JP2010277823A - Visible light responsive composition, and photoelectrode and photocatalyst as well as optical sensor using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a novel visible light responsive composition exhibiting high photocurrent response to visible light irradiation, and capable of being employed for forming a photocatalyst and an optical sensor. <P>SOLUTION: The visible light responsive composition is composed with Fe, Ti, M and oxygen, M is an element selected from a group consisting of Si, Ba and Y, an element content ratio (molar ratio) is in a range with Fe of 87 to 90%, Ti of 9 to 10% and M of 0.1 to 3% when a total of Fe, Ti and M is 100%. A photoelectrode, an optical sensor or a photocatalyst are composed by employing the above visible light responsive composition. Also, a water electrolysis method by the optical sensor or the photocatalyst is provided. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a visible light responsive composition and a photoelectrode / photocatalyst / photosensor using the composition.

In recent years, a photoelectrode for using solar energy, a photocatalyst that decomposes and removes environmental pollutants by sunlight, hydrogen production by water decomposition reaction using both, and a photoelectric conversion element type for quantitatively measuring light Optical sensors are attracting attention, and various semiconductors are being researched and developed as their materials. Titanium oxide is a typical example and is most frequently used in practice.
However, since this titanium oxide has a large band gap, the visible light region that occupies most of the sunlight has no absorbability, and sunlight cannot be used effectively. Titanium oxide does not function in indoor light or in-car light of an automobile where the absorbing ultraviolet light region is extremely weak.
As a countermeasure for this, in order to develop a newly usable visible light responsive composition, improvement research such as doping a small amount of other elements into an existing composition such as titanium oxide or a completely new visible light responsiveness Studies for searching for compositions have been conducted (for example, Non-Patent Documents 1 and 2).
However, since the number of combinations of compositions containing various elements in different proportions is enormous, it takes a lot of time and labor to synthesize a new composition and evaluate its visible light response. R & D has not made much progress so far.
Therefore, the present inventors newly developed a thin film automatic synthesis apparatus for compositions containing various kinds of elements in various ratios, and an automatic evaluation apparatus for photocurrent response to light irradiation of the thin film, and visible light responsiveness. Research has been conducted on a high-speed search for a novel composition that is promising as a photoelectrode, photocatalyst, and photosensor material (Patent Document 1). In the process, the present inventors paid attention to the composition of the Fe—Zr—Ti system, and proceeded with research and development. Fe was 20% to 80%, Zr was 20% to 50%, and Ti was 0% to 30%. The visible light responsive complex oxide in the range was found (Patent Document 2). However, research and development have not progressed much for compositions other than Fe-Zr-Ti.

JP 2006-300812 A JP 2009-73708 A

"Photocatalyst Standard Research Method", Tokyo Books, January 2005 Chemistry of Materials, Vol. 20, No. 12, 3803-3805 (2008)

  Against the background as described above, the present invention further deepens and develops the investigations made so far by the inventors and has photocurrent responsiveness to visible light irradiation, and is a photoelectrode material / photocatalyst material / photosensor. It is an object of the present invention to provide a novel composition that can be used as a material, a new photoelectrode / photocatalyst / photosensor constituted by the composition, and a new water decomposition method using the photoelectrode / photocatalyst.

  The present inventors diligently studied to solve the above-mentioned problems, and as a result of exploring and researching a novel visible light responsive composition using the apparatus described in Patent Document 1 described above, the present inventors have also performed visible light irradiation. The inventors have found a novel composition that exhibits photocurrent response and can be used as materials for photoelectrodes, photocatalysts, and photosensors, and have completed the present invention. It has been found to be very effective at a specific ratio of three or more elements other than oxygen, and is a special composition that was hardly found by manual search.

That is, the present invention is characterized by the following.
(1) Visible light responsive composition comprising Fe, Ti, M and oxygen, wherein M is one element selected from the group consisting of Si, Ba and Y, and the total of Fe, Ti and M Elemental content ratio (molar ratio) when Fe is 100%, Fe: 87 to 90%, Ti: 9 to 10%, M: 0.1 to 3% Sex composition.
(2) The element M is Si, and the element content ratio when the total of Fe, Ti, and Si is 100% is Fe: 88 to 90%, Ti: 9 to 10%, Si: 0.1 Visible light responsive composition in the range of 2%.
(3) When the element M is Ba and the total content of Fe, Ti, and Ba is 100%, the element content ratio is Fe: 87 to 90%, Ti: 9 to 10%, Ba: 0.1 to 0.1 Visible light responsive composition in the range of 3%.
(4) The element content ratio when the element M is Y and the total of Fe, Ti, and Y is 100% is Fe: 88 to 90%, Ti: 9 to 10%, Y: 0.3 to Visible light responsive composition in the range of 2%.
(5) A photoelectrode comprising any one of the above visible light responsive compositions.
(6) A photocatalyst configured with any of the above visible light responsive compositions.
(7) An optical sensor comprising any one of the above visible light responsive compositions.
(8) The water splitting method using the photoelectrode according to (5) and / or the photocatalyst according to (6).

  The photocurrent indicates the performance when used as a photoelectrode material, and indicates the degree of charge separation for the photocatalyst to function. Since the composition of the present invention generates a photocurrent by generating charge separation by irradiation with visible light, it can be used as a material for a visible light responsive photoelectrode or a visible light responsive photocatalyst. These can be used to reduce water to generate hydrogen and convert light energy to hydrogen. In addition, as an optical sensor having only a specific wavelength region, a material for an optical sensor having spectral sensitivity only in the visible light region can be provided.

  The visible light responsive composition of the present invention contains four elements of Fe, Ti, M, and oxygen as essential elements. Here, the element M refers to one element selected from the group consisting of Si, Ba and Y, and the element content ratio (molar ratio) when the total of Fe, Ti and M is 100% is Fe: 87. It is in the range of -90%, Ti: 9-10%, M: 0.1-3%. The visible light responsive composition of the present invention basically comprises the above four elements, but does not intend to exclude the inclusion of other elements as long as the visible light responsiveness is not significantly reduced. Even when other elements are contained, other elements are excluded from the content ratio and are not added to the total.

  When the composition is Fe, Ti, Si, and oxygen, the content ratio (molar ratio) of each of the three elements other than oxygen is 100% in total, Fe is 88 to 90%, Ti is 9 to 10%, Si is It is characterized by being in the range of 0.1 to 2%. Even when other elements are contained, other elements are excluded from the content ratio and are not added to the total.

  When the composition is Fe, Ti, Ba, and oxygen, the content ratio (molar ratio) of each of the three elements other than oxygen is 100% in total, Fe is 87 to 90%, Ti is 9 to 10%, and Ba is It is characterized by being in the range of 0.1 to 3%. Even when other elements are contained, other elements are excluded from the content ratio and are not added to the total.

  When the composition is Fe, Ti, Y, and oxygen, the content ratio (molar ratio) of each of the three elements other than oxygen is 100% in total, Fe is 88 to 90%, Ti is 9 to 10%, and Y is It is characterized by being in the range of 0.3 to 2%. Even when other elements are contained, other elements are excluded from the content ratio and are not added to the total.

  When a photoelectrode is constituted using the composition of the present invention, charge separation occurs due to visible light irradiation and a large photocurrent is generated within the range of the above-described element content ratio (molar ratio).

  The composition of the present invention can be produced by various methods such as a thermal decomposition method, a mixed powder sintering method, an electrodeposition method, a vapor deposition method such as sputtering, and the like. It is preferable to prepare by the method. For example, in the case of producing a thin film (coating pyrolysis method), details will be described in Examples. In this pyrolysis method, a solution containing each element (in some cases, a colloidal solution, a suspension, etc.) is mixed well to prepare a raw material solution, which is fired to produce a composition. In the thermal decomposition method, the element content ratio (molar ratio) can be accurately controlled, and a uniform composition can be prepared by mixing with a solution. In the case of a thin film shape (coating pyrolysis method), coating and baking are repeated. There is an advantage that a precise one can be produced by laminating the layers. The thermal decomposition method used in the present invention may be any method in which a liquid containing each element is mixed and fired, and examples thereof include a sol-gel method, a complex polymerization method, and an organometallic decomposition method. In order to control the porosity and solution viscosity of the thin film, a polymer or an organic substance such as polyethylene glycol or ethyl cellulose may be added to the solution.

The composition of the present invention may be a complex oxide having a uniform composition or a doping compound. A plurality of compounds may exist in a mixed state.
If the composition is synthesized by firing in oxygen or air, the oxide having the most stable composition is usually obtained, but a composition other than the oxide may be synthesized by controlling the atmospheric gas. For example, a composition containing a part of N, S, and C can be synthesized by synthesizing while flowing NH ₃ , H ₂ S, and CH ₄ gas.
When used as a photoelectrode or photosensor, the composition of the present invention is fixed on a conductive substrate. For example, a solution containing each element is applied onto a heat-resistant conductive substrate such as conductive glass or metal, and a film is formed by a thermal decomposition method.

  When the composition is used as a photoelectrode, it is desirable that the composition is strongly bonded to the substrate and is porous. When used as a photocatalyst, it is desirable that the surface area is relatively high and the crystallinity is high.

  And according to this invention, the photoelectrode, photocatalyst, and photosensor using said composition are provided.

  Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the examples.

(Examples 1-17, Comparative Examples 1-43)
A ternary thin film library of Fe—Ti—Si, Fe—Ti—Ba, and Fe—Ti—Y was synthesized by a coating pyrolysis method using an automatic composition thin film synthesis apparatus (Patent Document 1). This thin film library is prepared by forming thin films of compositions having different content ratios of elements on a single conductive glass substrate at intervals. The content of each ternary element was changed as shown in Tables 1-3.

As a raw material solution to be applied, an organic complex solution of Fe, Ti, Si, Ba, and Y manufactured by Symmetrics is diluted with butyl acetate so that the molar concentration is 0.2 M, and the volume ratio thereof is changed and mixed. Thus, the molar ratio of each content was adjusted. These solutions were mixed with a 10% by weight ethyl cellulose butyl acetate solution as a thickening agent in a volume ratio of 3 times. In addition, about the ternary system of Fe-Ti-Y, it replaced with the said butyl acetate and used the liquid mixture of butyl acetate and xylene as a diluent.
Each solution was applied to a predetermined position on a conductive glass substrate and fired four times to synthesize a laminated film. Firing was performed in air at 550 ° C. for 0.5 hour and at 700 ° C. for another 0.5 hour. These were made into (Examples 1-17, Comparative Examples 1-43).

Visible light responsiveness of the composition was evaluated by measuring photocurrent. The photocurrent is a scale indicating the charge separation ability and visible light reactivity of the composition, and the larger the performance, the higher the performance. A 300 W Xe lamp equipped with a filter that cuts a wavelength shorter than 420 nm is placed in a 0.1 M sodium dihydrogen phosphate solution adjusted to pH 7.0 with sodium hydroxide. The photocurrent was measured at 1 V (vs. Ag / AgCl) while irradiating at 3.2 mW through a 1 mm diameter hole slit. Platinum is used for the counter electrode, on which hydrogen corresponding to the current value is generated. In Examples and Comparative Examples in which the M component is the same, since the thin film library is synthesized on the same conductive glass substrate, the photocurrent values can be compared with each other. Since the thin film library does not exist on the same conductive glass substrate and the photocurrent measurement is performed for each thin film library, the background is not the same and the photocurrent values cannot be directly compared with each other. Tables 1 to 3 show the measurement results of the photocurrent.
As for titanium oxide, a photocurrent was measured by synthesizing a thin film library in the same manner as in the example of the present invention, but almost no photocurrent was generated (0 μA).

  As is clear from Tables 1 to 3, a predetermined photocurrent value is shown by selecting Fe, Ti and one of Si, Ba, and Y as the third component. In all of the examples, Visible light response far superior to that of titanium oxide.

  As the third component, Si, Ba, and Y included in M of the present invention are selected, and the composition is Fe: 87 to 90%, Ti: 9 to 10%, and M: 0.1 to 3%. In the case, the photocurrent value was significantly larger than that of the comparative example. As described above, the photocurrent values of Examples and Comparative Examples having different M components cannot be directly compared with each other, but compositions of Fe: 98.0% and Ti: 2.0% (Comparative Example 1, Comparative Example) 17 and Comparative Example 32) as a reference, it was found that the visible light responsiveness was compared among the three third components in the order of Y <Ba <Si.

  When the photoelectrode is constituted by the composition of the present invention, the absorption and utilization of visible light is promoted, and more efficient use of sunlight by the photoelectrode such as hydrogen production by water decomposition becomes possible. Further, even in a place where ultraviolet light is weak such as in a building or in a car, the photocatalyst constituted by the composition of the present invention can be used to remove or deodorize environmental pollutants using indoor light or in-car light. Furthermore, a material for an optical sensor that reacts only to light in the visible light range can be provided.

Claims (8)

  A visible light responsive composition comprising Fe, Ti, M and oxygen, wherein M is one element selected from the group consisting of Si, Ba and Y, and the total of Fe, Ti and M is 100% The elemental content ratio (molar ratio) is within the range of Fe: 87 to 90%, Ti: 9 to 10%, and M: 0.1 to 3%. .   The element M is Si, and the content ratio (molar ratio) when the total of Fe, Ti, and Si is 100% is Fe: 88 to 90%, Ti: 9 to 10%, Si: 0.1 The visible light responsive composition according to claim 1, which is in a range of ˜2%.   The element M is Ba, and the element content ratio (molar ratio) when the total of Fe, Ti, and Ba is 100% is Fe: 87 to 90%, Ti: 9 to 10%, Ba: 0.1 The visible light responsive composition according to claim 1, which is in a range of ˜3%.   The element content ratio (molar ratio) when the element M is Y and the total of Fe, Ti, and Y is 100% is Fe: 88 to 90%, Ti: 9 to 10%, Y: 0.3 The visible light responsive composition according to claim 1, which is in a range of ˜2%.   A photoelectrode comprising the visible light responsive composition according to claim 1.   A photocatalyst comprising the visible light responsive composition according to any one of claims 1 to 4.   An optical sensor comprising the visible light responsive composition according to claim 1.   A water splitting method using the photoelectrode according to claim 5 and / or the photocatalyst according to claim 6.