CN101886261B - Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof - Google Patents
Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof Download PDFInfo
- Publication number
- CN101886261B CN101886261B CN 201010222514 CN201010222514A CN101886261B CN 101886261 B CN101886261 B CN 101886261B CN 201010222514 CN201010222514 CN 201010222514 CN 201010222514 A CN201010222514 A CN 201010222514A CN 101886261 B CN101886261 B CN 101886261B
- Authority
- CN
- China
- Prior art keywords
- vanadium oxide
- carbon nanotube
- film
- micro
- substrate
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Fee Related
Links
Images
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
The present invention relates to Uncooled infrared detection, and non-refrigeration terahertz detection technical field, be specifically related to a kind of thermistor material of micro-metering bolometer and light absorbing material, with and preparation method thereof.
Background technology
Infrared eye is converted into detectable electrical signal to sightless infrared emanation, realizes the to external world observation of affairs.Infrared eye is divided into quantum detector and thermo detector two classes.Thermo detector claims again the non-refrigeration type infrared eye, can at room temperature work, and has the advantages such as the high and price of good stability, integrated level is low, has wide practical use in the field such as military, commercial and civilian.Non-refrigerated infrared detector mainly comprises the three types such as pyroelectricity, thermopair, thermistor, wherein, microbolometer FPA detector based on thermistor, that the very swift and violent a kind of non-refrigerated infrared detector of developed recently is (referring to LeonardP.Chen, " Advanced FPAs for Multiple Applications " Proc.SPIE, 4721,1-15 (2002) document).Terahertz detector is that the electromagenetic wave radiation of the longer terahertz wave band of wavelength is converted into detectable electrical signal, realizes the to external world observation of affairs.Terahertz also has the detector of Multiple Type, and wherein, non-refrigeration Terahertz micro-metering bolometer has and the similar structure of Uncooled Infrared Microbolometer, can obtain by the improvement to the latter.Infrared or the terahertz emission detection process of micro-metering bolometer is mainly finished by the micro-bridge structure that suspends, so the suspension microbridge is to affect the key factor that device is made success or failure and performance height.Micro-metering bolometer has special requirement to constructing the thermistor material of the thin-film material of its suspension microbridge, especially core, is embodied in: associated materials should have suitable electricity, optics, reach mechanical property etc.
There is multiple material can be used as the thermistor material of infrared eye or terahertz detector micro-metering bolometer.Wherein, vanadium oxide film has very good electrical and optical properties, and the integrated level of material preparation is high, is the most frequently used high-performance non-refrigerated infrared detector or the thermistor material of non-refrigeration terahertz detector.The US Patent No. P 5286976 that the people such as Barrett E.Cole of the Honeywll company that on February 15th, 1994 authorized declare, and document H.Jerominek, F.Picard, et al., " Micromachined, uncooled, VO
2-based, IR bolometer arrays ", Proc.SPIE, 2746,60-71 (1996) has described respectively the infrared detector structure based on vanadium oxide thermistor film.Yet, because the electronic structure of vanadium atom is 3d
34s
24s wherein and 3d track all can lose part or all of electronics, so, the preparation method of traditional vanadium oxide film, such as magnetron sputtering, electron beam evaporation, laser ablation deposition etc. contained the shortcoming that itself can't overcome: i.e. the poor stability of complicated, the film chemical structure of the valence state of V element etc. in the prepared vanadium oxide film.For example, when adopting magnetron sputtering to prepare vanadium oxide film, V element wherein generally comprises 0, + 2, + 3, + 4, the multiple valence states such as+5 are (referring to Xiaomei Wang, Xiangdong Xu, et al., " Controlling the growth of VOx films for variousoptoelectronic applications ", Proceedings of the 2009 16th IEEE InternationalSymposium on the Physical and Failure Analysis of Integrated Circuits, IPFA, p572-576 (2009) document).Because the composition of V element is complicated, preparation technology's subtle change all can produce larger impact to the chemical constitution of vanadium oxide film, thereby makes the performance generation considerable changes such as electricity, optics of film, and then has influence on performance of devices.So based on a main drawback of the micro-metering bolometer of vanadium oxide film be: preparation technology's difficulty of vanadium oxide film is large, the repeatability of product and poor stability.
The US Patent No. P5288380 that the people such as David A.Jackson that authorized on February 22nd, 1994 declare, and the US Patent No. P7250604 that on August 4th, 2005, the people such as Sung Mooon that authorize declared, a kind of method of cosputtering has been described respectively, in order to improve the physicals of vanadium oxide film.As sputtering target material, under certain condition, this mixture target of sputter makes it to form gaseous component, then deposits film forming this method the vanadium oxide material that is mixed with in advance some metallic impurity (such as Ni, Fe, Cr, Mn, W etc.); Perhaps, adopt two sputtering sources respectively splash-proofing sputtering metal and two different target sources of vanadium oxide, preparation contains the vanadium oxide (VM of certain metallic impurity
xO
y, M is metallic impurity) and film, with this electric property such as resistance value, temperature coefficient of resistance, transformation temperature of controlling vanadium oxide film, satisfy the needs of infrared eye.The shortcoming of cosputtering doping metals is: the sputter rate of metallic impurity and vanadium oxide is difficult to be consistent, so, vanadium oxide is often not identical with target with the ratio of metallic impurity in the film of the method preparation, and, this ratio also may be along with the fluctuation of sputtering technology acute variation.So the method for cosputtering is difficult to obtain the VM with fixing metering ratio, stable performance
xO
yFilm.In addition, the required facility investment of cosputtering is large, Technology is complicated.
Collosol and gel (Sol-gel) method is another method for preparing vanadium oxide film, document V.N Ovsyuk, et al., " Uncooled microbolometer IR FPA based on sol-gel VO
x", Proc.SPIE, 5834,47-54 (2005) has just described and has utilized sol-gel method for the preparation of the vanadium oxide thermosensitive film of infrared eye.The advantage of sol-gel method is that equipment is simple, and, can obtain the vanadium oxide film that valence state relatively concentrates, the effective control that is conducive to material property.But if there is not the adjusting of other impurity, so, the resistance value of the vanadium oxide film that conventional sol-gel method obtains is larger, and, also have phase transition phenomena under the working temperature, be unfavorable for being applied in the middle of the infrared eye.The Chinese patent 200510020789.8 that the Huang dimension of authorizing on June 13rd, 2007 has just waited the people to declare, described a kind of method that adopts inorganic sol-gel to vanadium oxide carry out metal-doped, to improve the performance of relevant vanadium oxide film.The method is at first V
2O
5With MoO
3Mix mutually, be heated under the normal pressure about 900 ℃, form melts; Then, melts is poured into water fast, adds oxalic acid, NH
4F forms inorganic sol.At last, 350-500 ℃ of lower anneal, the vanadium oxide material that obtains being mixed with Mo or W element and comprise the F element.The shortcoming of this inorganic sol-gel method is: the excess Temperature of (1) colloidal sol preparation, and it is integrated to affect device; (2) comprise a large amount of nonmetal F impurity in the product, affect material property; The absorptivity of the vanadium oxide that (3) obtains is lower, is unfavorable for the absorbing detection of infrared light.These deficiencies make inorganic sol-gel method be difficult to directly be applied in the middle of the manufacturing of infrared eye or terahertz detector vanadium oxide thermosensitive film.
The US Patent No. P6489613 that the people such as the Toru Mori of NEC Corporation that authorized on December 3rd, 2002 declare has then described another and has improved the sol-gel method that infrared acquisition is used the vanadium oxide film performance.This invention utilizes the organosol gel technique, adopts vanadium alkoxide (VO (OR)
3) as reaction raw materials, under collosol state, in vanadium oxide, mix the metallic impurity such as a certain amount of Cr, Al, Fe, Mn, Nb, Ta, Ti, through anneal, form metal-doped vanadium oxide film, make the electric properties such as resistance value, temperature coefficient of resistance (TCR) of vanadium oxide meet the requirement of infrared eye by the control of doping metals amount.Adopt the organosol gel method, can obtain the vanadium oxide film that valence state is relatively concentrated, the parameters such as resistance value, transformation temperature, TCR that are conducive to film control effectively, and make it to satisfy the requirement of infrared eye.Importantly, the temperature of reaction of organosol gel method lower (<200 ℃) is conducive to reduce to the integrated negative impact of device.Regrettably, conventional organosol gel method contains some shortcomings identical with inorganic sol-gel method, comprise: (1) organic or inorganic sol-gel method carries out when metal-doped, the poor stability of metallic impurity in vanadium oxide film, the phenomenons such as diffusion of contaminants, segregation occur easily, the performance generation regression, the Quality Down that cause vanadium oxide film are difficult to satisfy the long-time running needs of device; (2) organic or inorganic sol-gel method carries out the absorbing properties that metal-doped method can't improve vanadium oxide film effectively.
On the other hand, carbon nanotube is a kind of very important monodimension nanometer material.From 1991, the Iijima of Japan has found since the carbon nanotube (referring to Sumio Iijima, " Helical microtubules of graphiticcarbon ", Nature, 354,56, (1991) document), studies show that more and more this special monodimension nanometer material has physics and the chemical property of many uniquenesses, has broad application prospects in a lot of fields.At first, carbon nanotube has very good chemical stability, in vacuum condition, carbon nanotube is under 1200 ℃ high temperature, it is stable that its chemical structure can also keep, and in atmospheric environment, carbon nanotube also is being chemically stable below 650 ℃, obviously, the chemical stability of carbon nanotube is higher than vanadium oxide film far away.In addition, carbon nanotube also has good electricity, optics, and the performance such as mechanics, and for example, the temperature coefficient of resistance of bibliographical information carbon nanotube (TCR) can reach 0.3~2.5%/K, and under the specified conditions, its photoabsorption coefficient can reach 10
4~5Cm
-1(referring to M.E.Itkis, F.Borondics, A.Yu.R.C.Haddon, " Bolometric InfraredPhotoresponse of Suspended Single-Walled Carbon Nanotube Films ", Science, 312,413-416 (2006) document).So carbon nanotube is a kind of thermistor material with potential using value, be expected to overcome some shortcomings of traditional vanadium oxide thermosensitive film.
Summary of the invention
Problem to be solved by this invention is: how a kind of vanadium oxide film for micro-metering bolometers such as infrared eye or terahertz detectors and preparation method thereof is provided; this film can improve the serviceability of device; reduced the raw material manufacturing cost, suitable large-scale production.
Technical problem proposed by the invention is to solve like this: a kind of vanadium oxide film for micro-metering bolometer is provided, it is characterized in that, this film is the vanadium oxide-carbon nano-tube compound film that is composited by one dimension carbon nanotube and bidimensional vanadium oxide film, and this vanadium oxide-carbon nano-tube compound film consists of thermistor material and the light absorbing material of micro-metering bolometer.
The first preparation method of above-mentioned vanadium oxide-carbon nano-tube compound film is characterized in that, may further comprise the steps:
1. clean substrate, dry up rear for subsequent use;
2. the original carbon nanotube without functionalization for preparing in advance is placed in the middle of the beaker, mixes ultra-sonic dispersion with organic solvent, then, dispersion liquid is transferred to through the surface of the substrate of clean, made solvent evaporates, form staggered, interconnected carbon nano-tube film;
3. the substrate that is dispersed with carbon nano-tube film that 2. step is obtained is put into the reactor of vacuum pumping, utilize reactor growth one deck vanadium oxide membrane, the vanadium oxide membrane of growing is dispersed in the middle of the gap of the surface of carbon nanotube and tube and tube, annealing forms vanadium oxide-carbon nano-tube compound film structure;
4. after being cooled to room temperature, from reactor, take out;
5. as required, repeat successively carbon nanotube dispersed, vanadium oxide deposition and annealing steps, form vanadium oxide-carbon nanotube multilayer structure of composite membrane.
The second preparation method of above-mentioned vanadium oxide-carbon nano-tube compound film is characterized in that, may further comprise the steps:
1. clean substrate, dry up rear for subsequent use;
2. the carbon nanotube for preparing in advance is placed in the beaker, adopt first chemically treated mode, introduce functional group on the surface of carbon nanotube, through filtration, washing and drying step, obtain the carbon nanotube of functionalization, then, the carbon nanotube of this functionalization is placed in the middle of the beaker, mixes with organic solvent, ultra-sonic dispersion, again dispersion liquid is transferred to through the surface of the substrate of clean, made solvent evaporates, form staggered, interconnected carbon nano-tube film;
3. being dispersed with of 2. obtaining of step put into the reactor of vacuum pumping through the substrate of the carbon nanotube of functionalization, utilize reactor growth one deck vanadium oxide membrane, the vanadium oxide membrane of growing is dispersed in the middle of the gap of the surface of carbon nanotube and tube and tube, annealing forms vanadium oxide-carbon nano-tube compound film structure;
4. after being cooled to room temperature, from reactor, take out;
5. as required, repeat successively carbon nanotube dispersed, vanadium oxide deposition and annealing steps, form vanadium oxide-carbon nanotube multilayer structure of composite membrane.
Preparation method according to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that, step 2. in, be carbon nanotube dispersed a kind of in the middle of spin coating or dip-coating method, spraying method, spread coating, electrodip process, electrophoresis, the printing transplanting etc. to the method for substrate surface, when adopting the method for spin coating, used dispersion liquid is a kind of in the middle of the organic solvents such as ethanol or Virahol, isopropylcarbinol, primary isoamyl alcohol, isohexyl alcohol.
Preparation method according to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that, the carbon nanotube accumbency that step obtains in 2. on the surface of substrate, be staggered interconnect architecture, carbon nanotube is single wall or multi-walled carbon nano-tubes, the diameter of carbon nanotube is 1~50nm, and the length of carbon nanotube is 50~30000nm.
The second preparation method according to the vanadium oxide film for micro-metering bolometer provided by the present invention is characterized in that, its step 2. in, the method for carbon nanotube being carried out functionalization is: adopt dense H
2SO
4With dense HNO
3A kind of in the middle of mixed solution, concentrated nitric acid, potassium permanganate, the processing of Fenton method etc., the surface of carbon nanotube introducing-COOH ,-COH or-CNH
2Functional group.
Preparation method according to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that, step 3. in, the preparation method of vanadium oxide membrane is a kind of in the middle of magnetron sputtering, electron beam evaporation, thermal evaporation, organometallics chemical vapour deposition, laser ablation deposition, the ald etc.; When adopting magnetically controlled sputter method, used target is the oxide compound VO of vanadium metal or vanadium
x, x satisfies 1.0≤x≤2.5, and used reactant gases is that gas mixture and the per-cent of oxygen in gas mixture of argon gas and oxygen is 0.2~20%, and depositing temperature is 25~500 ℃.
A kind of vanadium oxide film for micro-metering bolometer, it is characterized in that, this film is the vanadium oxide-carbon nano-tube compound film that is composited by one dimension carbon nanotube and bidimensional vanadium oxide film, as thermistor material and the light absorbing material of infrared eye or terahertz detector micro-metering bolometer.Of particular note, the exist form of carbon nanotube in composite membrane is linear structure, is referred to as the one dimension carbon nanotube, and vanadium oxide film is membrane structure, is referred to as the bidimensional vanadium oxide film.
According to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that the vanadium oxide that vanadium oxide-carbon nano-tube compound film contains is non-crystalline state or crystalline structure, the molecular formula of vanadium oxide is expressed as VO
x, wherein, x satisfies 1.0≤x≤2.5, and the best is x=1.5,2.0,2.5.
According to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that, described one dimension carbon nanotube dispersed is in the middle of vanadium oxide, be staggered or reticulated structure, carbon nanotube is single wall or multi-walled carbon nano-tubes, the diameter of carbon nanotube is 1~50nm, and the best is 2nm, 5nm, 10nm, 15nm, 20nm, 25nm, 30nm etc.; The length of carbon nanotube is 50~30000nm, and the best is 500nm, 800nm, 1000nm, 1200nm, 1500nm, 2000nm etc.; The weight content of carbon nanotube in composite membrane is 0.1~98wt.%, and the best is 1wt.%, 1.5wt.%, 2wt.%, 2.5wt.%, 3wt.%, 3.5wt.%, 4wt.%, 4.5wt.%, 5wt.%, 5.5wt.%, 6wt.%, 8wt.%, 10wt.% etc.
According to the vanadium oxide film for micro-metering bolometer provided by the present invention, it is characterized in that, the thickness of this composite membrane is 5~1500nm, and the best is 50nm, 100nm, 120nm, 150nm, 200nm, 250nm, 300nm, 350nm, 400nm, 450nm, 500nm etc.; The sheet resistance of composite membrane is 100 Ω/~5M Ω/, and the best is 10k Ω/, 20k Ω/, 50k Ω/, 70k Ω/, 90k Ω/, 100k Ω/, 120k Ω/, 150k Ω/, 170k Ω/, 200k Ω/, 300k Ω/, 400k Ω/, 500k Ω/ etc.; The temperature coefficient of resistance of composite membrane (TCR) is-0.5~-4.5%/K, the best is-1.0%/K ,-1.3%/K ,-1.5%/K ,-1.8%/K ,-1.9%/K ,-2.0%/K ,-2.1%/K ,-2.2%/K ,-2.5%/K etc.
Beneficial effect of the present invention: the present invention considers non-refrigerated infrared detector, and the particular requirement of non-refrigeration terahertz detector, simultaneously for the deficiency of the existing thermistor thin film of vanadium oxide in the device at aspects such as material property and preparation methods, a kind of mutually compound material of one dimension carbon nanotube and bidimensional vanadium oxide that adopts is proposed as infrared eye, or the method for the thermistor material of terahertz detector micro-metering bolometer and light absorbing material, utilize on the one hand the good chemical stability of carbon nanotube, mechanical property and electroconductibility, improve the shortcomings such as the low and poor chemical stability of the electroconductibility of conventional oxidation vanadium thermistor thin film, the negative impact of having avoided simultaneously traditional doping process that vanadium oxide membrane is produced, on the other hand, utilize the high resistance of vanadium oxide, with and the absorptive character such as good temperature coefficient of resistance (TCR) and infrared light, remedy carbon nanotube deficiency in these areas, thereby improve the over-all properties of device.On this basis, by regulating the ratio between vanadium oxide and the carbon nanotube, can also be more prone to, regulate more exactly the device film performance, satisfy the special requirement of infrared eye or terahertz detector.Utilize infrared eye that this matrix material by special monodimension nanometer material and bidimensional film makes or the sensitive material of terahertz detector, improved the serviceability of device, reduced the raw material manufacturing cost, suitable large-scale industrialized production.
Description of drawings
Fig. 1 is the orthographic plan of implementing the vanadium oxide that the present invention proposes-carbon nano-tube compound film structure;
Fig. 2 is the sectional view of the vanadium oxide of implementing the individual layer that the present invention proposes-carbon nano-tube compound film structure;
Fig. 3 is the sectional view of the vanadium oxide of implementing the multilayer that the present invention proposes-carbon nano-tube compound film structure.
Wherein, 1, substrate, 2, vanadium oxide-carbon nano-tube compound film, 210, the carbon nanotube in the middle of vanadium oxide-carbon nano-tube compound film, 220, the vanadium oxide in the middle of vanadium oxide-carbon nano-tube compound film.
Embodiment
The invention will be further described below in conjunction with accompanying drawing:
Guiding theory of the present invention is in vanadium oxide-carbon nano-tube compound film structure, utilize separately good electrical and optical properties of carbon nanotube and vanadium oxide, prepare the good laminated film of comprehensive comparison (as shown in Figure 1), as thermistor material and the light absorbing material of uncooled microbolometer, improve the performance of infrared eye or terahertz detector.Preparation vanadium oxide of the present invention-carbon nano-tube compound film embodiment is as follows: 1. selects silicon wafer as the substrate 1 of film growth, uses first Piranha solution-treated and washed with de-ionized water, then soak with rare hydrofluoric acid solution, and after drying up with nitrogen, for subsequent use; 2. the carbon nanotube of getting ready in advance is placed in the beaker, adopts first chemically treated method, introduce some special functional groups on the surface of carbon nanotube, then, through filtration, washing, drying and other steps.Obtain the carbon nanotube of functionalization, for subsequent use; 3. through step 2. the carbon nanotube crossed of functionalization be placed in the middle of the beaker, mix ultra-sonic dispersion with organic solvent; Then, dispersion liquid is transferred to through the 1. surface of the substrate 1 crossed of clean of step, made solvent evaporates, form staggered, interconnected carbon nano-tube film 210; 4. the substrate 1 that the surface is dispersed with carbon nanotube 210 is put into the reactor of vacuum pumping, with vanadium metal as target, argon gas as sputter gas, oxygen as reactant gases, the method of employing direct current reaction magnetron sputtering, a layer thickness of growing under 200 ℃ are the vanadium oxide membrane 220 of 5~1500nm, vanadium oxide 220 covers in the middle of the gap of the surface of carbon nanotube 210 and tube and tube, annealing forms vanadium oxide-carbon nano-tube compound film 2; 5. after sample is cooled to room temperature, sample is taken out from magnetic control sputtering system; 6. as required, can repeat successively the steps such as carbon nanotube 210 dispersions, vanadium oxide 220 depositions and annealing, form vanadium oxide-carbon nanotube multilayer structure of composite membrane 2.In the middle of vanadium oxide-carbon nano-tube compound film 2, the introducing of carbon nanotube 210, electric property, optical property and the steady chemical structure etc. of vanadium oxide 220 are effectively improved, met the requirement of non-refrigerated infrared detector or non-refrigeration terahertz detector micro-metering bolometer.
The concrete technology of above-mentioned Preparation Example comprises: the preparation of (1) film growth substrate: select 4 inches Si (100) silicon chip as the growth substrates 1 of film, before the experiment, use first the Piranha solution (vitriol oil: hydrogen peroxide=7: 3 (volume ratio)) in 80 ℃ of lower processing 10 minutes, rinse well with deionized water, then be to soak 90 seconds under the room temperature in 1.5: 10 hydrofluoric acid (HF) solution in concentration, dry up silicon chip with high pure nitrogen at last, for subsequent use; (2) functionalized carbon nanotube is processed: the mixed acid solution of the configuration 30ml vitriol oil, 10ml concentrated nitric acid, taking by weighing the 0.1000g multi-walled carbon nano-tubes puts in the middle of the mixed acid solution, mixing solutions was put into ultrasonic pond (temperature 50 C, 80W) sonic oscillation 3 hours, the membrane filtration of usefulness 0.4 μ m after reaction is finished, and with deionized water washing and filtering carbon nanotube until the filtrate pH value is 7.The carbon nanotube that filtration obtains is put into 60 ℃ of baking oven bakings 24 hours, for subsequent use; (3) dispersion of carbon nanotube 210: the carbon nanotube through functionalization is placed in the middle of the beaker, mixes mutually ultra-sonic dispersion with alcohol solvent; Then, by spin coating (Spin Coating) method, dispersion liquid is transferred to the surface of clean substrate, make the alcohol solvent volatilization, form staggered, interconnected carbon nano-tube film 210; (4) deposition of vanadium oxide 220: the substrate 1 that the surface is dispersed with carbon nanotube 210 is put into the reactor of vacuum pumping, adopt superb vanadium (V) as target, superb argon gas (Ar) as sputter gas, superb oxygen (O
2) as reactant gases, utilizing the method for direct current reaction magnetron sputtering is the vanadium oxide membrane 220 of 5~1500nm 200 ℃ of lower growth a layer thickness.The representative condition of deposition vanadium oxide is: sputtering voltage is 350V; Power is 600W; The per-cent of oxygen in gas mixture is 2%; Underlayer temperature is 200 ℃; The about 10nm/min of sedimentation rate; Depositing time 10 minutes; The pressure of main vacuum chamber is 1.1Pa in the deposition; The thickness of vanadium oxide membrane is about 100nm; Anneal forms vanadium oxide-carbon nano-tube compound film 2; (5) then sample cool to room temperature in main vacuum chamber, takes out sample from vacuum chamber; (6) as required, can repeat successively the steps such as carbon nanotube 210 dispersions, vanadium oxide 220 depositions and annealing, form vanadium oxide-carbon nanotube multilayer structure of composite membrane 2, satisfy the device needs.
Silicon chip of the present invention 1 cleans not to be only limited to and adopts Piranha and hydrofluoric acid solution, also comprises the cleaning that other solution known to the employing in the industry and method are carried out.The film growth substrate also is not particularly limited, and except Si (100) silicon chip, also comprises the monocrystalline silicon piece of other crystal orientation and size or non-crystalline silicon (a-Si) film, silicon nitride (SiN
x) film, silicon oxide (SiO
x) film, silicon oxynitride (SiN
xO
y) substrate (different according to the substrate kind, as to adopt suitable cleaning) of wherein a kind of such as film and their other materials such as composite membrane.Carbon nanotube 210 also is not particularly limited in the composite membrane, can be single wall or the multi-walled carbon nano-tubes of different diameter, different lengths; And this carbon nanotube can be the carbon nanotube through functionalization, also can be the original carbon nanotube without functionalization; Among the present invention the method for carbon nanotube dispersed at substrate surface also is not particularly limited, except spin coating technique, it also can be the method for other dispersing Nano carbon tubes known to dip-coating method, spraying method, spread coating, electrodip process, electrophoresis, the printing transplanting etc. in the industry.
Claims (5)
1. a preparation method who is used for the vanadium oxide film of micro-metering bolometer is characterized in that, may further comprise the steps:
1. clean substrate, dry up rear for subsequent use;
2. the carbon nanotube for preparing in advance is placed in the beaker, adopt first chemically treated mode, introduce functional group on the surface of carbon nanotube, through filtration, washing and drying step, obtain the carbon nanotube of functionalization, then, the carbon nanotube of this functionalization is placed in the middle of the beaker, mixes mutually with organic solvent, ultra-sonic dispersion, again dispersion liquid is transferred to through the surface of the substrate of clean, made solvent evaporates, form staggered, interconnected carbon nano-tube film;
3. being dispersed with of 2. obtaining of step put into the reactor of vacuum pumping through the substrate of the carbon nanotube of functionalization, utilize reactor growth one deck vanadium oxide membrane, the vanadium oxide membrane of growing is dispersed in the middle of the gap of the surface of carbon nanotube and tube and tube, annealing forms vanadium oxide-carbon nano-tube compound film structure;
4. after being cooled to room temperature, from reactor, take out;
5. as required, repeat successively carbon nanotube dispersed, vanadium oxide deposition and annealing steps, form vanadium oxide-carbon nanotube multilayer structure of composite membrane.
2. the preparation method of the vanadium oxide film for micro-metering bolometer according to claim 1, it is characterized in that, its step 2. in, be carbon nanotube dispersed a kind of in the middle of spin coating or dip-coating method, spraying method, spread coating, electrodip process, electrophoresis, printing are transplanted to the method for substrate surface, when adopting spin coating method, used dispersion liquid is a kind of in the middle of ethanol or Virahol, isopropylcarbinol, primary isoamyl alcohol, the isohexyl alcohol.
3. the preparation method of the vanadium oxide film for micro-metering bolometer according to claim 1, it is characterized in that, 2. the carbon nanotube accumbency that obtains in step on the surface of substrate, be staggered interconnect architecture, carbon nanotube is single wall or multi-walled carbon nano-tubes, the diameter of carbon nanotube is 1~50nm, and the length of carbon nanotube is 50~30000nm.
4. the preparation method of the vanadium oxide film for micro-metering bolometer according to claim 1 is characterized in that, step 2. in, the method for carbon nanotube being carried out functionalization is: adopt dense H
2SO
4With dense HNO
3A kind of in the middle of mixed solution, concentrated nitric acid, potassium permanganate, Fenton method are processed, in carbon nanotube introducing-COOH or-COH functional group.
5. the preparation method of the vanadium oxide film for micro-metering bolometer according to claim 1, it is characterized in that, its step 3. in, the preparation method of vanadium oxide membrane is a kind of in the middle of the magnetron sputtering, electron beam evaporation, thermal evaporation, organometallics chemical vapour deposition, laser ablation deposition, ald; When adopting magnetically controlled sputter method, used target is the oxide compound VO of vanadium metal or vanadium
x, x satisfies 1.0≤x≤2.5, and used reactant gases is that gas mixture and the per-cent of oxygen in gas mixture of argon gas and oxygen is 0.2~20%, and depositing temperature is 25~500 ℃.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201010222514 CN101886261B (en) | 2010-07-09 | 2010-07-09 | Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN 201010222514 CN101886261B (en) | 2010-07-09 | 2010-07-09 | Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CN101886261A CN101886261A (en) | 2010-11-17 |
| CN101886261B true CN101886261B (en) | 2013-04-24 |
Family
ID=43072347
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN 201010222514 Expired - Fee Related CN101886261B (en) | 2010-07-09 | 2010-07-09 | Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN101886261B (en) |
Families Citing this family (10)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN101915620B (en) * | 2010-08-20 | 2012-05-09 | 电子科技大学 | Preparation method of vanadium oxide thin film for microbolometer |
| CN104947073B (en) * | 2014-03-26 | 2017-11-14 | 清华大学 | The preparation method of nanotube films |
| CN104611670B (en) * | 2015-01-21 | 2017-04-12 | 中国科学院半导体研究所 | Preparation method of vanadium oxide film with high resistance temperature coefficient |
| CN107946451B (en) | 2016-10-12 | 2019-07-12 | 清华大学 | A kind of temperature sensing system |
| CN107933911B (en) | 2016-10-12 | 2019-07-12 | 清华大学 | A kind of bionic insect |
| CN107934904B (en) | 2016-10-12 | 2019-07-12 | 清华大学 | A kind of actuator and actuating system based on carbon nanotube |
| CN107932475B (en) | 2016-10-12 | 2019-07-12 | 清华大学 | A kind of bionic arm and the robot using the bionic arm |
| US10908025B2 (en) | 2016-12-07 | 2021-02-02 | Carbon Solutions, Inc. | Patterned focal plane arrays of carbon nanotube thin film bolometers with high temperature coefficient of resistance and improved detectivity for infrared imaging |
| CN109211459B (en) * | 2018-07-26 | 2020-11-20 | 西北工业大学 | Flexible carbon nano tube thermosensitive film shear stress micro-sensor and manufacturing method thereof |
| CN113764145A (en) * | 2020-06-05 | 2021-12-07 | 高尔科技股份有限公司 | Thermistor and microbolometer based on thermistor |
Family Cites Families (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US6144285A (en) * | 1999-09-13 | 2000-11-07 | Honeywell International Inc. | Thermal sensor and method of making same |
| US7723684B1 (en) * | 2007-01-30 | 2010-05-25 | The Regents Of The University Of California | Carbon nanotube based detector |
| CN101881667B (en) * | 2010-06-24 | 2015-09-09 | 电子科技大学 | A kind of uncooled microbolometer and preparation method thereof |
| CN101900607B (en) * | 2010-06-24 | 2012-07-25 | 电子科技大学 | Vanadium oxide film for infrared detector and manufacturing method thereof |
-
2010
- 2010-07-09 CN CN 201010222514 patent/CN101886261B/en not_active Expired - Fee Related
Also Published As
| Publication number | Publication date |
|---|---|
| CN101886261A (en) | 2010-11-17 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CN101886261B (en) | Vanadium oxide thin film for micro-metering bolometer and manufacturing method thereof | |
| CN101900607B (en) | Vanadium oxide film for infrared detector and manufacturing method thereof | |
| CN101881667B (en) | A kind of uncooled microbolometer and preparation method thereof | |
| CN101774530B (en) | Microbolometer and preparation method thereof | |
| CN101915620B (en) | Preparation method of vanadium oxide thin film for microbolometer | |
| CN102426060B (en) | Terahertz or infrared micro-bolometer and manufacturing method thereof | |
| Lehman et al. | Carbon nanotube-based black coatings | |
| Aguilar-Frutis et al. | A study of the dielectric characteristics of aluminum oxide thin films deposited by spray pyrolysis from Al (acac) 3 | |
| CN102794947B (en) | A kind of DAST-carbon nano tube composite film and preparation method thereof | |
| CN103413594A (en) | Flexible transparent conductive material of topological insulator and preparation method and application thereof | |
| Liu et al. | Photothermoelectric SnTe photodetector with broad spectral response and high on/off ratio | |
| Zhao et al. | Effects of uniaxial stress on the electrical structure and optical properties of Al-doped n-type ZnO | |
| CN102419212B (en) | Vanadium oxide composite film and preparation method thereof | |
| Zhang et al. | Highly sensitive and ultra-broadband VO2 (b) photodetector dominated by bolometric effect | |
| Agnihotri et al. | Electrical and optical properties of chemically deposited conducting glass for SIS solar cells | |
| CN107574475B (en) | A kind of HfS2The preparation method of single crystal nanoplate | |
| Yu et al. | Enhanced light-induced transverse thermoelectric effect in tilted BiCuSeO film via the ultra-thin AuNPs layer | |
| Wu et al. | Progress and challenges on 3D tubular structures and devices of 2D materials | |
| Wang et al. | Research on VO x uncooled infrared bolometer based on porous silicon | |
| Li et al. | Bosonic metal states in crystalline iron-based superconductors at the two-dimensional limit | |
| CN106835019B (en) | vanadium oxide composite film and preparation method thereof | |
| Fujishiro et al. | Investigation of fabrication conditions for VO2 thin films by MOD using carbon thermal reduction | |
| Maeda et al. | Evaluation of characteristics in VOx microbolometer fabricated by MOD on Si3N4/SiO2 membrane | |
| Zhang et al. | Preparation of TiO2-x film with a high TCR performance for uncooled thermal sensor | |
| Czarnacka et al. | The influence of annealing on the electrical and optical properties of silicon-rich silicon nitride films |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| C06 | Publication | ||
| PB01 | Publication | ||
| C10 | Entry into substantive examination | ||
| SE01 | Entry into force of request for substantive examination | ||
| C14 | Grant of patent or utility model | ||
| GR01 | Patent grant | ||
| CF01 | Termination of patent right due to non-payment of annual fee | ||
| CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20130424 Termination date: 20160709 |