Appearance

1 Remains as a pellet; volume change less than 10%

2 Remains as a pellet; volume change between 10-25%

3 Pellet-like materials recovered; may change size and shape; volume change greater than 25%

4 No pellet recovered; residue height less than 5% times the height of the original sample

5 Mostly foam; residue height greater than 5 times the height of the original sample

The lower the qualitative rating the better. Where possible, at the end of the measurement, the diameter of the hydrogen storage material (for example a pellet) may be measured using vernier calipers and the degree of expansion calculated. Preferably, foaming of the material is minimal. Foaming can be measured using calipers.

The hydrogen-storage-material as described herein is

suitable for storing and releasing hydrogen upon demand. Thus, the hydrogen-storage-material may be used as a

hydrogen source, or hydrogen fuel source.

In one aspect of the present invention there is provided a method for releasing hydrogen stored within the hydrogen- storage-material as described herein, the method comprising heating the material to release hydrogen from the ammonia borane. Typically, heating the material to from about 60°C to 250°C will release at least some of the hydrogen from ammonia borane. Typically ammonia borane (AB, BH 3 NH 3 ) releases hydrogen by two mechanisms; hydrolysis by water and thermolysis when heated. The present invention is directed to thermolysis of the ammonia borane to produce hydrogen. Preferably, the hydrogen-storage-material as described herein is a fuel and/or is used as a fuel.

In one embodiment the material may be made by grinding or mixing the solid poly ( ethylene oxide) and the ammonia borane together to form an intimate mixture. In one aspect of the present invention there is provided a method of manufacturing of the hydrogen-storage-material as described herein, the method comprising mixing a powder of ammonia borane with a powder of poly ( ethylene oxide) .

Preferably the powders are fine and dry prior to mixing. Preferably the powders are mixed to form a substantially homogenous mixture.

The method may further comprise extruding the ammonia borane and poly ( ethylene oxide) . The powders of ammonia borane and poly ( ethylene oxide) may optionally be mixed with a

plasticiser, for example, such as poly ( ethylene glycol) or glycerol before extruding to form the material.

The powder of ammonia borane may be mixed with the powder comprising poly ( ethylene oxide) before extruding the

mixture. Alternatively, the hydrogen-storage-material as described herein may be manufactured by a method comprising feeding a powder of ammonia borane and a powder of

poly ( ethylene oxide) into an extruder as separate feeds and extruding to form the hydrogen-storage-material. Optionally a plasticiser may be added to one or both of the powder feeds . Typically the plasticiser will be added such that it is present in the final hydrogen-storage-material in an amount of from 1 to 5 % by weight based on the total weight of the hydrogen-storage-material.

In one aspect of the present invention there is provided a method of manufacturing the hydrogen-storage-material as described herein, the method comprising dissolving ammonia borane and poly ( ethylene oxide) in a solvent to form a solution; and solidifying said solution, and/or removing solvent to form the hydrogen-storage-material.

Any suitable solvent may be used to dissolve the ammonia borane and poly ( ethylene oxide) to form a solution.

Examples of suitable solvents include, for example, water, acetonitrile, dimethylformamide or mixtures thereof.

The solid hydrogen-storage-material may be formed from a solution comprising ammonia borane and the poly ( ethylene oxide) by using a technique that dries it rapidly such as: single phase electrospinning, electrospraying, vacuum drying, or by freeze-drying . Preferably, the method comprises dissolving and/or

dispersing poly ( ethylene ) oxide in a solvent to form a solution, then dissolving and/or dispersing ammonia borane in the solution. The solution comprising ammonia borane and poly ( ethylene ) oxide is then treated to from a solid

solution hydrogen-storage-material, and/or a single phase material. Preferably the poly ( ethylene ) oxide and/or the ammonia borane are dissolved in the solvent. In one aspect of the present invention, there is provided the use of poly ( ethylene oxide) as a foam-reducing and/or swell-reducing additive in a fuel comprising ammonia borane to form a hydrogen-storage-material comprising ammonia borane and poly ( ethylene oxide) .

In another aspect of the present invention, there is provided a method for releasing hydrogen stored within the hydrogen-storage-material as described herein, the method comprises heating the material to release hydrogen from the ammonia borane. Typically, the hydrogen-storage-material will be heated from 60°C to 250°C, more preferably from 80 °C to 170 °C. Preferably, the hydrogen-storage-material is a fuel. Preferably, the method further comprising

transferring at least a portion of the hydrogen released from the hydrogen-storage-material to a fuel cell and/or using at least a portion of the hydrogen released to

generate energy/power. The method may further comprise transferring substantially all of the hydrogen released from the hydrogen-storage-material to a fuel cell to generate energy/power . This method may be carried out in a power source, engine and/or in a vehicle. The hydrogen storage material may be used to provide

hydrogen gas as a secondary fuel in an internal combustion engine. The hydrogen provides carbon-free combustion and may be used with hydrocarbon fuels such as diesel, gasoline, liquefied petroleum gas or compressed natural gas, or mixtures thereof. More preferably the hydrogen will

additionally act as a combustion enhancer when used in proportion of 1-10% by energy to the primary fuel(s), to reduce the emissions of particulates and noxious gases.

Any suitable fuel cell may be used to convert the hydrogen produced from the hydrogen-storage-material to energy/power. Such fuel cells are known in the art.

In another one aspect of the present invention, there is provided a method of generating energy/power by the

thermolysis of a fuel comprising or consisting of the hydrogen-storage-material as described herein. Typically, the hydrogen-storage-material will be heated from 60°C to 250°C, more preferably from 80°C to 170 °C. The method may further comprise transferring at least a portion of the hydrogen released from the hydrogen-storage-material to a fuel cell to generate energy/power. The method may further comprise transferring substantially all of the hydrogen released from the hydrogen-storage-material to a fuel cell to generate energy/power. This method may be carried out in a power source, engine and/or in a vehicle.

Typically the hydrogen-storage material does not comprise a coating. One advantage of the present invention is that a coating is not required to maintain the structural integrity of the material. This is advantageous as it means that the costs and complexity of manufacturing the material are limited. Thus, advantageously, the components may be just mixed, or manufactured simply, and cheaply, but still surprisingly are sufficiently robust to act as a fuel without a coating. Alternatively, the hydrogen-storage material may further comprise a coating which permits release of hydrogen from the material through the coating. Preferably, the hydrogen-storage material will be in a solid state form. The hydrogen-storage material may be in the form of a pellet (for example a fuel pellet) . The hydrogen- storage material may be in the form of a composite or a nano-composite (for example a composite comprising nano- particles ) .

The hydrogen-storage material may be used to power or partially power a vehicle. In one embodiment, there is provided a power generator comprising :

a fuel chamber comprising the hydrogen-storage-material as described herein (preferably in the form of a pellet);

a heat source for heating the hydrogen-storage-material to release hydrogen;

a fuel cell to generate power; and

a means of transferring at least a portion of the hydrogen released to a fuel cell. When introducing elements of the present disclosure or the preferred embodiments ( s ) thereof, the articles "a", "an", "the" and "said" are intended to mean that there are one or more of the elements. The terms "comprising", "including" and "having" are intended to be inclusive and mean that there may be additional elements other than the listed elements . The foregoing detailed description has been provided by way of explanation and illustration, and is not intended to limit the scope of the appended claims. Many variations in the presently preferred embodiments illustrated herein will be apparent to one of ordinary skill in the art, and remain within the scope of the appended claims and their

equivalents .

These and other aspects of the invention will now be

described with reference to the accompanying Figures, in which :

Figure 1: shows a typical DSC curve for high wt% AB (ammonia borane) samples for a 2°C/min ramp heat. The figure shows the curve for sample FD120926-01 (60wt% AB) for a 2°C/min ramp heat produced using the Mettler Toledo STARe software. The "Peak" tool was used to calculate the strong exothermic peak on the right. Details as follows: Extrapol. Peak

100.66°C; Peak Value 6.13 mW normalised 0.77Wg _1 ; Left limit 93.09°C; Right Limit 108.60°C; Peak 100.92°C.

FD120926-01 CSC-2. 02.10.2012 17.44.36

Heatflow

FD120926-01 CSC-2, 8.0000mg

In the Figure, A is PEO/AB composite melting endotherm. B is Hydrogen release. C is Hydrogen release exotherm.

Figure 2: shows a typical DSC curve for low wt% AB samples, also for a 2°C/min ramp heat. The figure shows the curve for sample FD121002-04 (20wt% AB) for a 2°C/min ramp heat produced using STARe software. Note the additional endothermic trough at approximately 42 °C present in this sample .

FD121002-04 CSC-1, 20.10.2012 15:53:00

Heatflow

FD121002-04 CSC-1, CSC-1, 11.4000mg

In the Figure, F is Recrystallization endotherm; G is PEO/AB melting endotherm; H is Exothermic hydrogen release peak; J is Exothermic hydrogen.

Figure 3: DSC results for a heating rate of 1°C / min

On the Figure, S is Recrystallisation peak; R is Single Phase; T is Two Phase. X is Unknown Dip (l°C/min heat); Y is PEO melt (l°C/min heat); Z is AB melt (l°C/min heat).

Figure 4: DSC results for a heating rate of 2°C/min

In the Figure, S is Recrystallisation peak; R is Single Phase; T is Two Phase. X' is Unknown Dip (2°C/min heat); Y' is PEO melt (2°C/min heat); Z' is AB Melt (2°C/min heat).

The following non-limiting examples further illustrate the present invention. EXAMPLE 1

Production of 66wt% Ammonia Borane (AB) 33wt% Polyethylene Oxide (PEO) pellets by freeze drying followed by extrusion to form pellets: A 3wt% solution of PEO (molecular weight 2MDa, Sigma

Aldrich) is made in deionised water and left to stir for at least 24 hours until completely dissolved to a viscous solution. Ammonia borane powder of double the mass of PEO added is then added along with an amount of polyethylene glycol (molecular weight 200Da) to give a solids content of 0.5%. The solution is stirred for 2 hours until dissolved - the solution made is normally cloudy but no particles of AB can be seen. After AB dissolution the solution is poured into an evaporating basin of appropriate diameter such that the thickness of the solution is less than 2cm. The solution is then left in a freezer below -10°C until completely frozen (usually at least 4 hours) . Water is then removed from the solution by freeze drying under vacuum with

condenser temperature at -55°C for 2 days. The resulting composite is collected from the evaporating basin and extruded through a twin screw extruder working at 70 °C - the time in the extruder is kept below 2 minutes, a chipper is used to form the extrudate into cylindrical pellets of aspect ratio approximately 1:1.

The foam/swelling tests were done by heating the resulting pellets to 120°C by immersion of a small test tube

containing the pellets in a hot oil bath. In this case no foaming was seen but the dimensions of the pellets change showing an average reduction in volume of 5%. The pellets remain solid during the experiment and can be removed from the test tube in one piece once cooled. The samples were tested for hydrogen release by combined thermogravimetric analysis and mass spectrometry. Peak hydrogen release is observed at 4.6 minutes, compared with neat Ammonia Borane in which peak release is observed at 6.7 minutes. EXAMPLE 2

Production of 66wt% Ammonia Borane (AB) 33wt% Polyethylene Oxide (PEO) composite by vacuum drying from Acetonitrile. A 250ml Schlenk tube is filled with lg of PEO powder

(molecular weight 2MDa) and 30g of acetonitrile and the mixture is stirred for at least 24hrs at 40°C until a viscous solution is formed. To this solution 2g of Ammonia Borane (AB) powder is added at room temperature and stirred for at least 2 hours until no AB powder is visible. The Schlenk tube is sealed and slowly exposed to vacuum

(approximately 10 mbar) to remove the acetonitrile solvent which is collected before the vacuum pump using a liquid nitrogen cooled cold trap. Once all the liquid has been removed the composite solid is kept under vacuum for at least 4 hours. The resulting solid is then milled to a power using a knife mill. The resulting powder is extruded to pellets as described in example 1. The samples were tested for hydrogen release by combined thermogravimetric analysis and mass spectrometry. Peak hydrogen release is observed at 4.6 minutes, compared with neat Ammonia Borane in which peak release is observed at 6.7 minutes .

EXAMPLE 3

Production of an Ammonia Borane Polyethylene Oxide (PEO) composite by powder mixing and pressing. Ammonia Borane powder is mixed with Polyethylene Oxide

(8MDa) by shaking for 20 seconds in a sealed container. The resulting mixture is hand ground in an agate pestle and mortar for 3 minutes. Portions of this mixture are then pressed into 5mm diameter pellets using a pressure above IMPa - this results in a non-friable pellet being formed. A range of samples were made with concentrations between 10 wt.% AB to 90wt.% AB.

Heating of a pellet in a test tube in an oil bath at 120°C leads to visible gas release within 2 minutes and a volume expansion after 5 minutes below 15%.

The foam tests showed results largely similar to those seen with the freeze dried materials in that little foaming was seen below concentrations of 70 wt.% AB . However, the results were more inconsistent than the freeze dried

material for some of the lower concentration materials due to inconsistencies in complete mixing.

EXAMPLE 4

Electrospinning of an Ammonia Borane (AB) - Polyethylene Oxide (PEO) composite from Acetonitrile .

The solution for electrospinning is made by first dissolving PEO (molecular weight 2 MDa) in Acetonitrile (ACN) at 3wt% by leaving to stir at moderate temperature (~40°C) for 2 days. The AB at double the mass of PEO added is added 30 minutes prior to use. This gives enough time for the AB to dissolve, but also minimises gas release. The

electrospinning is performed through 10 nozzles

simultaneously with a flow rate of 0.5 ml/hr per nozzle. The tip to collector distance was 30cm and the electric field between the injector and the collector plate varied between 12-15 kV in order to produce spinning with a stable Taylor cone .

Thermo-gravimetric and foam tests show that these materials have similar properties to the freeze dried materials.

EXAMPLE 5

Solutions of PEO (2 MDa) were made by mixing appropriate masses of PEO and deionised water in a glass bottle and leaving to stir for at least 24 hours. Ammonia borane(AB) powder of the appropriate mass to give the desired AB:PE0 ratio was then added and the solution stirred for ~2 hours until dissolved. AB from Minal Intermediates was used for all samples. After AB dissolution the solution was poured into an evaporating basin of appropriate diameter such that the thickness of the solution was less than 2cm. The

solution was then left in a freezer until completely frozen (usually at least 4 hours) . Water was then removed from the solution by freeze drying with condenser temperature at -55°C for 2 days. If undried regions of the sample remained, freeze-drying was continued for an extra day or until dried.

The following samples were prepared:

Name ABtype AB

wt%

PEO 2M CSC N/A 0

FD120809-01 Minal (second 10

batch)

FD120820-01 Minal (second 25

batch)

FD120903-01 Minal (second 50

batch)

FD120713-01 Minal (first 66.67

batch) FD120829-01 Minal (second 75

batch)

FD120810-01 Minal (second 90

batch)

Minal Minal (second 100

CSC batch)

Table 1: AB-PEO samples analysed to produce the initial coarse phase diagram All composite samples were made using a 2M PEO solution and were freeze dried. All samples were subjected to three separate DSC runs, apart from the 100%AB sample which only had two runs. The value plotted in the phase diagram was the average temperature of the phase change for runs per sample.

Further materials were prepared and analysed having the compositions outlined in Table 2:

Table 2: AB-PEO samples produced for DSC analysis Differential Scanning Calorimetry

Initially, three TGA-DSC-MS runs were conducted on each sample. A ramp heat of 2°C/min from 35°C to 200°C was used. The temperatures of the thermodynamic events were calculated from peaks in the DSC curves using the METTLER STARe

Software. The repeat experiment was carried out at a higher resolution. This machine is considered to have a higher precision than the TGA-DSC-MS machine used for the previous runs and the slower rate of l°C/min gives a higher

resolution .

Figure 1 shows a typical DSC curve for high wt% AB samples, and Figure 2 for low wt% AB samples, both for the 2°C/min ramp heat .

Positive second differential peaks ("troughs") represent endothermic events, and negative second differential peaks ("peaks") represent exothermic events. The temperature values of the peaks were calculated using the software

(details provided above under Figure 1) and the normalised peak value in W/g was also recorded.

The present inventors have found that:

· Decreasing the AB (ammonia borane) content decreases the height of the hydrogen release peak, since the amount of hydrogen released depends on the mass of AB present

• Increasing the PEO (poly ( ethylene oxide)) content

decreases the onset temperature of hydrogen release

• Increasing the AB content increases the melting

temperature of the PEO-rich phase Taking out the hydrogen release peaks which are all

exotherms and just plotting the endotherms it is possible to get a clearer view of the phase diagram. Figures 3 and 4 compare the endotherms in both fast (2°C / min) and slow (1°C / min) ramp heat experiments.

• The AB melting curve is only seen distinctly at 70wt% AB and above. Below this the AB does not appear to melt before the hydrogen is released. This would explain why foaming is not observed at compositions below 70wt% AB .

• Below 70wt% AB the melting endotherms that can be

identified as the high AB phase does not exist,

indicating that the ammonia borane and poly ( ethylene oxide) are miscible and make a solid solution.

• Between 5% and 25% AB an extra endotherm appears just below 40°C, this changes dramatically with the heating rate and is likely to be associated with polymer recrystallization.

EXAMPLE 6

Ammonia borane and poly ( ethylene oxide) powders were

extruded using a twin screw extruder without significant pre-treatment . Composite materials were prepared by several methods :

- Forming a mixture of ammonia borane and poly ( ethylene oxide) powders and extruding this mixture

- Forming a mixture of ammonia borane, poly ( ethylene

oxide) and a suitable plasticiser (e.g. poly ( ethylene glycol) or glycerol) at a low level (e.g. 1%) and extruding this mixture

- Feeding ammonia borane and poly ( ethylene oxide) powders separately into the extrusion equipment at appropriate points A range of compositions from 60-80 wt% AB were used. The temperature of the extruder was maintained below 70 °C. Foam tests of the extrudates showed results largely similar to those seen with the freeze dried materials in that little foaming was seen below concentrations of 70 wt% AB .

EXAMPLE 7

The following comparative testing illustrates the superior anti-foaming properties of the hydrogen storage materials of the invention.

Methodology

Sample pellets comprising ammonia borane (AB) and one or more of a polyethylene oxide (PEO) ; a polyethylene glycol /polypropylene glycol block copolymer (PEG-PPG-PEG) (BLOCK; molecular weight 14.6K Daltons, 82.6% by weight PEG) ; methylcellulose (MC) and polyacrylamide (PA; molecular weight 5-6M Daltons) were prepared. Preparation involved first dissolving the relevant components in either water or tetrahydrofuran and then removing the solvent using either freeze-drying or vacuum-drying to generate the composite in powder form. Two 50mg pellets of each powder were then pressed in a 5mm cylindrical die to a density of approximately 1 gem and placed in a test-tube which in turn was placed in an oil-bath at 110°C. The state of the pellets was monitored by visual inspection over a 3 minute period and at the end assigned a qualitative rating using the qualitative rating scale referenced above. Where possible, at the end of the experiment, the diameter of each pellet was also measured using vernier calipers and the degree of expansion which had occurred calculated. The results obtained are set out in the following table (all composition percentages by weight) .

*Average of two experiments These results show that the compositions of the present invention exhibit superior resistance to foaming compared to comparative two-component compositions comprised of ammonia borane and a block glycol copolymer, ammonia borane and methyl cellulose (as disclosed in US 2009/0302269) and ammonia borane and polyacrylamide .