CN1915487A - Nano photocatalyst of possessing function of molecular engram, preparation method and usage - Google Patents
Nano photocatalyst of possessing function of molecular engram, preparation method and usage Download PDFInfo
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- CN1915487A CN1915487A CN 200610053334 CN200610053334A CN1915487A CN 1915487 A CN1915487 A CN 1915487A CN 200610053334 CN200610053334 CN 200610053334 CN 200610053334 A CN200610053334 A CN 200610053334A CN 1915487 A CN1915487 A CN 1915487A
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Abstract
A nano-photocatalyst with molecular engram function has a 3D pore structure matched fully with the space structure of the compounds in formaldehyde or benzene system and combined specifically with them. It can be used to improve indoor air by adsorbing and degradating said compounds. Its preparing process is also disclosed.
Description
Technical field
The present invention relates to a kind of photochemical catalyst, refer in particular to a kind of application of nano-photocatalyst, preparation method and the indoor volatile organic matter of photocatalytic degradation thereof of tool function of molecular engram.
Background technology
Have people's all one's life spend indoor approximately, indoor environment is particularly important to the influence of health of people time of 70~90%.Be a ubiquitous class organic pollution in the room air as formaldehyde, benzene series thing VOCs (VOCs) such as (benzene,toluene,xylenes) in the room air.Ubiquitous formaldehyde, benzene series thing etc. have neurotoxicity, renal toxicity, hepatotoxicity wind agitation and carcinogenicity in known many VOCs, the especially room air, also can damage blood constituent and cardiovascular system, cause gastrointestinal disturbance, and health in serious harm.The improvement of room air VOCs becomes one of international in recent years research focus.
Strict control has been done to the discharging of VOCs in the room air in countries in the world, and " the IAQ standard) " of China carried out strict qualification to the VOCs such as formaldehyde in the room air in (GB/T18883-2002): the standard value of formaldehyde, benzene,toluene,xylene is respectively 0.10,0.11,0.20,0.20mg/m
3(1 little hourly value).Therefore, the improvement of VOCs just more and more is subject to people's attention in the room air.
Nineteen nineties, begin to attempt the photoactivation method in the world and remove VOCs.Discover that aspect the removal of VOCs, gas-phase photocatalysis has the following advantages: reaction can be carried out at normal temperatures and pressures, and directly makes oxidant with the oxygen in the atmosphere, the reaction efficiency height; Catalyst easily reclaims, and can realize the serialization processing; Can use the lower light source of energy, the light utilization efficiency height is easily realized complete oxidation; The reaction light source belongs to cold light, and environment temperature is not made significant difference; The diffusion rate height of molecule in the gas phase, reaction speed is fast.Used TiO
2Advantages such as it is long that photochemical catalyst not only has active height, Heat stability is good, continuation, harmless but also have sterilization, deodorizing, from effects such as cleanings.TiO
2Photochemical catalyst has great application prospect on purifying VOCs.
But TiO
2Photocatalysis exist following problem: quantum efficiency low (about 4%); The generation of electron-hole pair, migration or recombination rate height; Reactive material is adsorbed on catalyst surface, catalytic reaction takes place, and product is low from the speed of catalyst surface desorption.These problems make life of catalyst shorter, and the overall efficiency of various photocatalytic applications commodity is low, stability is poor.Efficiently, the development of the photochemical catalyst of life-span length, stable performance just becomes the key that strengthens various light catalytic purifying product competitiveness.
To TiO
2Carried out finishing (as noble metal decorated, semiconductor is compound and doped transition metal ions etc.), can reduce generation, migration or the recombination rate of electron-hole pair, improve the utilization rate and the TiO of photon
2Photocatalytic activity.Yet, because pollutant is limited in the absorption of catalyst surface, limited the raising of photocatalysis efficiency, and the intermediate that generates in the light-catalyzed reaction process or end product can be adsorbed on the catalyst surface, occupy active sites, can cause catalysqt deactivation, high efficiency to be difficult to continue.
In photochemical catalyst, add strong adsorptivity material (as active carbon) but the intensified response thing in the absorption of catalyst surface, improve the speed of catalytic reaction.Yet,, be difficult to obtain lasting high degradation efficiency because all there is saturated adsorption phenomena in adsorbents such as active carbon, carbon black.
To sum up, reducing intermediate product is one of key that improves photochemical catalyst life-span and activity in absorption, the fortifying catalytic agent of catalyst surface to the absorption property of target contaminant.How to develop the selective absorption of target contaminant, do not adsorb the TiO of intermediate product
2Photochemical catalyst is photocatalysis technology is able to practical application in indoor VOCs is administered a key, and molecular imprinting (MIT) can effectively address the above problem.
MIT is meant the technology of preparing into the functional material that obtains to mate fully with certain a part (template molecule) on space structure and binding site.It has three big characteristics: (1) precordainment: can prepare different function of molecular engram materials according to different purposes, to satisfy different needs; (2) identity: can discern microsphere according to the function of molecular engram material that template molecule is customized single-mindedly; (3) practicality: can be comparable with natural biomolecule recognition system, have the stability and the long service life of height.MIT realizes by the following method: (1) at first combines with template molecule with the function monomer with suitable functional group and forms monomer-template molecule compound; (2) select suitable crosslinking agent that function monomer is cross-linked into co-polymer mutually, thereby the functional group on the function monomer is fixed up on space arrangement and spatial orientation; (3) by certain method template molecule is sloughed.So just in high-molecular copolymer, stay next and template molecule coupling fully on space structure, and can with the single-minded three-dimensional hole that combines of template molecule.This three-dimensional hole can optionally combine with template molecule again, promptly template molecule is had the selectivity recognition reaction.
Summary of the invention
The invention provides a kind of PARA FORMALDEHYDE PRILLS(91,95), the benzene series thing has the selective absorption function, and does not adsorb the nano-photocatalyst of intermediate product.
The present invention also provides the method for preparing this photochemical catalyst, utilize molecular imprinting (MIT), with of greatest concern in the room air, bigger formaldehyde, the benzene series thing (benzene,toluene,xylene etc.) of harm be template molecule, it is adsorbed onto have that specific area is big, the duct even, template molecule is had monolayer adsorption and is easy to form mesoporous material in the mesoporous material that the demoulding removes | the template molecule compound; (sol-gel) makes TiO by sol-gel process
2Gel, and with TiO
2Gel is assembled in this compound, forms mesoporous material | template molecule | and TiO
2Gel " sandwich " structure, through the technologies such as calcining, fragmentation that heat up, mesoporous material and template molecule are removed in the demoulding, prepare the nano-TiO that template molecule is had the selective absorption function again
2Photochemical catalyst.
The present invention further provides the purposes of above-mentioned nano-photocatalyst.
A kind of nano-photocatalyst of tool function of molecular engram has and formaldehyde or benzene series thing coupling fully on space structure, and can with formaldehyde or the single-minded three-dimensional hole that combines of benzene series thing.
A kind of method for preparing above-mentioned nano-photocatalyst may further comprise the steps:
(1) selected formaldehyde or benzene series thing are as template molecule;
(2) template molecule in (1) is adsorbed onto on the mesoporous material to saturated, forms mesoporous material | the template molecule compound;
(3) alkyl oxide with titanium is a sol precursor, alcohols solvent is a solvent, and inorganic acid is an inhibitor, adopts sol-gel process, mol ratio according to the alkyl oxide of titanium, alcohols solvent, water, inorganic acid is 1: (2~20): (1~10): mix (3~15), makes TiO
2Gel;
(4) with the TiO that makes in (3)
2Gel is according to the alkyl oxide of titanium: the mol ratio of mesoporous material is 1: (2~20) are coated on the composite surface that makes in (2), form mesoporous material | template molecule | and TiO
2Gel " sandwich " structure;
(5) with gained " sandwich " structure intensification calcining, fragmentation in (4), demoulding is removed mesoporous solid and template molecule, forms nano-photocatalyst.
Described mesoporous material is selected NACF or molecular sieve for use.
The alkyl oxide of described titanium is selected isopropyl titanate, tetrabutyl titanate or isopropyl titanate for use.
Described alcohols solvent adopts ethanol.
Described inorganic acid adopts Bronsted acid.
Calcine in tube furnace in N in the step (5)
2Carry out in the atmosphere, calcining heat is 300~700 ℃.
The application of above-mentioned nano-photocatalyst low concentration formaldehyde, benzene series thing in the degraded air.
The experiment of catalyst performance evaluation and degraded indoor VOCs thereof is carried out in the continuous-flow light-catalyzed reaction system.
Definition selectivity factor α=(Ф
1/ Ф
0)/(C
1/ C
0)=Ф
1* C
1/ Ф
0* C
0, Ф wherein
1, Ф
0Be respectively the photocatalytic degradation efficient of catalyst, C to template molecule and chaff interference
1, C
0Be respectively the molar concentration of template molecule and chaff interference.With selectivity factor and photocatalytic degradation efficient is index, and itself and commercialization P25 (German Degussa company produce) are compared, and catalyst activity is estimated.
Advantage of the present invention:
1, three-dimensional hole can optionally combine with formaldehyde or benzene series thing again, and PARA FORMALDEHYDE PRILLS(91,95) or benzene series thing have the selectivity recognition reaction;
2, can improve adsorptivity, degradation efficiency and the life-span of photochemical catalyst greatly;
3, be used for significantly to reduce behind the indoor air cleaner etc. gaseous contamination substrate concentration such as indoor VOCs, promote indoor air quality, contribute for waiting improvement of air in closed space quality in indoor and the car;
4, economic benefit is obvious, but suitability for industrialized production.
Description of drawings
Fig. 1 is preparation technology's of the present invention flow chart.
The specific embodiment
A kind of nano-photocatalyst of tool function of molecular engram has and formaldehyde or benzene series thing coupling fully on space structure, and can with formaldehyde or the single-minded three-dimensional hole that combines of benzene series thing.
As shown in Figure 1, prepare the method for above-mentioned nano-photocatalyst, may further comprise the steps:
(1) selected formaldehyde or benzene series thing are as template molecule;
(2) template molecule in (1) is adsorbed onto on the mesoporous material to saturated, forms mesoporous material | the template molecule compound;
(3) alkyl oxide with titanium is a sol precursor, alcohols solvent is a solvent, and inorganic acid is an inhibitor, adopts sol-gel process, mol ratio according to the alkyl oxide of titanium, alcohols solvent, water, inorganic acid is 1: (2~20): (1~10): mix (3~15), makes TiO
2Gel;
(4) with the TiO that makes in (3)
2Gel is according to the alkyl oxide of titanium: the mol ratio of mesoporous material is 1: (2~20) are coated on the composite surface that makes in the step (2), form mesoporous material | template molecule | and TiO
2Gel " sandwich " structure;
(5) with gained " sandwich " structure intensification calcining, fragmentation in (4), demoulding is removed mesoporous solid and template molecule, forms nano-photocatalyst.
Embodiment 1
(1) selected formaldehyde is as template molecule, and active carbon is a mesoporous material;
(2) formaldehyde is adsorbed onto on the active carbon to saturated, forms active carbon | the compound of formaldehyde;
(3) with the tetrabutyl titanate be sol precursor, ethanol is solvent, and Bronsted acid is an inhibitor, adopts sol-gel process, and be 1: 20: 3 according to the mol ratio of tetrabutyl titanate, ethanol, water, Bronsted acid: 15 mix, and make TiO
2Gel;
(4) with the TiO that makes
2Gel is according to tetrabutyl titanate: the mol ratio of active carbon is to be coated on the active carbon that makes in (2) at 1: 15 | the methanal complex surface forms active carbon | and formaldehyde | TiO
2" sandwich " structure of gel;
(5) gained " sandwich " structure in (4) is calcined 4h, fragmentation at 600 ℃, demoulding is removed active carbon and formaldehyde, forms the nano-photocatalyst that PARA FORMALDEHYDE PRILLS(91,95) has special absorption degradation function.
With formaldehyde, toluene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system, and initial concentration is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, toluene is respectively 98%, 0.5%, and the selectivity factor of PARA FORMALDEHYDE PRILLS(91,95) is 75.Substantially do not find deactivation phenomenom in 72 hours, high efficiency is constant substantially.Compare with the degradation efficiency of P25 PARA FORMALDEHYDE PRILLS(91,95) under the same experimental conditions, its catalytic efficiency is 10.5 times of P25, and the selectivity factor of PARA FORMALDEHYDE PRILLS(91,95) is 172 times of P25.
Embodiment 2
According to the step of embodiment 1, be that template molecule, active carbon are that mesoporous material makes active carbon with benzene | the compound of benzene; With the tetrabutyl titanate is Gel Precursor, is 1: 2: 10 according to the mol ratio of tetrabutyl titanate, ethanol, water, Bronsted acid: 3 mix, and make TiO
2Gel; According to tetrabutyl titanate: the mol ratio of active carbon be 1: 5 with TiO
2Gel pack is overlying on active carbon | and the composite surface of benzene forms active carbon | benzene | TiO
2" sandwich " structure of gel, at 350 ℃ of calcining 4h, broken, demoulding is removed active carbon and benzene, makes the nano-photocatalyst that benzene is had special absorption degradation function.
With formaldehyde, benzene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde and benzene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, benzene is respectively 0.7%, 93%, is not find deactivation phenomenom in 345,72 hours substantially to the selectivity factor of benzene, and high efficiency is constant substantially.With P25 under the same experimental conditions degradation efficiency of benzene is compared, its catalytic efficiency is 8.5 times of P25, is 113 times of P25 to the selectivity factor of benzene.
Embodiment 3
According to the step of embodiment 1, be that template molecule, active carbon are that mesoporous material makes active carbon with toluene | the compound of toluene; With the tetrabutyl titanate is Gel Precursor, is 1: 5: 5 according to the mol ratio of tetrabutyl titanate, ethanol, water, Bronsted acid: 8 mix, and make TiO
2Gel; According to tetrabutyl titanate: the mol ratio of active carbon be 1: 2 with TiO
2Gel pack is overlying on active carbon | and the composite surface of toluene forms active carbon | toluene | TiO
2" sandwich " structure of gel, at 500 ℃ of calcining 4h, broken, demoulding is removed active carbon and toluene, makes the nano-photocatalyst that toluene is had special absorption degradation function.
With formaldehyde, toluene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde, toluene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, toluene is respectively 0.9%, 95%, is not find deactivation phenomenom in 323,72 hours substantially to the selectivity factor of toluene, and high efficiency is constant substantially.With P25 under the same experimental conditions degradation efficiency of toluene is compared, its catalytic efficiency is 9.5 times of P25, is 151 times of P25 to the selectivity factor of toluene.
Embodiment 4
According to the step of embodiment 1, be that template molecule, active carbon are that mesoporous material makes active carbon with dimethylbenzene | the compound of dimethylbenzene; With the tetrabutyl titanate is Gel Precursor, is 1: 18: 5 according to the mol ratio of tetrabutyl titanate, ethanol, water, Bronsted acid: 7 mix, and make TiO
2Gel; According to tetrabutyl titanate: the mol ratio of active carbon be 1: 8 with TiO
2Gel pack is overlying on active carbon | and the composite surface of dimethylbenzene forms active carbon | dimethylbenzene | TiO
2" sandwich " structure of gel, at 700 ℃ of calcining 4h, broken, demoulding is removed active carbon and dimethylbenzene, makes the nano-photocatalyst that paraxylene has special absorption degradation function.
With formaldehyde, dimethylbenzene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde, dimethylbenzene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, dimethylbenzene is respectively 0.9%, 93%, and the selectivity factor of paraxylene is not find deactivation phenomenom in 365,72 hours substantially, and high efficiency is constant substantially.Compare with the degradation efficiency of P25 paraxylene under the same experimental conditions, its catalytic efficiency is 6.5 times of P25, and the selectivity factor of paraxylene is 85 times of P25.
Embodiment 5
According to the step of embodiment 1, be that template molecule, molecular sieve are that mesoporous material makes molecular sieve with toluene | the compound of toluene; With the tetrabutyl titanate is Gel Precursor, is 1: 10: 7 according to the mol ratio of tetrabutyl titanate, ethanol, water, Bronsted acid: 12 mix, and make TiO
2Gel; According to tetrabutyl titanate: the mol ratio of molecular sieve be 1: 15 with TiO
2Gel pack is overlying on molecular sieve | and the composite surface of toluene forms molecular sieve | toluene | TiO
2" sandwich " structure of gel, at 450 ℃ of calcining 4h, broken, demoulding is removed molecular sieve and toluene, makes the nano-photocatalyst that toluene is had special absorption degradation function.
With formaldehyde, toluene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde, toluene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, toluene is respectively 0.9%, 98%, is not find deactivation phenomenom in 334,72 hours substantially to the selectivity factor of toluene, and high efficiency is constant substantially.With P25 under the same experimental conditions degradation efficiency of toluene is compared, its catalytic efficiency is 11.2 times of P25, is 101 times of P25 to the selectivity factor of toluene.
Embodiment 6
According to the step of embodiment 1, be that template molecule, molecular sieve are that mesoporous material makes molecular sieve with toluene | the compound of toluene; With the isopropyl titanate is Gel Precursor, is 1: 18: 6 according to the mol ratio of isopropyl titanate, ethanol, water, Bronsted acid: 8 mix, and make TiO
2Gel; According to isopropyl titanate: the mol ratio of molecular sieve be 1: 10 with TiO
2Gel pack is overlying on molecular sieve | and the composite surface of toluene forms molecular sieve | toluene | TiO
2" sandwich " structure of gel, at 550 ℃ of calcining 4h, broken, demoulding is removed molecular sieve and toluene, makes the nano-photocatalyst that toluene is had special absorption degradation function.
With formaldehyde, toluene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde, toluene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, toluene is respectively 0.9%, 93%, is not find deactivation phenomenom in 317,72 hours substantially to the selectivity factor of toluene, and high efficiency is constant substantially.With P25 under the same experimental conditions degradation efficiency of toluene is compared, its catalytic efficiency is 7.5 times of P25, is 89 times of P25 to the selectivity factor of toluene.
Embodiment 7
According to the step of embodiment 1, be that template molecule, molecular sieve are that mesoporous material makes molecular sieve with toluene | the compound of toluene; With the isopropyl titanate is Gel Precursor, is 1: 15: 5 according to the mol ratio of isopropyl titanate, ethanol, water, Bronsted acid: 8 mix, and make TiO
2Gel; According to isopropyl titanate: the mol ratio of molecular sieve be 1: 18 with TiO
2Gel pack is overlying on molecular sieve | and the composite surface of toluene forms molecular sieve | toluene | TiO
2" sandwich " structure of gel, at 650 ℃ of calcining 4h, broken, demoulding is removed molecular sieve and toluene, makes the nano-photocatalyst that toluene is had special absorption degradation function.
With formaldehyde, toluene is target contaminant, carries out catalyst performance evaluation in the continuous-flow light-catalyzed reaction system.The initial concentration of formaldehyde, toluene all is 10mg/m in the system
3, humidity is 60%, and reaction temperature is 25 ℃, and catalyst loadings is 1.51mg/cm
2, the degradation efficiency of formaldehyde, toluene is respectively 0.9%, 90%, is not find deactivation phenomenom in 306,72 hours substantially to the selectivity factor of toluene, and high efficiency is constant substantially.With P25 under the same experimental conditions degradation efficiency of toluene is compared, its catalytic efficiency is 5.9 times of P25, is 98 times of P25 to the selectivity factor of toluene.
Claims (8)
1. the nano-photocatalyst of a tool function of molecular engram is characterized in that: it has and formaldehyde or benzene series thing coupling fully on space structure, and can with formaldehyde or the single-minded three-dimensional hole that combines of benzene series thing.
2. one kind prepares the method for nano-photocatalyst according to claim 1, it is characterized in that may further comprise the steps:
(1) selected formaldehyde or benzene series thing are as template molecule;
(2) template molecule in (1) is adsorbed onto on the mesoporous material to saturated, forms mesoporous material | the template molecule compound;
(3) alkyl oxide with titanium is a sol precursor, alcohols solvent is a solvent, and inorganic acid is an inhibitor, adopts sol-gel process, mol ratio according to the alkyl oxide of titanium, alcohols solvent, water, inorganic acid is 1: (2~20): (1~10): mix (3~15), makes TiO
2Gel;
(4) with the TiO that makes in (3)
2Gel is according to the alkyl oxide of titanium: the mol ratio of mesoporous material is 1: (2~20) are coated on the composite surface that makes in (2), form mesoporous material | template molecule | and TiO
2Gel " sandwich " structure;
(5) with gained " sandwich " structure intensification calcining, fragmentation in (4), demoulding is removed mesoporous material and template molecule, forms nano-photocatalyst.
3. nano-photocatalyst according to claim 2 is characterized in that: described mesoporous material is selected NACF or molecular sieve for use.
4. nano-photocatalyst according to claim 2 is characterized in that: the alkyl oxide of described titanium is selected isopropyl titanate, tetrabutyl titanate or isopropyl titanate for use.
5. nano-photocatalyst according to claim 2 is characterized in that: described alcohols solvent adopts ethanol.
6. nano-photocatalyst according to claim 2 is characterized in that: described inorganic acid adopts Bronsted acid.
7. nano-photocatalyst according to claim 2 is characterized in that: calcine in tube furnace in N in the step (5)
2Carry out in the atmosphere, calcining heat is 300~700 ℃.
8. the application of nano-photocatalyst according to claim 1 low concentration formaldehyde, benzene series thing in the degraded air.
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| CN102125877A (en) * | 2011-01-05 | 2011-07-20 | 江苏大学 | Method for preparing selectively degraded ciprofloxacin photocatalyst |
| CN103977775A (en) * | 2014-06-03 | 2014-08-13 | 吉首大学 | Preparation method and application of molecularly imprinted polymer for adsorbing formaldehyde in air |
| CN105289670A (en) * | 2015-10-28 | 2016-02-03 | 江苏大学 | Specific recognition SiO2/Ag3PO4@ZnFe2O4 inorganic imprint compound photocatalyst and preparing method thereof |
| CN106587282A (en) * | 2016-12-08 | 2017-04-26 | 上海纳米技术及应用国家工程研究中心有限公司 | Difunctional multi-template molecularly imprinted type photoelectric anode material and preparation method and application |
| CN110652868A (en) * | 2019-10-22 | 2020-01-07 | 上海创健环保科技有限公司 | Environment-friendly formaldehyde purification spray capable of releasing negative oxygen ions and preparation method thereof |
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| US7319038B2 (en) * | 2002-09-19 | 2008-01-15 | The Johns Hopkins University | Sensor for monitoring an analyte |
| US20050079506A1 (en) * | 2003-10-09 | 2005-04-14 | Eastman Kodak Company | Filled, biological microarray and method for use |
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| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102125877A (en) * | 2011-01-05 | 2011-07-20 | 江苏大学 | Method for preparing selectively degraded ciprofloxacin photocatalyst |
| CN102125877B (en) * | 2011-01-05 | 2012-12-19 | 江苏大学 | Method for preparing selectively degraded ciprofloxacin photocatalyst |
| CN103977775A (en) * | 2014-06-03 | 2014-08-13 | 吉首大学 | Preparation method and application of molecularly imprinted polymer for adsorbing formaldehyde in air |
| CN103977775B (en) * | 2014-06-03 | 2016-01-20 | 吉首大学 | The preparation method of the molecularly imprinted polymer of formaldehyde and application in a kind of absorbed air |
| CN105289670A (en) * | 2015-10-28 | 2016-02-03 | 江苏大学 | Specific recognition SiO2/Ag3PO4@ZnFe2O4 inorganic imprint compound photocatalyst and preparing method thereof |
| CN106587282A (en) * | 2016-12-08 | 2017-04-26 | 上海纳米技术及应用国家工程研究中心有限公司 | Difunctional multi-template molecularly imprinted type photoelectric anode material and preparation method and application |
| CN106587282B (en) * | 2016-12-08 | 2020-02-21 | 上海纳米技术及应用国家工程研究中心有限公司 | Double-functional multi-template molecularly imprinted photoelectric anode material and preparation and application thereof |
| CN110652868A (en) * | 2019-10-22 | 2020-01-07 | 上海创健环保科技有限公司 | Environment-friendly formaldehyde purification spray capable of releasing negative oxygen ions and preparation method thereof |
| CN110652868B (en) * | 2019-10-22 | 2022-04-05 | 上海创健环保科技有限公司 | Environment-friendly formaldehyde purification spray capable of releasing negative oxygen ions and preparation method thereof |
| CN114471695A (en) * | 2022-01-18 | 2022-05-13 | 安庆市长三角未来产业研究院 | Catalyst capable of efficiently degrading cyanogen-containing waste gas and preparation method and application thereof |
| CN114471695B (en) * | 2022-01-18 | 2023-07-11 | 安庆市长三角未来产业研究院 | Catalyst capable of efficiently degrading cyanide-containing waste gas and preparation method and application thereof |
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| CN100415365C (en) | 2008-09-03 |
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