Patent Application
20170203973
The present invention relates to tungsten oxide and its applications, including the material and its preparation methods thereof, its special properties, applications in the field of energy storage, catalysis and the like, and more particularly, to the field of chemistry, chemical engineering, material and energy industries.
From photosynthesis to electrochemical energy storage and conversion, energy conversion is achieved through the synergistic transfer of electrons and ions (such as protons, lithium ions, etc.). in this case, the mixed electron--ion conductors have a great potential, especially for high-power electrochemical device. At present, electrochemical energy storage devices with battery and electrochemical capacitors are widely used in portable electronic devices, and are rapidly expanding to electric vehicles, grid energy storage, renewable energy storage and so on. In such devices, the physical separation of the change or chemical energy conversion is achieved through the electron and ion co-transfer, thereby realizing the energy storage and release. Materials with hybrid electron-ion conductivity have been widely used in many fields, such as solid oxide fuel cells, electrochromic materials, chemical sensors, gas separation and so on. However, the vast majority of hybrid electron-ion conductors are based on fluorides or perovskite ceramic materials operating at high temperature (e.g., greater than 500 degrees Celsius). At the same time, mixed electron-lithium ion conductors operating at room temperature, such as lithium cobalt oxide (LiCoO2) and lithium manganese oxide (LiMn2O4), are widely used as electrode materials for lithium ion batteries. But in these materials, the conduction in the solid phase is often accompanied by the obvious phase transition behavior, which limits the dynamic characteristics of the material and operation lifetime. So the cycle life of common commercial lithium-ion battery is often limited to only a few hundred times. Although the electron-proton conductor materials at low temperature can be produced by simply mixing an electron conductive material (e.g., metal, carbon material, conductive polymer, conductive oxide, etc.) with a proton-conductive material (e.g. water, aqueous polymer, hydrated oxide), these materials themselves do not have charge storage capabilities and therefore cannot be used as energy storage materials. Although ruthenium oxide with a hydrated structure has high electron-proton conductivity at room temperature, as well as a high electrochemical capacitance (700 Faraday per grain), the high price limits its large-scale applications.
In general, electrodes of electrochemical energy storage devices such as batteries and electrochemical capacitors are formed by integrating a conductive material (graphite, carbon black, etc.), a redox active material (oxide, etc.), and a porous ion-conducting network. The porous network structure provides a transport channel for the electrolyte. However, the electronic and ionic conductivity of the electrode formed by such a simple mixture of a variety of material composition is not high, and the structure is also not stable enough. Therefore, the energy density, power density and cycle life of such energy storage devices are limited by the conductivity of the electrode, the ion mobility, the reversibility of the redox reaction, the side reactions, and so on. In order to achieve higher energy storage performance, the use of mixed electron ion conductor directly as the electrode material will have a greater promise. This material can simultaneously provide redox capacity, high conductivity, fast ionic conductivity, and a stable structure, so that large capacity, high power, and long life can be achieved at the same time. In addition to being able to manufacture energy storage devices, hybrid electron-ion conductors also have other broad applications, such as catalysis, separation, and the like. However, so far it has been very difficult to design and manufacture such a material.
In fact, ion conduction is a very common phenomenon in nature. For example, many biological behaviors, such as photosynthesis, adenosine triphosphate synthesis, and the maintenance of biological tissue acidic environment all involve proton transport. In these processes, the proton conduction is achieved using their efficient proton channels. Such proton channel is prevalent in some specific protein structure, and they can be constructed by the internal single-stranded water structure. Gramicidin A, for example, is a widely studied simple proton polypeptide that can dimerize within the hydrophobic interior of the phospholipid bilayer of a cell to form a beta-helix structure that contains a single-stranded water channel, which can effectively conduct protons.
By mimicking the natural structure of the biomaterial, we designed and synthesized a novel hybrid electron-proton conductive material. Through controlling the growth of crystals during the synthesis process, we have prepared tungsten oxide materials with unique structures, which have internal continuous channels that can efficiently conduct protons. By performing simple doping, the tungsten oxide material can become a highly efficient electron conductor as well, thereby forming an electron-proton conductor having excellent properties. This material is used in electrochemical storage devices and shows excellent energy, power and cycling performance compared to conventional materials. Due to its special structure, it is expected that this tungsten oxide material can also be applied to other fields.
The object of the present invention is to provide a novel hybrid electron-proton conductive material, a method for producing the same, and an application thereof. Such materials are tungsten oxides having special properties. The method is to synthesize tungsten oxide material with special properties, and realize high proton conductivity; to realize high electron conductivity through simple cation doping. Such materials can be used as electrochemical energy storage materials, fuel cell catalyst materials and for many other applications.
The technical proposal of the invention is as follows:
A novel hybrid electron-proton conductive material for novel battery, its manufacturing method and applications, and the material has the following characteristics:
A possible preparation method comprises the steps of:
Wherein, the precursor material can be sodium tungstate or ammonium tungstate.
The acid can be hydrochloric acid or sulfuric acid to adjust pH value of the precurors.
It should be noted that the present invention does not specifically limit the number of water contained in the hydrate, and the tungsten trioxide hydrate obtained by the above method is within the scope of the present application. Most preferably, however, the hydrate fraction is 0 to 1, i.e., WO3.xH2O, where x=0-1.
It should be also noted that the precursor material may be any compound as long as it can obtain the tungsten element in the final product, but sodium tungstate and ammonium tungstate are particularly preferable. Here, the specific synthesis steps may be as follows:
In addition, the tungsten oxide prepared by the above-described method can be subjected to a doping treatment with a hetero-element. That is, the doped tungsten oxide can be obtained by immersing the tungsten oxide in a salt solution containing different doping elements, separated by centrifugation and then heat-treated for a certain time at increased temperature. Wherein, the salt solution is 0.1 to 6 mol per liter of strontium oxide precursor solution, calcium oxide precursor solution, strontium chloride solution, calcium oxalate solution, sodium chloride solution, chloroplatinic acid solution, palladium chloride solution, copper acetate solution; the treatment is conducted for a period of 4 to 8 hours and the temperature of the heat treatment is 200 to 800° C. It should be noted that the above-mentioned various solutions are merely for providing the hetero-elements in the final product, and therefore, the type of the solution used is not limited thereto, and the solutions herein are just a few examples.
In addition, the acidified intermediate is formed with an acidified tungsten-containing precursor material together with ammonium sulfate. The concentration of ammonium sulfate is 1% to 10%.
It should be noted that the ratio of the dopant element in the present application is not particularly limited, and any doped tungsten oxide or tungsten oxide hydrate prepared by the above method is within the scope of the present application.
Applications of the materials obtained by the methods of the present application include:
As mentioned previously, the present application is directed to protecting a particular tungsten-containing material that can be obtained by the above-described method. This material has excellent properties as electrochemical energy storage materials as well as fuel cell electrolytes and electrochemical catalyst materials (to be described in detail below). Therefore, tungsten-containing materials obtained by the above process of the present invention, should be included in the scope of protection of the present application. However, for the sake of clarity, in the present invention, the tungsten-containing material includes tungsten oxide (WO3) and tungsten oxide hydrate (WO3.xH2O), doped tungsten oxide (MxWO3, M=Li, Na, K, Ca, Mg, Sr, Ba, etc.), doped tungsten oxide hydrate (MxWO3.xH2O, M=Li, Na, K, Ca, Mg, Sr, Ba, etc.), tungsten oxide composites (including tungsten with metals, metal oxides, carbon materials and polymers), tungsten oxide hydrate composites (including tungsten oxide hydrate and metal, metal oxides, carbon materials, polymers)
In the present invention, the tungsten oxide and tungsten oxide hydrate have high conductivity and rapid proton-proton capability.
The positive effect of the present invention is that:
The advantages of the present invention will be further elucidated by way of specific examples, but the scope of the present invention is not limited to the following examples.
The reagents and starting materials used in the present invention are commercially available.
Firstly, tungsten oxide materials with above-mentioned special properties were synthesized by hydrothermal method, co-precipitation method, thermal decomposition method or spray drying method. For example, for the synthesis of tungsten oxide hydrate (WO3 xH2O), sodium tungstate or sodium tungstate hydrate is dissolved in deionized water to form a the homogeneous solution with concentration of 0.1% -20%, followed by adding sulfuric acid or hydrochloric acid; Then adding 1 to 10% of ammonium sulfate to form an intermediate; then the mixed solution is transferred into a reaction vessel to heat the reaction, reacting at a temperature of 90 to 200 degrees Celsius for 1 to 96 hours to obtain the product; after the reaction the reactor is cooled down, the product is washed and dried to obtain the tungsten oxide material.
(1) Sodium tungstate was used as a tungsten precursor material and dissolved in deionized water to form a homogeneous solution at a concentration of 5% by mass. An appropriate amount of hydrochloric acid was added to make the pH of the solution=1.5. Then, 5% ammonium sulfate was added to form an intermediate, and the mixed solution was transferred to a reaction vessel for reaction at 160° C. for 72 hours to finally obtain a tungsten trioxide material. The proton conductivity of tungsten oxide material is shown in
In addition, the obtained tungsten oxide was made into electrodes to explore the application and performance as electrochemical energy storage materials. In this embodiment, for example, in the case of electrochemical capacitor application, the tungsten oxide material can be configured as an electrode paste or in combination with a conductive material to form an electrode. In the present embodiment, specifically, the above-mentioned tungsten oxide is uniformly mixed with the conductive agent, the binder and the dispersion solvent in a certain mass ratio (8:1:1) to obtain an electrode paste, which is coated on the current collector, and dried for 10 hours to form an electrode. The obtained electrode was combined with the positive electrode, the glass fiber separator and the electrolyte (2 mol sulfuric acid) to form the initial cell. The battery was activated to obtain tungsten-acid battery with excellent performance. The obtained electrode was paired with a lead oxide electrode, separated by a separator, an acidic electrolyte was added to form a single cell, and electrochemical test was performed. The results are shown in
Besides the above specific methods, the inventors of the present application also obtained different types of tungsten materials and electrodes by the following ratios, all achieving similar properties to those of Example 1 (except for the parameters listed in Table 1, all other parameters are the same):
It should be noted that the tungsten oxide prepared by the above method may contain a hydrated tungsten oxide which depends on the reaction temperature and time, but the present application does not make any restriction to the number of hydrated water molecules contained in the oxides. Any tungsten oxide and/or tungsten oxide hydrate obtained by the above process is within the scope of the present application.
(2) Doped tungsten oxide can be obtained by soaking tungsten oxide in a salt solution of different doping elements, followed by centrifugation separation and heat treatment for a certain time.
Wherein, the salt solution is 0.1 to 6 mol per liter of the strontium chloride solution, or the calcium chloride solution; the time of heat treatment is 4-8 hours, and the temperature of the heat treatment is 200-800 degrees Celsius. Specific ratios are shown in Table 2:
Among them, the electronic conductivity of the product 6 is measured, and the performance data is shown in
(1) First, a tungsten oxide material (specifically, a tungsten oxide hydrate (WO3 xH2O)) was synthesized by dissolving sodium tungstate or sodium tungstate hydrate in deionized water to form a homogeneous solution having a concentration of 0.1 wt % 20 wt. % of tungsten salt, followed by adding the appropriate amount of sulfuric acid or hydrochloric acid to adjust the pH value to 1 to 3, so that the solution acidification; then adding 1 wt. %-10 wt. % of ammonium sulfate to form intermediates; the resulting mixed solution was transferred to a reactor. The reaction product is obtained at a temperature of 90 to 200° C. for 1 to 96 hours. After the completion of the reaction, the product is cooled down, washed and dried to obtain a tungsten oxide material. In Table 3, the specific tungsten oxide material is the one described in specific example 1.
(2) Doped tungsten oxide can be obtained by reacting tungsten oxide with a salt solution of different dopant elements. In the specific examples, the ratios of chloroplatinic acid (H2PtCl66H2O), palladium chloride, copper acetate (monohydrate) (all these materials are commercially available), tungsten oxide, the above materials, and water are shown in Table 3:
(3) Test conditions of the catalyst:
Test Condition 1:0.1 g of product 9-11 was homogeneously mixed with 0.9 g of quartz sand and placed in a tubular reactor. Before the test, the sample was activated for 30 min at 250° C. in a 5% H2 atmosphere. The total flow rate of the raw reaction gas was 500 mL/min; nitrogen was the balance gas; the methane content was 2% and the oxygen content was 0.5%. The heating rate was controlled at 10° C./min, and the reaction temperature was raised from 250° C. to 450° C. The products concentration of methane partial oxidation was monitored.
Test Condition 2:0.1 g of product 9-11 was homogeneously mixed with 0.9 g of quartz sand and placed in a tubular reactor (internal diameter of about 4 mm). The sample was activated for 30 min at 250° C. in a 5% H2 atmosphere. The total flow rate of the feed gas was 210 mL/min, consisting of 200 mL/min of methane/nitrogen mixture with a methane content of 20% pre-mixed with 10 mL/min of pure oxygen. The temperature of the feed gas was maintained for 30 min at 250, 300, 350 and 400° C. while flowing the raw reaction gas. The conversion rate of full methane oxidation reaction and amount of H2O and CO2 production were monitored.
(4) Comparison of catalytic performance
The catalytic oxidation of methane on the surface of the prepared catalyst was investigated. First, the methane molecules are adsorbed onto the active sites of the precious metal; then the electron and proton are transferred to the tungsten oxide carrier (WO3) to form HWO3 bronze; finally, the gas phase oxygen oxidizes HWO3 bronze to produce WO3 and water, and the methane can be partially oxidized and converted to methanol. By continuing to increase the amount of oxygen supply, methanol can be further oxidized, which is the complete oxidation of methane to generate CO2 and water.
The conversion efficiency of methane partial oxidation was tested under test condition 1, and the catalytic performance of partial oxidation of methane can be quantitatively evaluated by comparing product 9, 10 and 11. Product 9-10 can catalyze partial oxidation of methane at 250° C. to efficiently convert methane to methanol and water, and maintain high methanol yield at low temperature (250° C. to 400° C.), showing excellent low temperature catalytic performance, while the product 10 exhibits only a limited catalytic activity at 300° C. or higher. When the temperature rose to above 400° C., the main oxidation reaction of methane occurred on the product 9, 10 and 11 is full oxidation, which forms CO2 and water as the products.
The conversion efficiencies of complete oxidation of methane were measured under test conditions 2 for product 9, 10 and 11, and the difference between CO2 and water production was compared to quantify their efficiency difference. Product 9 can be highly efficiently catalytize oxidation reaction at 250° C., all of the methane gases were completely oxidized to CO2 and water. The product 10 only showed some complete oxidation catalytic activity at temperatures above 350° C., and all methane can be completely oxidized at temperatures up to 400° C., while product 11 did not show catalytic activity over the entire test temperature range, without CO2 and water formation.
The oxidation conversion of methane at different temperatures was directly compared for the catalytic efficiency of products 9, 10 and 11. Product 9 can achieve 14% conversion rate at 250° C., i.e. more than 70% of methane is effectively converted, and the conversion rate did not change significantly with the increase of reaction temperature. Product 10 did not undergo significant catalytic oxidation of methane below 350° C. until the temperature rose to 400° C. to achieve a similar conversion to product 9. Product 11 did not show an effective catalytic oxidation activity in the temperature range of 250-400° C. It can be seen that using tungsten oxide as the support, an active metal components can be rationally chosen to prepare effective methane oxidation catalyst, and it can be also used for solid oxide fuel cell.
While specific embodiments of the present invention have been described in detail above, they are provided by way of example only and are not intended to limit the invention to the specific embodiments described above. It will be apparent to those skilled in the art that any equivalents and alternatives to the present invention are within the scope of the present invention. Accordingly, equivalents and modifications may be made without departing from the spirit and scope of the invention, which is intended to be within the scope of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201410356583.1 | Jul 2014 | CN | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/CN2015/084998 | 7/24/2015 | WO | 00 |
