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Method for acquiring large-area high-quality flexible self-supporting single crystalline oxide film based on Van der Waals epitaxy

A technology of oxide thin film and single crystal oxide, which is applied in the field of microelectronics, can solve the problems of increasing the time and high cost of thin film preparation and transfer, and achieve the effects of improving thin film preparation efficiency, preventing cracking, and simplifying preparation technology

Active Publication Date: 2018-09-11
XIDIAN UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

The ion exchange method is to use the chemical replacement reaction between the ion exchanger and the liquid electrolyte to separate, the choice of material is limited by the type of exchanger, and the cost is high; the chemical corrosion method is to use acid or alkali solution to corrode The sacrificial layer in the middle is used for separation. This method needs to grow the sacrificial layer first, which increases the time for film preparation and transfer.

Method used

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  • Method for acquiring large-area high-quality flexible self-supporting single crystalline oxide film based on Van der Waals epitaxy

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0025] Example 1: Preparation of a large-area, high-quality, flexible and self-supporting cobalt ferrite film.

[0026] Step 1: growing a cobalt ferrite thin film on a mica substrate.

[0027] 1a) Put the mica substrate and cobalt ferrite target into the reaction chamber of the pulsed laser deposition system, and evacuate the reaction chamber until the vacuum degree reaches 1*10 -6 Below mbar, then feed oxygen into the reaction chamber to keep the oxygen pressure in the reaction chamber at 0.01mbar;

[0028] 1b) Turn on the laser switch and set the energy density of the laser to 2.4J / cm 2 , the frequency is 5Hz, the temperature of the substrate is set to 600°C, and the cobalt ferrite target is burned 2000 times by the laser beam, so that the burnt cobalt ferrite plasma is deposited on the substrate, and the growth of the cobalt ferrite film is completed. .

[0029] Step 2: forming a cobalt ferrite film with PMMA attached.

[0030] 2a) Spin-coat a layer of polymethyl methac...

Embodiment 2

[0037] Example 2: Preparation of a large-area, high-quality, flexible and self-supporting strontium titanate film.

[0038] Step 1: growing a strontium titanate thin film on a mica substrate.

[0039] 1.1) Put the mica substrate and strontium titanate target into the reaction chamber of the pulsed laser deposition system, and evacuate the reaction chamber until the vacuum degree reaches 1*10 -6 Below mbar, then feed oxygen into the reaction chamber to keep the oxygen pressure in the reaction chamber at 0.01mbar;

[0040] 1.2) Turn on the laser switch and set the energy density of the laser to 3J / cm 2 , the frequency is 5Hz, the temperature of the substrate is set to 800°C, the laser beam is used to burn the strontium titanate target 1000 times, so that the burnt strontium titanate plasma is deposited on the substrate, and the growth of the strontium titanate film is completed .

[0041] Step 2: forming a strontium titanate thin film attached with polymethyl methacrylate PMM...

Embodiment 3

[0049] Example 3: Preparation of a large-area, high-quality, flexible and self-supporting strontium niobate-doped titanate thin film.

[0050] Step A: growing a strontium niobate titanate thin film on a mica substrate.

[0051] A1) Put the mica substrate and strontium niobate-doped titanate target into the reaction chamber of the pulsed laser deposition system, and evacuate the reaction chamber until the vacuum degree reaches 1*10 -6 Below mbar, then feed oxygen into the reaction chamber to keep the oxygen pressure in the reaction chamber at 0.01mbar;

[0052] A2) Turn on the laser switch and set the energy density of the laser to 2.8J / cm 2 , the frequency is 5Hz, the temperature of the substrate is set at 750°C, and the laser beam is used to burn the strontium niobium titanate target material for 3000 times, so that the burned strontium niobium titanate plasma is deposited on the substrate, and the niobium doping is completed. Growth of strontium titanate thin films.

[00...

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Abstract

The invention discloses a method for acquiring a large-area high-quality flexible self-supporting single crystalline oxide film based on Van der Waals epitaxy, and mainly solves a problem in the priorart that a process for preparing the oxide film is complicated. The method comprises the following steps: 1, growing the oxide film on a mica substrate through a pulsed laser deposition technology; 2, spin-coating the surface of the oxide film by polymethyl methacrylate, and soaking in weakly acidic solution, while corners of the film are upwarping, taking out the film and placing in clear water,enabling the film to break away from the mica substrate by using a tension force of the water, and transferring to a follow-up needed substrate, to obtain the large-area high-quality flexible self-supporting single crystalline oxide film. The method is capable of, through using the mica substrate and the weakly acidic solution, acquiring the large-area high-quality flexible self-supporting singlecrystalline oxide film based on the Van der Waals epitaxy, greatly shortening the film preparation time, and preparing the multi-functional oxide film for a flexible electronic device.

Description

technical field [0001] The invention belongs to the technical field of microelectronics, and in particular relates to a method for obtaining large-area, high-quality, flexible self-supporting single-crystal oxide films, which can be used for the preparation of various functional oxide films. Background technique [0002] Flexible electronic devices are an emerging electronic technology that manufactures electronic devices on flexible, extensible organic or thin metal substrates. It has broad application prospects, such as flexible displays, flexible wearable devices, epidermal electronics, and flexible solar cells. Flexible electronic devices are mainly composed of metal or semiconductor films and flexible substrates. The two most critical points in the preparation of flexible electronic devices are how to prepare flexible semiconductor films with excellent performance, good ductility, and stable structure, and how to transfer the films to subsequent flexible substrates. ...

Claims

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Application Information

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IPC IPC(8): C30B23/08C30B29/16C30B29/64
CPCC30B23/025C30B23/08C30B29/16C30B29/64
Inventor 陆小力王涛吴飞虎王贺黄玉瑶张进成郝跃
Owner XIDIAN UNIV
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