Indian Patents. 269475:"HYDROGEN GETTER"

Title of Invention	"HYDROGEN GETTER"
Abstract	A getter composition suitable for gettering hydrogen comprises a first melal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0 °C and 100 °C than said second metal oxide.

Full Text	Description Hydrogen Getter Technical Field [001] The present invention relates to a getter composition especially a composition which is capable of absorbing hydrogen. Background Art [002] Getters arc absorbent compositions often used within a scaled enclosure forming part of, or a housing for, the electrical or electronic device, to remove unwanted materials from the atmosphere within the enclosure. Getter compositions for the removal of hydrogen are already known. For example, unsaturated organic compounds may be used as hydrogen getters, optionally in a composition including a hy-drogenation catalyst. In US 6428612 B . , a hydrogen getter is described comprising a particulate zeolite having a portion of its sodium ions exchanged by an activated metal such as silver. The getter is provided in a flexible hydrogen permeable, moisture-impermeable sheet material in combination with a moisture absorber. US 4559471 A. describes the use of getter auxiliary means for decomposition of hydrocarbons within evacuated apparatus in which the getter auxiliary means comprises an inorganic porous carrier charged with one or more^f rhodium, copper, platinum, palladium and their oxides. US 6200494 B . describes a combination of getter materials comprising a mixture of an oxide of a transition metal, metallic palladium and a moisture absorbing material. Disclosure of Invention [003] It is an object of the present invention to provide a getter which is capable of absorbing, and has a high capacity for, hydrogen. [004] According to the invention we provide a composition suitable for use as a getter for hydrogen comprising a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0 °C and 100 °C than said second metal oxide. [005] The first metal oxide is preferably selected from an oxide of platinum, palladium, rhodium and ruthenium and is most preferably palladium oxide, PdO. The second metal oxide is preferably an oxide of a transition metal, more preferably selected from copper oxide, iron oxide, nickel oxide, cobalt oxide, cerium oxide and silver oxide. The most preferred second metal oxides are copper (II) oxide and iron oxide especially as Fe3O4 . [006] The getter composition may optionally comprise a moisture absorbing material as a further component. The moisture absorbing material is preferably a zeolite.Particularly suitable zeolites include FAU zeolites such as that sold as CBV500™ by Zcolyst International, or LTA zeolite (A-type). In a preferred embodiment the moisture absorbing material is a mixture of more than one zeolite especially a mixture of a small-pore zeolite such as an LTA zeolite which absorbs water rapidly, with a larger-pore zeolite such as a FAU zeolite which has a very high moisture absorbing capacity. An alternative moisture absorbing material may be used, e.g. an anhydrous metal oxide such as barium oxide. However, such materials are more difficult to dry when they have absorbed moisture and therefore they are not preferred moisture absorbents. When one of the first and second metal oxide is components is capable of absorbing water, the presence of an additional moisture absorbing component may be un-necessary. For example, when the second metal oxide comprises copper oxide in the form of a calcined malachite, a separate moisture absorber may not be required. [007] The getter may be provided in the form of a shaped pellet or tablet which is non- friable and resistant to breakage. In this form, the getter dimensions may vary according to the application for which it is to be used, but typically the largest dimension is between about 2mm and 30 mm. The shape of the getter may be a circular, rectangular, triangular or other polygonal tablet, having a thickness of between about 0.5 and 5 mm. Other shapes designed to provide a relatively large surface for exposure to the atmosphere may also be used. [008] A binder compound may be present in the getter to provide a strong tablet or extrudate. The binder is any suitable inorganic binder material. Preferred binders are non-porous silicas such as colloidal silica or fumed silica. The composition preferably contains up to 25% by weight of the binder. Other compounds such as lubricants, colourants etc may also be present. Pelleting aids such a graphite or metal stearates may be included in the powder mixture, but since at the preferred calcination temperatures graphite may only be partially removed, stearates, especially magnesium stearate, are preferred pelleting aids. [009] To assist with the extrusion or granulation process, or indeed to assist in the preparation of a paste which is subsequently dried and milled before lablelling, certain organic components may be added. These organic components can be readily removed during any calcination stage (as described above) leaving no residual organic species. For the tabletting process convenient organic additives include polyvinyl alcohol or cellulose materials such as microcrystalline cellulose. [010] Tabletting (or compaction) is the preferred method of preparing the final form of a getter according to the invention in the form of a shaped pellet or tablet. This is because it provides a higher density formed body than other methods of forming such as extrusion or granulation and can give products having a close dimensional tolerance. The higher density allows a higher mass loading of getter into a housing of certain volume or alternatively allows the same mass of getter to be enclosed in a smaller volume: this is an important consideration for electronic and opto-electron devices where overall physical dimensions are an important feature. The close dimensional tolerance allows preparation of getters which may fit tightly into a certain housing or retaining unit and, most importantly, allows very thin getters (for example about I mm thickness) to be prepared. Alternatively the getter may be made by other shaping techniques such as roll compacting or paste extrusion followed as necessary by calcination to remove any extrusion aids etc. [011 ] Alternatively the getter may be provided in a mouldable or printable form. In this embodiment, it is preferred to mix the getter composition with a binder, e.g. an organic binder such as those which are already known for similar use. Suitable binders include cellulose derivatives, e.g. alkyl celluloses, nitrocellulose etc of the type used in printing ink formulations for example. Alternatively a polymeric binder such as a silicone polymer may be used. In this form the getter may be applied as a layer or coating to a component which forms a part. of the device in which the getter is to be used. When the getter is provided in this form, the binder material must be permeable to the gas which is intended to be absorbed by the getter. In this form of the invention the getter composition which is suitable for application to a substrate as an ink or coating, preferably additionally comprises a solvent for said binder in which at least a part of the binder material is soluble. The selection of a suitable solvent depends upon the binder selected and may be done by the skilled person with routine experimentation. [012] The first metal,oxide may be applied by precipitation onto the second metal oxide, may be coprecipitated with the second metal oxide or may be applied to the second metal oxide by impregnation of .the second metal oxide with a solution of a precursor of the first metal oxide. Suitable soluble salts of the first or second metals include nitrates, sulphates, halides, carboxylates etc. Normally aqueous solutions are used in the preparation of the first and/or second metal oxide. In a typical precipitation method, an aqueous solution of a soluble salt of the first metal is mixed with an alkaline precipitating agent such as an alkali metal carbonate, hydroxide or bicarbonate to effect precipitation of an insoluble salt of the first metal. The precipitation may be effected in the presence of particles of the second metal oxide. The precipitated first metal compound is then heated 'to form the first metal oxide. [013] Co-precipitation methods are equally well-known in the art. A mixed solution of a soluble precursor of each of the first and second metal oxides may he pre-mixed before the addition to the mixture of a precipitant. Alternatively a solution of a precursor to one of the first or second metal oxides may be added to the precipitant separately from the solution of the precursor to the other metal oxide either prior to or simultaneously with that other metal compound precipitation in order to maintain control over the pH of the solution during precipitation. All of these methods arc well known. The co-precipitated metal compounds are then heated to form the metal oxides. [014] In a further method, the metal oxide may be applied by impregnating a solid form of the second metal oxide with a soluble compound of the first metal, such as a metal salt, e.g. a nitrate, sulphate, chloride or a salt of an organic acid such as formic or acetic acid, followed by drying. Impregnation methods are well known to the skilled person. In one common method the solid material is immersed in an excess of the solution for a period of time to enable the solution to be absorbed into the pores of the solid material, before being removed and then dried. Another common impregnation technique is the so-called "incipient wetness" technique in which a measured amount of a solution of a soluble metal compound is added slowly, e.g. by spraying, to the solid material. The volume of solution applied is normally calculated to fill a certain proportion of the pore-volume of the solid material. The impregnated metal compound is then heated to form the oxide. [015] In a preferred form of the invention, the first metal oxide is supported on the second metal oxide in such a way that the use of a separate support is unnecessary. For example, in a preferred form of the invention, palladium oxide is supported on a solid copper oxide support. Thus the first and second metal oxides may be prepared for use in the getter composition by impregnating a solid form of the second metal oxide with a solution of the first metal oxide or a precursor thereto (for example a metal chloride or nitrate), then drying and calcining the resulting composition to transform the soluble precursor into a metal oxide. Likewise the first and second metal oxides may be co- precipitated from solution or from a solution of a precursor to the metal oxide or one of the first or second metal oxide may be precipitated from a solution of a soluble precursor to the metal oxide in the presence of the other oxide in solid form, e.g. as solid particles. [016] In each case when the preparation is carried out using a soluble or insoluble precursor to the metal oxide, the precipitated or impregnated metal compound is then transformed to the oxide, usually by heating in an oxygen-containing atmosphere, i.e. by calcination. Suitably the calcination is carried out by heating the oxide precursor in an oxygen-containing atmosphere (usually air) at a temperature which is normally in the range from 175 to 500°C. The calcination temperature must be selected to be suitable for the particular metal oxides used, for example when PtO is the desired product, it should not he heated to'a temperature at which it may decompose to Pt metal and so a calcination temperature below about 400°C is preferred in that case. When copper carbonate (malachite) is used as a second metal oxide precursor, then the calcination temperature should be between about 200°C and 800°C, more preferably between about 250 - 350°C to ensure complete calcination and avoid the formation of Cu2 0. When iron carbonate is used as a precursor to iron oxide as the second metal oxide, the calcination temperature is optimally between about 300 and 550°C, since at lower temperatures the calcination may be incomplete and at higher temperatures there is a tendency for larger crystallites to form. These preparation methods are well known from the field of catalyst preparation, [017] Alternatively the first or second metal oxides may be provided upon a separate support such as a porous silica or alumina, silica-alumina or other known support material. However, in order to increase the effective mass of active gettering material, and therefore provide getters which arc as small as possible, it is preferred that a separate metal oxide or carbon support is not provided. In a preferred form of the invention the getter consists essentially of a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0 °C and 100 °C than said second metal oxide, from 0 - 25% of a binder, and optionally materials selected from a moisture absorbing material, a colourant and a lubricant. [018] As a further alternative, the first and second metal oxides may be deposited on a moisture absorbing material such as a zeolite, by co-impregnation (simultaneous or sequential), co-precipitation or otherwise. [019] The first metal oxide is preferably present at a concentration of from 0.01% to 20%, more preferably from 0.01% to 5%, especially from about 0.1% to 2%, by weight calculated as the metal and based upon the total weight of the first and second metal oxides. The second metal oxide preferably forms from 80 - 99.9%, more preferably from 99.9% to 95%, by weight of the total metal oxide components of the getter composition. When a separate moisture absorbing material is provided it forms preferably from 5 - 75 % of the total weight of the dried getter composition (including binders etc). When the getter material is in the form of a printable material, e.g. an ink or coating, so that it contains a binder and a solvent, then the amounts of first and second metal oxide and moisture absorbing material arc given on the basis of the printed and dried getter material, i.e. in the absence of a solvent. [020] For the getter to work most effectively, the dispersion of the first metal oxide is preferably relatively high such that preferably the crystallite size of the first metal oxide is in the range l-10nm. [021 ] The particle size of the components of the getter material may vary considerably. The selection of a suitable particle size and shape to form a solid shaped getter is within the experience of any skilled fonnulator. Nonnally the average diameter of the primary particles will vary between 1 micron and 200 microns, and will normally be less than 100 microns. By "primary particles", we mean the particulate form of material before granulation, extrusion, tabletting etc into larger shaped units. When the getter material is in the form of a printable material, it is preferable for the solid particles to have a maximum particle size of 30 microns. The particles may be ground, milled sieved etc using known methods to select a suitable particle size and particle size dis tribution for the desired getter material. [022] Upon absorption of hydrogen the first and/or second metal oxides may be reduced to the respective metal. [023] Example .1 Preparation of PdO / Al2O3 getter [024] A volume of aqueous PdNO solution which was calculated to fill the pores of a powdered gamma alumina support was added to the alumina a few drops at a time and mixed well in to make a paste. The concentration of the PdNO solution was calculated to provide 1 % by weight Pd, calculated as Pd metal, on the alumina support. This paste was dried at 110°C before being calcined at 350°C in air for 5 hours,during which process the PdNO is converted to PdO. After calcination the sample was combined with CBV500 zeolite in a 1:1 ,weight ratio together with 1ml of water for every gram mixed. This was again dried at 110°C before testing for H absorption performance. [025 ] The volume of hydrogen absorbed per gram of getter over time is shown graphically in Fig 1. The volume uptake for the "blank", i.e. reduced sample is also shown lor comparison. [026] Testing of the hydrogen uptake of the getter [027] The getter prepared in Example 1 was tested by measuring its hydrogen uptake over a period of time, using standard hydrogen absorption apparatus (Micromeritics). The samples were pretreated by evacuation for at least 16 hours at 400°C, following which they were transferred to the measuring instrument without exposure to atmosphere. The sample was then evacuated iri-situ for at least 4 hours. Following a leak check, the sample evacuation was continued until the leak rate is lower than 0.002 mmHg min"1. [028] Initial uptake of the sample was measured by pre-dosing the instrument manifold with hydrogen and then dosing the sample with 100 ppm H (i.e. to give a H pressure of 0,076 mm Hg) three times in succession, The sample was then dosed with successive 10,000 ppm doses of H until the pressure remained at greater than 10mm Hg for 30 minutes. [029] A blank uptake of the reduced sample. was, measured by evacuating the sample after the initial uptake tests until the leak rate was less than 0.002 mmHg min-1 and then the H uptake was tested using the same procedure as for the initial uptake. The blank uptake tests were run in order to determine the amount of hydrogen physically absorbed into the pores of the getter material. [0301 Example 2 [031 ] A getter material was prepared using the method described in Example 1, using malachite instead of alumina and using a solution concentration calculated to provide 0.5% by weight Pd (expressed as metal) on CuO. On calcination, the malachite loses water and CO and forms CuO. The PdNO is converted to PdO. The hydrogen uptake was tested by the method described and is shown graphically in Fig 2. The testing procedure differed from that given above in that when the uptake exceeded that of the sample prepared in Example 1, much larger doses of hydrogen (100,000 ppm) were used in order to indicate the capacity of the material. The test was stopped after 40 hours even though the capacity of this sample had not been reached. [032] Example 3 [033] A getter material was prepared using the method described in Example 1, using iron carbonate instead of alumina and using a solution concentration calculated to provide only 0.05% by weight Pd (expressed as metal) on Fe O . On calcination, the carbonate loses water and CO and forms iron oxide. The PdNO is converted to PdO. The 2 3 hydrogen uptake was tested by the method described and is shown graphically in Fig 3. [034] Example 4 Preparation of 0.5wt%Pd/CuO by co-precipitation. [035] 6.02g palladium nitrate solution (8.3 wt% Pd assay) was mixed with 144.67g Cu(NO ) ,6H O and made up to 200 ml with deionised water and placed in a dropping funnel. A second funnel was filled with, 1M aqueous Na CO solution. The mixed metal nitrates and the Na CO solutions were added dropwise to a 2 litre beaker r equipped with an overhead stirrer providing high agitation. The rate of addition of the two liquids was set to maintain a pH of 7.Q +/-0.5 units to precipitate the mixed oxide at constant pH. When all of the metal nitrates had been precipitated the solid was recovered by filtration and washed with boiling deionised water until the conductivity of the washings dropped to less than 10 rnS. [036] Example 5 Preparation of 0.5wt%Pt/CuO by co-precipitation. [037] The general procedure of Example 4 was used to prepare a sample of 0.5Pt/CuO. 3.19g of platinum nitrate (15.67 wt% Pt assay) were used with 144.67g Cu(NO ) .6H O. [038] Example 6 Preparation of 0.5wt%Rh/CuO by co-precipitation. [039] The general procedure of Example 4 was used to prepare a sample of 0.5Rh/CuO. 6.97g of rhodium nitrate (14.35 wt% Pt assay) were used with 144.67g Cu(NO ) .6H O. [040] Example 7 Preparation of getter as an ink [041 ] 9.99g of zeolite (BDH, 3A pore size) and 5.73g of Pd/CuO prepared as in Example 4 were added to 15.07g of a 4% by weight solution of ethyl cellulose in dipropylene glycol monomethyl ether (Dowanol DPM; Aldrich). The three components were first mixed by hand and then passed through a triple roll mill, until the maximum particle size in the ink was 30 microns. The resultant ink was printed onto metal lids using a polyester screen (18 counts per cm) which, after drying, yielded a dry, dust-free deposit with a height of 145 microns. [042] Ex ample 8 Preparation of getter as an ink [043] An ink was prepared as described as in Example 4 containing 9.09g of zeolite (BDH, 3 A pore size), 4.20g of 0.5% PdyCuO and 15.00g of a 3% by weight solution of ethyl cellulose in 2-cyclohexylethanpl (Aldrjch) structured with the addition of 0.02g of fused silica (Degussa). [044] Brief Description of the Drawings [045] The invention will be further described in the following examples and with reference to the drawings which are: [046] Figs 1 - 3 graphical representations of the hydrogen uptake over time of the getters prepared in Examples 1-3. [047] Amended claims for PCT/GB2005/050247 on entry to National Phase 1. A composition suitable for use as a getter for hydrogen comprising a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0°C and 100°C than said second metal oxide, wherein the first metal oxide is selected from an oxide of platinum, palladium, rhodium and ruthenium and wherein the second metal oxide is selected from copper oxide, iron oxide, nickel oxide, cobalt oxide and cerium oxide. 2. A composition as claimed in any one of the preceding claims, further comprising a moisture absorbing material. 3. A composition as claimed in claim 2, wherein the moisture absorbing material comprises a zeolite. 4. A composition as claimed in any one of the preceding claims in the form of a shaped pellet or tablet. 5. A composition as claimed in claim 4, wherein said pellet or tablet has a minimum dimension of 1.5mm or less. 6. A composition as claimed in any one of claims 1 - 3 in a mouldable or printable form. 7. A composition as claimed in claim 6, further comprising an organic binder and a solvent for said binder, said binder being permeable to hydrogen. 8. A composition as claimed in claim 7, wherein said binder comprises a cellulose derivative or a polymeric binder. 9. A composition as claimed in any one of the preceding claims, wherein the first metal oxide is present at a concentration of from 0.01% to 20% by weight calculated as the metal and based upon the total weight of the first and second metal oxides and the second metal oxide forms from 80 - 99.9% by weight of the total metal oxide components of the getter composition. 10. A composition as claimed in any one of the preceding claims, from which a support comprising a third metal oxide or carbon is absent. 11. A composition as claimed in any one of the'preceding claims, consisting essentially of a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0°C and 100°C than said second metal oxide, from 0 - 25% of a binder, and optionally materials selected from a moisture absorbing material, a colourant and a lubricant 12. Use of a composition as claimed in any one of claims 1 -11 as a getter for hydrogen. 13. An electronic device comprising a getter composition as claimed in any of the preceding claims.

Full Text

Description Hydrogen Getter
Technical Field
[001] The present invention relates to a getter composition especially a composition
which is capable of absorbing hydrogen. Background Art
[002] Getters arc absorbent compositions often used within a scaled enclosure forming
part of, or a housing for, the electrical or electronic device, to remove unwanted materials from the atmosphere within the enclosure. Getter compositions for the removal of hydrogen are already known. For example, unsaturated organic compounds may be used as hydrogen getters, optionally in a composition including a hy-drogenation catalyst. In US 6428612 B .
, a hydrogen getter is described comprising a particulate zeolite having a portion of its
sodium ions exchanged by an activated metal such as silver. The getter is provided in a
flexible hydrogen permeable, moisture-impermeable sheet material in combination
with a moisture absorber.
US 4559471 A.
describes the use of getter auxiliary means for decomposition of hydrocarbons within evacuated apparatus in which the getter auxiliary means comprises an inorganic porous carrier charged with one or more^f rhodium, copper, platinum, palladium and their oxides.
US 6200494 B .
describes a combination of getter materials comprising a mixture of an oxide of a transition metal, metallic palladium and a moisture absorbing material.
Disclosure of Invention
[003] It is an object of the present invention to provide a getter which is capable of
absorbing, and has a high capacity for, hydrogen.
[004] According to the invention we provide a composition suitable for use as a getter for
hydrogen comprising a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0 °C and 100 °C than said second metal oxide.
[005] The first metal oxide is preferably selected from an oxide of platinum, palladium,
rhodium and ruthenium and is most preferably palladium oxide, PdO. The second metal oxide is preferably an oxide of a transition metal, more preferably selected from copper oxide, iron oxide, nickel oxide, cobalt oxide, cerium oxide and silver oxide.
The most preferred second metal oxides are copper (II) oxide and iron oxide especially as Fe3O4 .
[006] The getter composition may optionally comprise a moisture absorbing material as a further component. The moisture absorbing material is preferably a zeolite.Particularly suitable zeolites include FAU zeolites such as that sold as CBV500™ by Zcolyst International, or LTA zeolite (A-type). In a preferred embodiment the moisture absorbing material is a mixture of more than one zeolite especially a mixture of a small-pore zeolite such as an LTA zeolite which absorbs water rapidly, with a larger-pore zeolite such as a FAU zeolite which has a very high moisture absorbing capacity. An alternative moisture absorbing material may be used, e.g. an anhydrous metal oxide such as barium oxide. However, such materials are more difficult to dry when they have absorbed moisture and therefore they are not preferred moisture absorbents. When one of the first and second metal oxide is components is capable of absorbing water, the presence of an additional moisture absorbing component may be un-necessary. For example, when the second metal oxide comprises copper oxide in the form of a calcined malachite, a separate moisture absorber may not be required.
[007] The getter may be provided in the form of a shaped pellet or tablet which is non-
friable and resistant to breakage. In this form, the getter dimensions may vary according to the application for which it is to be used, but typically the largest dimension is between about 2mm and 30 mm. The shape of the getter may be a circular, rectangular, triangular or other polygonal tablet, having a thickness of between about 0.5 and 5 mm. Other shapes designed to provide a relatively large surface for exposure to the atmosphere may also be used.
[008] A binder compound may be present in the getter to provide a strong tablet or
extrudate. The binder is any suitable inorganic binder material. Preferred binders are non-porous silicas such as colloidal silica or fumed silica. The composition preferably contains up to 25% by weight of the binder. Other compounds such as lubricants, colourants etc may also be present. Pelleting aids such a graphite or metal stearates may be included in the powder mixture, but since at the preferred calcination temperatures graphite may only be partially removed, stearates, especially magnesium stearate, are preferred pelleting aids.
[009] To assist with the extrusion or granulation process, or indeed to assist in the
preparation of a paste which is subsequently dried and milled before lablelling, certain organic components may be added. These organic components can be readily removed during any calcination stage (as described above) leaving no residual organic species. For the tabletting process convenient organic additives include polyvinyl alcohol or cellulose materials such as microcrystalline cellulose.
[010] Tabletting (or compaction) is the preferred method of preparing the final form of a
getter according to the invention in the form of a shaped pellet or tablet. This is because it provides a higher density formed body than other methods of forming such as extrusion or granulation and can give products having a close dimensional tolerance. The higher density allows a higher mass loading of getter into a housing of certain volume or alternatively allows the same mass of getter to be enclosed in a smaller volume: this is an important consideration for electronic and opto-electron devices where overall physical dimensions are an important feature. The close dimensional tolerance allows preparation of getters which may fit tightly into a certain housing or retaining unit and, most importantly, allows very thin getters (for example about I mm thickness) to be prepared. Alternatively the getter may be made by other shaping techniques such as roll compacting or paste extrusion followed as necessary by calcination to remove any extrusion aids etc.
[011 ] Alternatively the getter may be provided in a mouldable or printable form. In this
embodiment, it is preferred to mix the getter composition with a binder, e.g. an organic binder such as those which are already known for similar use. Suitable binders include cellulose derivatives, e.g. alkyl celluloses, nitrocellulose etc of the type used in printing ink formulations for example. Alternatively a polymeric binder such as a silicone polymer may be used. In this form the getter may be applied as a layer or coating to a component which forms a part. of the device in which the getter is to be used. When the getter is provided in this form, the binder material must be permeable to the gas which is intended to be absorbed by the getter. In this form of the invention the getter composition which is suitable for application to a substrate as an ink or coating, preferably additionally comprises a solvent for said binder in which at least a part of the binder material is soluble. The selection of a suitable solvent depends upon the binder selected and may be done by the skilled person with routine experimentation.
[012] The first metal,oxide may be applied by precipitation onto the second metal oxide, may be coprecipitated with the second metal oxide or may be applied to the second metal oxide by impregnation of .the second metal oxide with a solution of a precursor of the first metal oxide. Suitable soluble salts of the first or second metals include nitrates, sulphates, halides, carboxylates etc. Normally aqueous solutions are used in the preparation of the first and/or second metal oxide. In a typical precipitation method, an aqueous solution of a soluble salt of the first metal is mixed with an alkaline precipitating agent such as an alkali metal carbonate, hydroxide or bicarbonate to effect precipitation of an insoluble salt of the first metal. The precipitation may be effected in the presence of particles of the second metal oxide. The precipitated first metal compound is then heated 'to form the first metal oxide.
[013] Co-precipitation methods are equally well-known in the art. A mixed solution of a soluble precursor of each of the first and second metal oxides may he pre-mixed before
the addition to the mixture of a precipitant. Alternatively a solution of a precursor to one of the first or second metal oxides may be added to the precipitant separately from the solution of the precursor to the other metal oxide either prior to or simultaneously with that other metal compound precipitation in order to maintain control over the pH of the solution during precipitation. All of these methods arc well known. The co-precipitated metal compounds are then heated to form the metal oxides.
[014] In a further method, the metal oxide may be applied by impregnating a solid form
of the second metal oxide with a soluble compound of the first metal, such as a metal salt, e.g. a nitrate, sulphate, chloride or a salt of an organic acid such as formic or acetic acid, followed by drying. Impregnation methods are well known to the skilled person. In one common method the solid material is immersed in an excess of the solution for a period of time to enable the solution to be absorbed into the pores of the solid material, before being removed and then dried. Another common impregnation technique is the so-called "incipient wetness" technique in which a measured amount of a solution of a soluble metal compound is added slowly, e.g. by spraying, to the solid material. The volume of solution applied is normally calculated to fill a certain proportion of the pore-volume of the solid material. The impregnated metal compound is then heated to form the oxide.
[015] In a preferred form of the invention, the first metal oxide is supported on the second
metal oxide in such a way that the use of a separate support is unnecessary. For
example, in a preferred form of the invention, palladium oxide is supported on a solid
copper oxide support. Thus the first and second metal oxides may be prepared for use
in the getter composition by impregnating a solid form of the second metal oxide with
a solution of the first metal oxide or a precursor thereto (for example a metal chloride
or nitrate), then drying and calcining the resulting composition to transform the soluble
precursor into a metal oxide. Likewise the first and second metal oxides may be co-
precipitated from solution or from a solution of a precursor to the metal oxide or one of
the first or second metal oxide may be precipitated from a solution of a soluble
precursor to the metal oxide in the presence of the other oxide in solid form, e.g. as
solid particles.
[016] In each case when the preparation is carried out using a soluble or insoluble
precursor to the metal oxide, the precipitated or impregnated metal compound is then transformed to the oxide, usually by heating in an oxygen-containing atmosphere, i.e. by calcination. Suitably the calcination is carried out by heating the oxide precursor in an oxygen-containing atmosphere (usually air) at a temperature which is normally in the range from 175 to 500°C. The calcination temperature must be selected to be suitable for the particular metal oxides used, for example when PtO is the desired product, it should not he heated to'a temperature at which it may decompose to Pt
metal and so a calcination temperature below about 400°C is preferred in that case. When copper carbonate (malachite) is used as a second metal oxide precursor, then the calcination temperature should be between about 200°C and 800°C, more preferably between about 250 - 350°C to ensure complete calcination and avoid the formation of Cu2 0. When iron carbonate is used as a precursor to iron oxide as the second metal oxide, the calcination temperature is optimally between about 300 and 550°C, since at lower temperatures the calcination may be incomplete and at higher temperatures there is a tendency for larger crystallites to form. These preparation methods are well known from the field of catalyst preparation,
[017] Alternatively the first or second metal oxides may be provided upon a separate
support such as a porous silica or alumina, silica-alumina or other known support material. However, in order to increase the effective mass of active gettering material, and therefore provide getters which arc as small as possible, it is preferred that a separate metal oxide or carbon support is not provided. In a preferred form of the invention the getter consists essentially of a first metal oxide and a second metal oxide, said first metal oxide being more readily reducible in hydrogen at temperatures between 0 °C and 100 °C than said second metal oxide, from 0 - 25% of a binder, and optionally materials selected from a moisture absorbing material, a colourant and a lubricant.
[018] As a further alternative, the first and second metal oxides may be deposited on a
moisture absorbing material such as a zeolite, by co-impregnation (simultaneous or sequential), co-precipitation or otherwise.
[019] The first metal oxide is preferably present at a concentration of from 0.01% to 20%,
more preferably from 0.01% to 5%, especially from about 0.1% to 2%, by weight calculated as the metal and based upon the total weight of the first and second metal oxides. The second metal oxide preferably forms from 80 - 99.9%, more preferably from 99.9% to 95%, by weight of the total metal oxide components of the getter composition. When a separate moisture absorbing material is provided it forms preferably from 5 - 75 % of the total weight of the dried getter composition (including binders etc). When the getter material is in the form of a printable material, e.g. an ink or coating, so that it contains a binder and a solvent, then the amounts of first and second metal oxide and moisture absorbing material arc given on the basis of the printed and dried getter material, i.e. in the absence of a solvent.
[020] For the getter to work most effectively, the dispersion of the first metal oxide is
preferably relatively high such that preferably the crystallite size of the first metal oxide is in the range l-10nm.
[021 ] The particle size of the components of the getter material may vary considerably.
The selection of a suitable particle size and shape to form a solid shaped getter is
within the experience of any skilled fonnulator. Nonnally the average diameter of the
primary particles will vary between 1 micron and 200 microns, and will normally be
less than 100 microns. By "primary particles", we mean the particulate form of material
before granulation, extrusion, tabletting etc into larger shaped units. When the getter
material is in the form of a printable material, it is preferable for the solid particles to
have a maximum particle size of 30 microns. The particles may be ground, milled
sieved etc using known methods to select a suitable particle size and particle size dis
tribution for the desired getter material.
[022] Upon absorption of hydrogen the first and/or second metal oxides may be reduced
to the respective metal.
[023] Example .1 Preparation of PdO / Al2O3 getter
[024] A volume of aqueous PdNO solution which was calculated to fill the pores of a
powdered gamma alumina support was added to the alumina a few drops at a time and
mixed well in to make a paste. The concentration of the PdNO solution was calculated
to provide 1 % by weight Pd, calculated as Pd metal, on the alumina support. This paste
was dried at 110°C before being calcined at 350°C in air for 5 hours,during which
process the PdNO is converted to PdO. After calcination the sample was combined
with CBV500 zeolite in a 1:1 ,weight ratio together with 1ml of water for every gram
mixed. This was again dried at 110°C before testing for H absorption performance.
[025 ] The volume of hydrogen absorbed per gram of getter over time is shown
graphically in Fig 1. The volume uptake for the "blank", i.e. reduced sample is also shown lor comparison.
[026] Testing of the hydrogen uptake of the getter
[027] The getter prepared in Example 1 was tested by measuring its hydrogen uptake over
a period of time, using standard hydrogen absorption apparatus (Micromeritics). The
samples were pretreated by evacuation for at least 16 hours at 400°C, following which
they were transferred to the measuring instrument without exposure to atmosphere.
The sample was then evacuated iri-situ for at least 4 hours. Following a leak check, the
sample evacuation was continued until the leak rate is lower than 0.002 mmHg min"1.
[028] Initial uptake of the sample was measured by pre-dosing the instrument manifold
with hydrogen and then dosing the sample with 100 ppm H (i.e. to give a H pressure
of 0,076 mm Hg) three times in succession, The sample was then dosed with
successive 10,000 ppm doses of H until the pressure remained at greater than 10mm
Hg for 30 minutes.
[029] A blank uptake of the reduced sample. was, measured by evacuating the sample after
the initial uptake tests until the leak rate was less than 0.002 mmHg min-1 and then the

H uptake was tested using the same procedure as for the initial uptake. The blank
uptake tests were run in order to determine the amount of hydrogen physically
absorbed into the pores of the getter material.
[0301 Example 2
[031 ] A getter material was prepared using the method described in Example 1, using
malachite instead of alumina and using a solution concentration calculated to provide 0.5% by weight Pd (expressed as metal) on CuO. On calcination, the malachite loses water and CO and forms CuO. The PdNO is converted to PdO. The hydrogen uptake was tested by the method described and is shown graphically in Fig 2. The testing procedure differed from that given above in that when the uptake exceeded that of the sample prepared in Example 1, much larger doses of hydrogen (100,000 ppm) were used in order to indicate the capacity of the material. The test was stopped after 40 hours even though the capacity of this sample had not been reached.
[032] Example 3
[033] A getter material was prepared using the method described in Example 1, using iron
carbonate instead of alumina and using a solution concentration calculated to provide only 0.05% by weight Pd (expressed as metal) on Fe O . On calcination, the carbonate loses water and CO and forms iron oxide. The PdNO is converted to PdO. The
2 3
hydrogen uptake was tested by the method described and is shown graphically in Fig 3.
[034] Example 4 Preparation of 0.5wt%Pd/CuO by co-precipitation.
[035] 6.02g palladium nitrate solution (8.3 wt% Pd assay) was mixed with 144.67g
Cu(NO ) ,6H O and made up to 200 ml with deionised water and placed in a dropping funnel. A second funnel was filled with, 1M aqueous Na CO solution. The mixed metal nitrates and the Na CO solutions were added dropwise to a 2 litre beaker
r
equipped with an overhead stirrer providing high agitation. The rate of addition of the
two liquids was set to maintain a pH of 7.Q +/-0.5 units to precipitate the mixed oxide
at constant pH. When all of the metal nitrates had been precipitated the solid was
recovered by filtration and washed with boiling deionised water until the conductivity
of the washings dropped to less than 10 rnS.
[036] Example 5 Preparation of 0.5wt%Pt/CuO by co-precipitation.
[037] The general procedure of Example 4 was used to prepare a sample of 0.5Pt/CuO.
3.19g of platinum nitrate (15.67 wt% Pt assay) were used with 144.67g Cu(NO ) .6H
O.
[038] Example 6 Preparation of 0.5wt%Rh/CuO by co-precipitation.
[039] The general procedure of Example 4 was used to prepare a sample of 0.5Rh/CuO.
6.97g of rhodium nitrate (14.35 wt% Pt assay) were used with 144.67g Cu(NO ) .6H
O.
[040] Example 7 Preparation of getter as an ink
[041 ] 9.99g of zeolite (BDH, 3A pore size) and 5.73g of Pd/CuO prepared as in Example
4 were added to 15.07g of a 4% by weight solution of ethyl cellulose in dipropylene
glycol monomethyl ether (Dowanol DPM; Aldrich). The three components were first mixed by hand and then passed through a triple roll mill, until the maximum particle size in the ink was 30 microns. The resultant ink was printed onto metal lids using a polyester screen (18 counts per cm) which, after drying, yielded a dry, dust-free deposit with a height of 145 microns.
[042] Ex ample 8 Preparation of getter as an ink
[043] An ink was prepared as described as in Example 4 containing 9.09g of zeolite
(BDH, 3 A pore size), 4.20g of 0.5% PdyCuO and 15.00g of a 3% by weight solution of ethyl cellulose in 2-cyclohexylethanpl (Aldrjch) structured with the addition of 0.02g of fused silica (Degussa).
[044]
Brief Description of the Drawings
[045] The invention will be further described in the following examples and with
reference to the drawings which are:
[046] Figs 1 - 3 graphical representations of the hydrogen uptake over time of the getters
prepared in Examples 1-3. [047]

Amended claims for PCT/GB2005/050247 on entry to National Phase
1. A composition suitable for use as a getter for hydrogen comprising a first metal
oxide and a second metal oxide, said first metal oxide being more readily
reducible in hydrogen at temperatures between 0°C and 100°C than said second
metal oxide, wherein the first metal oxide is selected from an oxide of platinum,
palladium, rhodium and ruthenium and wherein the second metal oxide is
selected from copper oxide, iron oxide, nickel oxide, cobalt oxide and cerium
oxide.
2. A composition as claimed in any one of the preceding claims, further
comprising a moisture absorbing material.
3. A composition as claimed in claim 2, wherein the moisture absorbing material
comprises a zeolite.
4. A composition as claimed in any one of the preceding claims in the form of a
shaped pellet or tablet.
5. A composition as claimed in claim 4, wherein said pellet or tablet has a minimum
dimension of 1.5mm or less.
6. A composition as claimed in any one of claims 1 - 3 in a mouldable or printable
form.
7. A composition as claimed in claim 6, further comprising an organic binder and a
solvent for said binder, said binder being permeable to hydrogen.
8. A composition as claimed in claim 7, wherein said binder comprises a cellulose
derivative or a polymeric binder.
9. A composition as claimed in any one of the preceding claims, wherein the first
metal oxide is present at a concentration of from 0.01% to 20% by weight calculated as the metal and based upon the total weight of the first and second metal oxides and the second metal oxide forms from 80 - 99.9% by weight of the total metal oxide components of the getter composition.
10. A composition as claimed in any one of the preceding claims, from which a
support comprising a third metal oxide or carbon is absent.
11. A composition as claimed in any one of the'preceding claims, consisting
essentially of a first metal oxide and a second metal oxide, said first metal oxide
being more readily reducible in hydrogen at temperatures between 0°C and
100°C than said second metal oxide, from 0 - 25% of a binder, and optionally

materials selected from a moisture absorbing material, a colourant and a lubricant
12. Use of a composition as claimed in any one of claims 1 -11 as a getter for
hydrogen.
13. An electronic device comprising a getter composition as claimed in any of the
preceding claims.

Documents:

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Patent Number

269475

Indian Patent Application Number

5027/DELNP/2007

PG Journal Number

44/2015

Publication Date

30-Oct-2015

Grant Date

24-Oct-2015

Date of Filing

29-Jun-2007

Name of Patentee

JOHNSON MATTHEY PLC.

Applicant Address

40-42 HATTON GARDEN, LONDON EC 1N 8EE, UNITED KINGDOM.

Inventors:

#	Inventor's Name	Inventor's Address
1	PATRICIA BLANCO-GARCIA	9 MOUNT STREET, OXFORD, OXFORDSHIRE OX2 6DH, GREAT BRITIAIN.
2	PAUL JOHN COLLIER	12 MORECAMBE AVENUE, READING BERKSHIRE RG4 7NL, GREAT BRITAIN.
3	ALISON MARY WAGLAND	27 SPRING LANE, WATLINGTON, OXFORDSHIRE OX49 5QN, GREAT BRITAIN.
4	JOHN WEST	169 HUMMERSKNOTT AVENUE, DARLINGTON, COUNTY DURHAM DL3 8RL, GREAT BRITAIN.

PCT International Classification Number

C01B 3/00

PCT International Application Number

PCT/GB2005/050247

PCT International Filing date

2005-12-14

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	0427647.3	2004-12-17	U.K.