A (y 1 - x ln x ) 2 (moo 4 ) 3 Direct method for the preparation of thin films

Abstract

The invention discloses a (Y 1‑x ln x ) 2 (MoO 4 ) 3 A direct method for the preparation of thin films. Set Y(NO 3 ) 3 ·6H 2 O or Y (NO 3 ) 3 ·6H 2 O and Ln(NO 3 ) 3 ·6H 2 O was dissolved in deionized water to prepare a solution with a total concentration of rare earth ions of 0.005~1mol / L, and EDTA or citric acid, NaOH solution, Na 2 MoO 4 2H 2 O, KCl and HNO 3 After mixing evenly, the electrodeposition solution is obtained, placed in a water bath, and the temperature reaches the required temperature; a three-electrode system is inserted in the electrodeposition solution, and a thin film is deposited on the conductive glass through the electrodeposition reaction, and the thin film is separately used Rinse with deionized water and absolute ethanol, then place in a blast drying oven to dry, and then place the dried electrodeposited film in a tube furnace for heat treatment to obtain (Y 1‑x ln x ) 2 (MoO 4 ) 3 film. The invention is simple to operate, compared with the traditional method of making powder first and then forming a film, it greatly simplifies the film preparation method, and at the same time avoids the influence of powder morphology on the quality of film formation; and the method provided by the invention is simple to operate and time-consuming Short, good film quality.

Description

Technical field [0001] The present invention belongs to the technical field of materials science, and specifically relates to a (Y 1-x Ln x ) 2 (MoO 4 ) 3 Direct method of film preparation. Background technique [0002] Rare earth luminescent materials of the molybdate system are used as fluorescent materials in solid-state lighting, flat panel displays, lasers and other fields because of their good chemical stability and high fluorescence quantum efficiency. The preparation of fluorescent materials into corresponding thin films is An important prerequisite for the deviceization of luminescent materials. At present, there are many methods to prepare rare earth molybdate materials with different morphologies, such as sol-gel method, hydrothermal method, solid phase method, microwave method, etc. The principle of the sol-gel method is that alkoxides or ester compounds are dissolved in an organic solvent and undergo a hydrolysis reaction to form active monomers. The monomers are th...

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Problems solved by technology

The principle of the sol-gel method is that an alkoxide or an ester compound is dissolved in an organic solvent, and undergoes a hydrolysis reaction to form an active monomer. The monomer is then polymerized to form a sol, and the sol is polymerized to form a gel with a certain spatial structure, and then dried. And heat treatment to remove the organic matter, sintering and solidification to form the required nanomaterials. The nanomaterials of the molybdate system prepared by this method are mostly nanorods with uneven surfaces, and are prone to agglomeration. Materials with this shape are not suitable for making Film formation; the hydrothermal method is to create a high temperature and high pressure environment to dissolve the insoluble or insoluble substances under atmospheric conditions, or to react to form the dissolved products of the substances, and to convect the reactants by controlling the temperature difference of the solution in the autoclave. A supersaturated state is formed to precipitate growth crystals. The nanomaterials of the molybdate system prepared by this method are mostly in the shape of flowers, and each flower is composed of multiple nanosheets, and these nanosheets are stable enough and not easy to disperse. The similar morphology is also not suitable for making thin films; solid-phase method generally refers to a method that uses solid-phase substances to participate and produce powders through phase changes. The powders prepared by this method are not fine enough and not uniform, so It is also impossible to obtain the ideal morphology for preparing high-quality thin films; microwave synthesis is widely used in nano During the synthesis process of the material, the morphology of the product prepared by the microwave method is prone to agglomeration, so the obtained product is still not ideal for the preparation of high-quality thin films

[0003] In summary, the synthesis conditions of the above methods are relatively high, which is reflected in the high synthesis temperature and high requirements on the reaction vessel; except for the microwave method, the synthesis process of other methods takes a long time; the most important thing is to use the above The morphology of the nanomaterials obtained by the method is not suitable for the preparation of high-quality light-emitting films, which greatly limits its application

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