Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof

Abstract

The invention discloses a vanadium oxide thin film for a micro-metering bolometer and a preparation method thereof. The preparation method comprises the following steps of: (1) cleaning a substrate, and then blow-drying the substrate for later use; (2) putting a prepared original or functionalized carbon nanotube into a beaker to mix with an organic solvent, performing ultrasonic dispersion, and then transferring dispersion liquid to the surface of the cleaned substrate to volatilize the solvent and form crisscross and interconnected carbon nanotube films; (3) putting the substrate diffused with the carbon nanotube films and obtained in the step (2) in to a vacuumized reactor, growing a layer of vanadium oxide film by using the reactor, and performing annealing to form a vanadium oxide-carbon nanotube composite film structure, wherein the grown vanadium oxide film is diffused on the surface of the carbon nano-tube and in gaps between tubes; (4) cooling the vanadium oxide-carbon nanotube composite film structure to the room temperature, and taking the vanadium oxide-carbon nanotube composite film structure out of the reactor; and (5) repeating the steps of carbon nanotube diffusion, vanadium oxide sedimentation and annealing in turn as required to form a vanadium oxide-carbon nanotube multi-layer composite film structure.

Description

technical field [0001] The invention relates to the technical fields of uncooled infrared detection and uncooled terahertz detection, in particular to a thermistor material and light-absorbing material of a microbolometer, and a preparation method thereof. Background technique [0002] Infrared detectors convert invisible infrared heat radiation into detectable electrical signals to realize the observation of external affairs. Infrared detectors are divided into two categories: quantum detectors and thermal detectors. Thermal detectors, also known as uncooled infrared detectors, can work at room temperature, have the advantages of good stability, high integration, and low price, and have broad application prospects in military, commercial, and civilian fields. Uncooled infrared detectors mainly include three types: pyroelectric, thermocouple, and thermistor. Among them, the microbolometer focal plane detector based on thermistor is a kind of uncooled infrared detector that ...

AI Technical Summary

Problems solved by technology

However, since the electronic structure of the vanadium atom is 3d 3 4s 2 , the 4s and 3d orbitals can lose part or all of their electrons. Therefore, the traditional methods of preparing vanadium oxide films, such as magnetron sputtering, electron beam evaporation, and laser ablation deposition, have their own insurmountable shortcomings: That is, the valence state of the V element in the prepared vanadium oxide film is complex, and the stability of the chemical structure of the film is poor.

Due to the complex composition of the V element, small changes in the preparation process will have a greater impact on the chemical composition of the vanadium oxide film, resulting in significant changes in the electrical and optical properties of the film, which in turn affect the performance of the device.

Therefore, one of the main disadvantages of the microbolometer based on vanadium oxide film is that the preparation process of vanadium oxide film is difficult, and the repeatability and stability of the product are poor.

The disadvantage of co-sputtering metal doping is that the sputtering rate of metal impurities and vanadium oxide is difficult to keep consistent, so the ratio of vanadium oxide to metal impurities in

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