CN1502405A - TiO2 photocatalyst film with inhomogeneously-doped metal ions on base body and preparation process thereof - Google Patents

TiO2 photocatalyst film with inhomogeneously-doped metal ions on base body and preparation process thereof Download PDF

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CN1502405A
CN1502405A CNA021520410A CN02152041A CN1502405A CN 1502405 A CN1502405 A CN 1502405A CN A021520410 A CNA021520410 A CN A021520410A CN 02152041 A CN02152041 A CN 02152041A CN 1502405 A CN1502405 A CN 1502405A
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film
metal ion
ion
tio
titanium dioxide
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CN1275686C (en
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梁园园
李新军
王良焱
张琦
郑少健
黄琮
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Guangzhou Institute of Energy Conversion of CAS
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Guangzhou Institute of Energy Conversion of CAS
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Abstract

The present invention relates to a TiO2 photocatalyst film in which the metal ions are non-uniformly doped on the base and its preparation method. Said film includes barrier SiO2 film layer, and it is characterized by that it also includes at least one layer of TiO2 photocatalyst film layer and at least one layer of metal ions doped TiO2 film layer, in the metal ions doped TiO2 film layer the atomic percentage of metal ions and Ti is 0.01-5%. Its preparation method includes the following steps: using sol-gel method to prepare barrier layer SiO2 film for 1-5 times, prepare TiO2 photocatalyst film for 2-20 times and prepare metal ions doped TiO2 film for 2-20 times on the base. After the metal ions are non-uniformly doped, its photocatalytic activity can be greatly raised.

Description

Metal ion non-uniform doping titanium dioxide optical catalyst film and preparation method thereof on the matrix
Technical field
The present invention relates to metal ion non-uniform doping titanium dioxide optical catalyst film and preparation method thereof on a kind of matrix.
Background technology
TiO 2As a kind of semiconductor light-catalyst, in two more than ten years in the past, obtained extensively and in depth research.Titanium dioxide film photocatalyst has good chemical stability and mechanical strength owing to possessing, in various fields, has application prospects, particularly 1997, Fujshima found that light urges the self-cleaning anti-fog function of agent film, has more caused people's extensive concern.Yet the titanium deoxid film on the carrier still exists the not high problem of photocatalysis efficiency because its specific area is less, and the titanium deoxid film of preparing highlight catalytic active more and more becomes the emphasis of present research.
At present, Chang Yong raising TiO 2The method of catalytic activity is included in semiconductor surface and adds supported noble metal, compound other metal oxide or doped metal ion etc.Chinese invention patent 1320557A discloses the pyrogenic titanium dioxide that adopts aerosol to mix, and doping component has: zinc oxide, platinum oxide, magnesia and/or aluminium oxide.Chinese invention patent 1323046A discloses nanometer magnetic titania material of manganese-zinc ferrite bluk recombination and preparation method thereof.The Chinese invention patent 00101041 of ULVAC Corp's application provides a kind of method of vacuum magnetic-control sputtering method light-plated catalytic film, Chinese invention patent 1243029A discloses a kind of spin-coating method coating semiconductive thin film, and the Chinese invention patent 96193834 of Japanese Toto Ltd application provides sol-gel process, sol method, coating process, the magnetron sputtering method of preparation photocatalysis film.Chinese patent database finds that domestic 15 patents that are detected all relate to photocatalysis film by retrieval, but the mode of all not mentioned employing non-uniform doping metal ion is with the method for the photocatalytic activity of raising titanium dioxide.
The content of invention
The objective of the invention is in order to overcome the not enough or difficult shortcoming of technical sophistication manufacturing of prior art photocatalytic activity, provide metal ion non-uniform doping titanium dioxide optical catalyst film on a kind of matrix to improve the photocatalytic activity of titanium dioxide, another object of the present invention is to provide the preparation method of this metal ion species non-uniform doping titanium dioxide optical catalyst film.
Metal ion non-uniform doping titanium dioxide optical catalyst film comprises barrier layer SiO on a kind of matrix of the present invention 2Thin layer (ground floor) is characterized in that also comprising one deck TiO at least 2Photocatalyst film layer and one deck metal ion mixing TiO at least 2Thin layer, TiO 2Photocatalyst film layer and metal ion mixing TiO 2Thin layer is alternate, successively all can, formed the metal ion non-uniform doping on the whole, metal ion mixing TiO 2Metal ion in the thin layer and the atomic percent of Ti are 0.01-5%.(said here " layer " is meant the identical overlapping again calculation one deck of chemical analysis, all calculates one deck no matter its dipping lifts preparation how many times (every dipping lifts preparation once increases by a substratum), as SiO 2Thin layer, TiO 2Thin layer, metal ion mixing TiO 2Thin layer)
Described metal ion chosen from Fe ion, vanadium ion, cadmium ion, chromium ion, cobalt ions, manganese ion, nickel ion, copper ion, zinc ion, tungsten ion or gold ion a kind of or two kinds.Preferred vanadium ion is or/and iron ion.
Described matrix is selected from glass, stainless steel, pottery or plastics
The preferred version second layer of metal ion non-uniform doping titanium dioxide optical catalyst film is the TiO that V/Ti=0.1-1.3% mixes vanadium on the described matrix 2Film, the 3rd layer are titanium dioxide optical catalyst film, the 3rd layer of titanium dioxide optical catalyst film of mixing iron for Fe/Ti=1.3-1.8% for titanium dioxide optical catalyst film or the second layer.
Described SiO 2Thin layer thickness is 50-80nm, described TiO 2The photocatalyst film layer thickness is 150nm-500nm, described metal ion mixing TiO 2Thin layer thickness is 150nm-500nm.
The preparation method of metal ion non-uniform doping titanium deoxide catalyst film comprises the following steps: on the above-mentioned matrix
(a) on matrix, prepare barrier layer SiO with sol-gel process 2Film 1-5 time (50nm-80nm);
(b) use sol-gel process at SiO 2Prepare TiO on the film 2Photocatalyst film 2-20 time (150nm-500nm);
(c) on above-mentioned film, prepare metal ion mixing TiO with sol-gel process 2Film 2-20 time (150nm-500nm); Wherein (b) and (c) order of step and number of times are determined according to membrane structure.
Preferred version lifts preparation 1-3 time for dipping in (a) among the described preparation method, (b), each dipping lifts and prepares 3-8 time (every dipping lifts preparation once increases by a substratum) in (c).
Concrete embodiment
The following example will further specify the present invention, but the present invention is not construed as limiting.
The titanium deoxid film of embodiment 1 preparation surface doping comprises the following steps: successively
(a) preparation of barrier layer SiO2 film
The preparation of Ludox: get 100ml absolute ethyl alcohol, 104ml ethyl orthosilicate, 160ml absolute ethyl alcohol 900rpm in the 500ml triangular flask successively and stir 1hr, getting 26ml HCl (2M) slowly is added dropwise in the above triangular flask when evenly stirring, drip off the back and continue to stir 1hr, the dark place is left standstill 24hr and is got Ludox.
Barrier layer SiO 2The preparation of film
(200mm * 34mm * 2mm) soaked two days in concentrated nitric acid solution the simple glass sheet, took out afterwash, soaked about two hours with washing lotion again, cleaned with distilled water, and oven for drying is then promptly finished the preprocessing process of sheet glass.Adopt dip-coating method, pull rate is 2mms -1, sheet glass is at SiO 2Lift in the colloidal sol once, wet film is put into 500 ℃ of Muffle furnaces behind 100 ℃ baking oven inner drying 5min, is incubated and naturally cools to room temperature after 1 hour.Repeat aforesaid operations once, can obtain SiO 2Film.
(b) preparation TiO 2Photocatalyst film
TiO 2The preparation of colloidal sol: earlier positive four butyl esters of metatitanic acid, diethanol amine, water are mixed with absolute ethyl alcohol, stirred 1 hour, obtain solution (1).Distilled water mixes with remaining ethanol, obtains solution (2).The solution (2) that will move under vigorous stirring again in the separatory funnel slowly is added drop-wise in the solution (1), continues to stir promptly to get TiO 2 sol half an hour.Wherein, Ti (OC 4H 9) 4: EtOH: H 2O: NH (C 2H 5OH) 2=1: 26.5: 1: 1 (mol ratio).
Adopt dip-coating method, pull rate is 2mms -1, above-mentioned sheet glass flooded in this colloidal sol lifting once, 100 ℃ of baking 10min will lift drying course 4 times repeatedly in electrically heated drying cabinet, place 2 ℃ of min of Muffle furnace -1Temperature programming to 500 ℃, constant temperature 1hr obtains TiO 2Film.
(c) TiO of preparation doping 2Photocatalyst film
The preparation metal ion carries out the TiO of doping vario-property 2Colloidal sol: earlier positive four butyl esters of metatitanic acid, diethanol amine, water are mixed with absolute ethyl alcohol, stirred 1 hour, obtain solution (1).Distilled water mixes with remaining ethanol, obtains solution (2).The solution (2) that will move under vigorous stirring in the separatory funnel slowly is added drop-wise in the solution (1) again, after waiting to dropwise, adds the metal ion that will mix, and continues to stir promptly to get metal ion doped titanium dioxide colloidal sol half an hour.Wherein, Ti (OC 4H 9) 4: EtOH: H 2O: NH (C 2H 5OH) 2=1: 26.5: 1: 1 (mol ratio).In the present invention, preferred V 5+, adopt metavanadic acid ammonia to mix, wherein V/Ti (atom%) elects 0.1,0.25,0.5,1,1.5 as.And Fe 3+, adopt Fe (NO) 39H 2O mixes, and Fe/Ti (atom%) elects 0.05,0.1,0.25,0.5,1,1.5,2,2.5 as.
Above-mentioned sheet glass is being mixed V 5+Or mix Fe 3+TiO 2Dipping lifts once in the colloidal sol, and 100 ℃ of baking 10min will lift drying course 4 times repeatedly in electrically heated drying cabinet, place 2 ℃ of min of Muffle furnace -1Temperature programming to 500 ℃, constant temperature 1hr, the TiO that obtains mixing 2Film.
The titanium deoxid film that embodiment mixes 2 preparation bottoms comprises the following steps: successively
(a) barrier layer SiO 2The preparation of film: same with embodiment 1
(b) TiO of preparation doping 2Photocatalyst film: same with (c) among the embodiment 1
(c) preparation TiO 2Photocatalyst film: same with (b) among the embodiment 1
The bulk phase-doped titanium deoxid film of embodiment 3 preparations comprises the following steps: successively
(a) preparation of barrier layer SiO2 film: same with embodiment 1
(b) TiO of preparation doping 2Photocatalyst film: same with (c) among the embodiment 1
(c) TiO of preparation doping 2Photocatalyst film: same with (c) among the embodiment 1
Embodiment 4 photocatalysis performances
The dominant wavelength that adopts 125W is that the high-pressure sodium lamp (the inferior bright electric light source in Beijing Development Co., Ltd) of 365nm is light source, and the photocatalytic degradation of methyl orange solution is a model reaction.Detailed process is: mix iron TiO 2(35 * 200mm) put into vertically that initial concentration is housed is 10mg/L to the sheet glass of film, and in the teat glass of 400ml methyl orange solution, sheet glass is placed according to wall, and high-pressure sodium lamp is vertically put into test tube central authorities.With air pump bubbling air in the solution.Timing sampling in the light-catalyzed reaction process, the mensuration of methyl orange concentration adopt 752 type ultraviolet grating spectrophotometric determination 446nm place light absorption values, and its absorbance and concentration have good linear relationship.According to first order kinetics relational expression (lnC 0/ C=kt), adopt linear regression analysis can use the apparent speed constant k of methyl orange solution decolouring when respectively organizing catalyst, come the photocatalytic activity of comparison catalyst with this.
The apparent speed constant of table 1 photocatalytic degradation methyl orange and the relation of V/Ti ratio
Mix at the end 0.00316 ?0.00651 ?0.00678 ?0.00713 ?0.00744 ?0.00223
Body is mixed 0.00316 ?0.00252 ?0.00288 ?0.00236 ?0.00217 ?0.00201
Table is mixed 0.00316 ?0.00219 ?0.00209 ?0.00218 ?0.00185 ?0.00216
The apparent speed constant of table 2 photocatalytic degradation methyl orange and the relation of Fe/Ti ratio
The drawing explanation
Fig. 1 is the difference along with doping content; Body mix mutually vanadium film, surface mix vanadium film and bottom mix vanadium film degradation methyl orange the changing trend diagram of apparent speed constant.As seen from Figure 1, when V/Ti=0.9-1.0%, the photocatalytic activity that the vanadium film is mixed in the bottom has reached maximum.The surface is mixed the vanadium film and is then constantly reduced with the photocatalytic activity that body is mixed the vanadium film mutually.Wherein the TiO of vanadium is mixed in the bottom 2The maximum photocatalysis apparent speed constant of film is than pure TiO 2The apparent speed constant of film will exceed about 2.3 times.
Fig. 2 is the difference along with doping content, and body is mixed iron thin film and the surperficial changing trend diagram of mixing the apparent speed constant of iron thin film degraded methyl orange mutually.As seen from Figure 2, when Fe/Ti=0.12%, the photocatalytic activity that body is mixed iron thin film has mutually reached maximum.When Fe/Ti=1.5%, the photocatalytic activity that iron thin film is mixed on the surface has also reached maximum.And when Fe/Ti more than or equal to 0.5% the time, the photocatalytic activity that iron thin film is mixed on the surface is mixed the photocatalytic activity of iron thin film mutually apparently higher than body.When Fe/Ti is the photocatalytic activity height of bulk phase-doped film less than 0.5% the time.And the maximum that the surperficial maximum photocatalysis apparent speed constant of mixing iron thin film is mixed iron mutually than body will exceed 1.5 times.

Claims (8)

1. metal ion non-uniform doping titanium dioxide optical catalyst film comprises barrier layer SiO on the matrix 2Thin layer (ground floor) is characterized in that also comprising one deck TiO at least 2Photocatalyst film layer and one deck metal ion mixing TiO at least 2Thin layer, TiO 2Photocatalyst film layer and metal ion mixing TiO 2Thin layer is alternate, successively all can, formed the metal ion non-uniform doping on the whole, metal ion mixing TiO 2Metal ion in the thin layer and the atomic percent of Ti are 0.01-5%.
2. according to metal ion non-uniform doping titanium dioxide optical catalyst film on a kind of matrix described in the claim 1, it is characterized in that a kind of of metal ion chosen from Fe ion, vanadium ion, cadmium ion, chromium ion, cobalt ions, manganese ion, nickel ion, copper ion, zinc ion, tungsten ion or gold ion or two kinds.
3. according to metal ion non-uniform doping titanium dioxide optical catalyst film on a kind of matrix described in the claim 2, it is characterized in that metal ion is that vanadium ion is or/and iron ion.
4. according to metal ion non-uniform doping titanium dioxide optical catalyst film on a kind of matrix described in the claim 1, it is characterized in that described matrix is selected from glass, stainless steel, pottery or plastics.
5. according to metal ion non-uniform doping titanium dioxide optical catalyst film on a kind of matrix described in the claim 1, it is characterized in that the preferred version second layer is the TiO that V/Ti=0.1-1.3% mixes vanadium 2Film, the 3rd layer are titanium dioxide optical catalyst film, the 3rd layer of titanium dioxide optical catalyst film of mixing iron for Fe/Ti=1.3-1.8% for titanium dioxide optical catalyst film or the second layer.
6. according to metal ion non-uniform doping titanium dioxide optical catalyst film on any matrix among the claim 1-5, it is characterized in that SiO 2Thin layer thickness is 50-80nm, TiO 2The photocatalyst film layer thickness is 150nm-500nm, metal ion mixing TiO 2Thin layer thickness is 150nm-500nm.
7. the preparation method of metal ion non-uniform doping titanium dioxide optical catalyst film on the matrix described in the claim 1 is characterized in that comprising the following steps:
(a) on matrix, prepare barrier layer SiO with sol-gel process 2Film 1-5 time (50nm-80nm);
(b) use sol-gel process at SiO 2Prepare TiO on the film 2Photocatalyst film 2-20 time (150nm-500nm);
(c) on above-mentioned film, prepare metal ion mixing TiO with sol-gel process 2Film 2-20 time (150nm-500nm); Wherein (b) and (c) order of step and number of times are determined according to membrane structure.
8. according to the preparation method of metal ion non-uniform doping titanium dioxide optical catalyst film on the matrix described in the claim 7, it is characterized in that in (a) preparation 1-3 time, (b), respectively prepare 3-8 time in (c).
CN 02152041 2002-11-26 2002-11-26 TiO2 photocatalyst film with inhomogeneously-doped metal ions on base body and preparation process thereof Expired - Fee Related CN1275686C (en)

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Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1323752C (en) * 2005-04-30 2007-07-04 中国地质大学(武汉) Manufacture of Ag+-Fe+ dosed TiO2 weakly exciting catalytic luminating film
US8080315B2 (en) 2007-02-27 2011-12-20 Horiba, Ltd. Responsive glass membrane and glass electrode
CN102294234A (en) * 2011-07-15 2011-12-28 刘凡新 Composite titanium dioxide photocatalyst and preparation method thereof
CN102407107A (en) * 2011-11-10 2012-04-11 苏州大学 Metal/TiO2 composite multilayer film photocatalyst and preparation method thereof
CN102407105A (en) * 2011-10-27 2012-04-11 济南大学 Nanometer titanium dioxide modified film and gradient doping modification method of nanometer titanium dioxide film
CN103007948A (en) * 2012-12-18 2013-04-03 湖北工业大学 Preparation method of glass loaded copper/chromium ion double doped nano titanium dioxide photocatalysis film
CN103359955A (en) * 2012-03-31 2013-10-23 江南大学 Preparation method of zinc-doped anti-reflection type self-cleaning coating
CN103638930A (en) * 2013-11-28 2014-03-19 陕西科技大学 Preparation method and application of CO<2+>-doped titanium dioxide self-cleaning film
CN104258837A (en) * 2014-10-21 2015-01-07 辽宁工业大学 Preparation method of carbon and silicon co-doped nano titanium dioxide
CN105413690A (en) * 2015-10-26 2016-03-23 湖南永清环保研究院有限责任公司 Catalyst for degrading organic wastewater and preparation method thereof
CN108147677A (en) * 2017-12-06 2018-06-12 吕莉 A kind of preparation method of high efficiency photocatalysis glass with clean

Cited By (14)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1323752C (en) * 2005-04-30 2007-07-04 中国地质大学(武汉) Manufacture of Ag+-Fe+ dosed TiO2 weakly exciting catalytic luminating film
US8080315B2 (en) 2007-02-27 2011-12-20 Horiba, Ltd. Responsive glass membrane and glass electrode
CN102294234A (en) * 2011-07-15 2011-12-28 刘凡新 Composite titanium dioxide photocatalyst and preparation method thereof
CN102407105A (en) * 2011-10-27 2012-04-11 济南大学 Nanometer titanium dioxide modified film and gradient doping modification method of nanometer titanium dioxide film
CN102407105B (en) * 2011-10-27 2013-03-27 济南大学 Nanometer titanium dioxide modified film and gradient doping modification method of nanometer titanium dioxide film
CN102407107A (en) * 2011-11-10 2012-04-11 苏州大学 Metal/TiO2 composite multilayer film photocatalyst and preparation method thereof
CN102407107B (en) * 2011-11-10 2013-06-19 苏州大学 Metal/TiO2 composite multilayer film photocatalyst and preparation method thereof
CN103359955B (en) * 2012-03-31 2016-04-13 江南大学 A kind of preparation method mixing zinc anti-reflection emitting automatic cleaning coating
CN103359955A (en) * 2012-03-31 2013-10-23 江南大学 Preparation method of zinc-doped anti-reflection type self-cleaning coating
CN103007948A (en) * 2012-12-18 2013-04-03 湖北工业大学 Preparation method of glass loaded copper/chromium ion double doped nano titanium dioxide photocatalysis film
CN103638930A (en) * 2013-11-28 2014-03-19 陕西科技大学 Preparation method and application of CO<2+>-doped titanium dioxide self-cleaning film
CN104258837A (en) * 2014-10-21 2015-01-07 辽宁工业大学 Preparation method of carbon and silicon co-doped nano titanium dioxide
CN105413690A (en) * 2015-10-26 2016-03-23 湖南永清环保研究院有限责任公司 Catalyst for degrading organic wastewater and preparation method thereof
CN108147677A (en) * 2017-12-06 2018-06-12 吕莉 A kind of preparation method of high efficiency photocatalysis glass with clean

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