CN109482242A

CN109482242A - Ni adulterates TiO2/ MOF-5 photochemical catalyst and preparation method thereof

Info

Publication number: CN109482242A
Application number: CN201811494788.0A
Authority: CN
Inventors: 向柏霖; 刘跃进; 朱璐; 陈桂
Original assignee: Huaihua University
Current assignee: Huaihua University
Priority date: 2018-12-07
Filing date: 2018-12-07
Publication date: 2019-03-19

Abstract

The present invention relates to a kind of Ni to adulterate TiO₂/ MOF-5 photochemical catalyst and preparation method thereof, the preparation method is the following steps are included: step 1: zinc nitrate, nickel nitrate, terephthalic acid (TPA), n,N-Dimethylformamide and triethylamine being mixed, after reacting 1-10h, solid is collected, washing is drying to obtain Ni doping MOF-5；Step 2: butyl titanate, glacial acetic acid, Ni doping MOF-5 and alcohol water mixed solvent being mixed, are stirred to react, to which after the reaction was completed, filtering collects gained filtrate and is aged, dries, calcining and adulterate TiO2/MOF-5 photochemical catalyst up to Ni.The Ni doping TiO2/MOF-5 photochemical catalyst that the above method is prepared has stronger water resistance, can effectively improve the application range of catalyst.

Description

Ni adulterates TiO2/ MOF-5 photochemical catalyst and preparation method thereof

Technical field

The present invention relates to catalysis material technical field, in particular to Ni adulterates TiO₂/ MOF-5 photochemical catalyst and its preparation Method.

Background technique

Photocatalysis technology, that is, semiconductor light-catalyst technology can be used to degradation of organic waste water, reducing heavy metal ion, net Change air, sterilization, antifog etc..Nano-titanium dioxide (TiO₂) it is used as a kind of photochemical catalyst, it is that a kind of N-shaped of function admirable is partly led Body material can make full use of solar energy, not only energy-efficient but also environmentally friendly, and show preferable light when reacting and stablize Property and higher reactivity, nontoxic, inexpensive are without secondary pollution, are a kind of current application prospect nanometers the most wide Functional material.

MOF-5 is a most typical representative in metal-organic framework complex family, is developed in metal organic complex With the meaning of milestone in history.MOF-5 is by 4 Zn²⁺With 1 O^2-[the Zn formed₄O]⁶⁺Inorganic group and organic group [O₂C-C-C₆H₄-CO₂]^2-The 3 D stereo rigid-skeleton formed with octahedral form connection, chemical basic unit are Zn₄O(BDC)₃.MOF-5 is a kind of very potential frame compound, and specific surface area and hole capacity rate are carried than common solid Body active carbon, zeolite, molecular sieve, silica are contour.But MOF-5 water resistance is bad, it is easy to hydrolyze, seriously should such urge The application of agent.

Summary of the invention

Based on this, it is necessary to provide a kind of potent Ni doping TiO with certain water resistance₂/ MOF-5 photochemical catalyst and Preparation method.

A kind of Ni doping TiO₂The preparation method of/MOF-5 photochemical catalyst, comprising the following steps:

Zinc nitrate, nickel nitrate, terephthalic acid (TPA), n,N-Dimethylformamide and triethylamine are mixed, after reacting 1-10h, Solid is collected, washing is drying to obtain Ni doping MOF-5；

Butyl titanate, glacial acetic acid, Ni doping MOF-5, glacial acetic acid and alcohol water mixed solvent are mixed, stirring is anti- It answers, to which after the reaction was completed, filtering collects gained filtrate and is aged, dries, calcining and adulterate TiO up to the Ni₂/ MOF-5 light is urged Agent.

Above-mentioned Ni adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst is by addition nickel nitrate, so that obtained MOF- Doped with nickel in 5, the water resistance of MOF-5 is effectively improved, and then improves obtained Ni doping TiO₂/ MOF-5 light is urged The application range of agent.And by using butyl titanate and MOF-5 (Ni) material as raw material in the above method, and it is aided with glacial acetic acid Accelerate tetrabutyl titanate hydrolysis, so that is generated is titania oxide supported on Ni doping MOF-5, being formed has preferable physical behavior Ni adulterates TiO₂/MOF-5。

In one embodiment, in the step 1, the molar ratio of the zinc nitrate and the nickel nitrate is 1: (0.5-3)；And/or；The molar ratio of the terephthalic acid (TPA) and the zinc nitrate is 1:(0.8-1.5).

By the control of zinc nitrate, nickel nitrate and terephthalic acid (TPA) in above-mentioned molar ratio range, can further it be promoted made The water resistance of the Ni doping MOF-5 obtained, and the specific surface area of obtained Ni doping MOF-5 can be improved, improve titanium oxide Load capacity.

In one embodiment, in the step 1, the n,N-Dimethylformamide (DMF) and the zinc nitrate It is (30-50) with the ratio between the quality sum of the nickel nitrate: 1.

In one embodiment, in the step 1, the zinc nitrate is zinc nitrate hexahydrate (Zn (NO₃)₂· 6H₂O), the nickel nitrate is Nickelous nitrate hexahydrate (Ni (NO₃)₂·6H₂O)。

In implementing wherein one, in the step 2, the temperature of the calcining is 200 DEG C -700 DEG C, calcination time 1- 4h。

By controlling temperature at 200 DEG C -700 DEG C, the photocatalysis efficiency of photochemical catalyst can be effectively improved.

By that within the above range, carbon dioxide conversion can be made at the rutile titania with more high catalytic activity temperature control Mine crystal form, and be conducive to such as C, H organic atoms in MOF-5 with substance (such as CO of volatile₂、H₂) etc. O forms are overflowed, Further enhance the catalytic activity of catalyst.

In implementing wherein one, in the step 2, the temperature of the calcining is 450 DEG C -700 DEG C.

In implementing wherein one, the mixed gas that the atmosphere of the calcining forms for oxygen and inert gas, and institute The volume ratio for stating oxygen and the inert gas is 1:(2-5).

By the way that such as C, H organic atoms can be conducive in the mixed gas for using oxygen and inert gas to form can wave Substance (such as CO of hair property₂、H₂) etc. O forms are overflowed, and MOF-5 material is made to retain MOF-5 in the form of metal oxide (such as ZnO) Skeleton structure, keep high permeability and high-specific surface area, and then enhance the load capacity of titanium dioxide.

In one embodiment, the inert gas includes nitrogen, helium and argon gas.

In one embodiment, in the step 2, by zinc nitrate, nickel nitrate, terephthalic acid (TPA), N, N- dimethyl The step of formamide and triethylamine mix the following steps are included:

Zinc nitrate, nickel nitrate and DMF are mixed, the terephthalic acid (TPA) (H is then added₂BDC), it is completely dissolved to solid Afterwards, the triethylamine (TEAC) is added.

In one embodiment, butyl titanate, glacial acetic acid, Ni doping MOF-5 material and alcohol water are mixed molten Agent mixing, the step of being stirred to react the following steps are included:

The alcohol water mixed solution is prepared, and adjusts pH value to pH value 2-4, obtains the first solution；

Butyl titanate, glacial acetic acid and ethyl alcohol are mixed, the second solution is formed；

The Ni is adulterated into MOF-5 and second solution mixes, obtains third solution；

First solution is added in the third solution and is uniformly mixed.

First butyl titanate and glacial acetic acid are mixed, is formed after the second solution and to be mixed to form the with Ni doping MOF-5 material Three solution, then the alcohol water mixed solution that pH is 2-4 is instilled in third solution, the localized rich of hydrolysis can be effectively improved in this way Degree, so that butyl titanate hydrolyzes rapidly in the moment that alcohol water mixed solution instills, and is supported on Ni doping MOF-5 material, Load capacity of the titanium oxide on Ni doping MOF-5 can be effectively improved, while obtained Ni adulterates TiO₂/ MOF-5 light is urged Agent has excellent physical behavior, can effectively improve unit mass Ni doping TiO₂The catalysis of/MOF-5 photochemical catalyst is imitated Rate.

In one embodiment, using the nitric acid tune pH to 2-4 of 4mol/L-6mol/L.

In implementing wherein one, in first solution, the volume ratio of the ethyl alcohol and the water is (1.5-3): 1.

In implementing wherein one, in second solution, the volume ratio of the glacial acetic acid and the ethyl alcohol is 1:(1.5- 8)。

In implementing wherein one, in second solution, the volume ratio of the glacial acetic acid and the ethyl alcohol is 1:(1.9- 4)。

In implementing wherein one, in second solution, the total volume and the titanium of both the glacial acetic acid and ethyl alcohol The ratio of the volume of sour four butyl esters is (2.5-4): 1.

In implementing wherein one, first solution was added in the third solution in the step of stirring evenly, by institute The first solution is stated to be added drop-wise in the third solution with the speed of 1-3 drop per second.

The Ni that above-mentioned preparation method is prepared adulterates TiO₂/ MOF-5 photochemical catalyst.

The Ni that above-mentioned preparation method is prepared adulterates TiO₂The MOF-5 that/MOF-5 photochemical catalyst is adulterated by using Ni, The water resistance of MOF-5 can be effectively improved, and then improves obtained Ni and adulterates TiO₂The applicable model of/MOF-5 photochemical catalyst It encloses.

Detailed description of the invention

Fig. 1 is the TiO of embodiment 1₂The XRD of/MOF-5 (Ni) (Zn: Ni=1: 1) catalyst is tested；

Fig. 2 is the TiO of embodiment 2₂The XRD of/MOF-5 (Ni) (Zn: Ni=1: 2) catalyst is tested；

Fig. 3 is the TiO of embodiment 1₂The electron microscope of/MOF-5 (Ni) (Zn: Ni=1: 1) catalyst；

Fig. 4 is the TiO of embodiment 2₂The electron microscope of/MOF-5 (Ni) (Zn: Ni=1: 2) catalyst；

Fig. 5 is the XRD comparison diagram of the 2 hours front and backs of water process MOF-5 in comparative example 1；

Fig. 6 is the Ni doping MOF-5 (Zn in embodiment 1²⁺: Ni²⁺=1:1) it is compared with the XRD of 2 hours front and backs of water process Figure；

Fig. 7 is the Ni doping MOF-5 (Zn in embodiment 2²⁺: Ni²⁺=1:2) it is compared with the XRD of 2 hours front and backs of water process Figure.

Specific embodiment

To facilitate the understanding of the present invention, below will to invention is more fully described, and give it is of the invention compared with Good embodiment.But the invention can be realized in many different forms, however it is not limited to embodiment described herein.Phase Instead, purpose of providing these embodiments is makes the disclosure of the present invention more thorough and comprehensive.

Unless otherwise defined, all technical and scientific terms used herein and belong to technical field of the invention The normally understood meaning of technical staff is identical.Term as used herein in the specification of the present invention is intended merely to description tool The purpose of the embodiment of body, it is not intended that in the limitation present invention.Term as used herein "and/or" includes one or more phases Any and all combinations of the listed item of pass.

Specific embodiment is set forth below, and the present invention will be described.

Embodiment 1

Step 1: the synthesis of Ni doping MOF-5, first by the Zn (NO of 0.61g₃)₂·6H₂O、0.6gNi(NO₃)₂·6H₂O It is contained in beaker with 40ml n,N-Dimethylformamide (DMF), at room temperature by 0.34g terephthalic acid (TPA) (H₂BDC it) is added to In beaker, be stirred continuously, after waiting solid to be completely dissolved after, then 1.4mL triethylamine TEAC is added in mixed solution, no Disconnected stirring, stirring make it react about 3h, obtain white solid, take out press filtration, are washed 3-4 times, are removed with DMF during taking out press filtration Remove unreacted inorganic salts and organic acid in product.Finally sample is put into baking oven and is dried.Dress sample is ground after drying.

Step 2: taking 4.5ml distilled water, the mixing of 8.9ml dehydrated alcohol is 3 with the 5mol/L nitric acid solution tune pH prepared, The first solution is made；4.5ml glacial acetic acid is added in 26.7ml dehydrated alcohol, with vigorous stirring, by four fourth of 8.9ml metatitanic acid Ester is slowly added into above-mentioned solution, forms shallow yellow transparent solution, forms the second solution；

Ni doping MOF-5 material 0.6546g is weighed, Ni doping MOF-5 material is slowly poured into the second solution, is allowed to It is uniformly mixed, forms third solution；With vigorous stirring, the first solution is slowly added into the with the speed of 1 drop per second In three solution, stopping stirring being dripped.The collosol and gel that reaction generates is filtered under diminished pressure, and is aged under room temperature, then by product It is put into baking oven and is dried for 100 DEG C.Dried product (being in granular form) is ground, product is then put into high temperature furnace Middle calcining is allowed to lead to oxygen in 500 DEG C of calcining 2h, calcination process and nitrogen ratios is the mixed gas of 1:2 to get embodiment 1 Ni adulterates TiO₂/ MOF-5 photochemical catalyst.The XRD test chart of embodiment 1 is referring to Fig. 1, and electron microscope is referring to Fig. 3.

Embodiment 2

Step 1: the synthesis of Ni doping MOF-5, first by the Zn (NO of 0.41g₃)₂·6H₂O、0.8gNi(NO₃)₂·6H₂O It is contained in beaker with 40ml n,N-Dimethylformamide (DMF), at room temperature by 0.34g terephthalic acid (TPA) (H₂BDC it) is added to In beaker, be stirred continuously, after waiting solid to be completely dissolved after, then 1.4mL triethylamine TEAC is added in mixed solution, no Disconnected stirring, stirring make it react about 3h, obtain white solid, take out press filtration, are washed 3-4 times, are removed with DMF during taking out press filtration Remove unreacted inorganic salts and organic acid in product.Finally sample is put into baking oven and is dried.Dress sample is ground after drying.

Ni doping MOF-5 material 0.6546g is weighed, Ni doping MOF-5 material is slowly poured into the second solution, is allowed to It is uniformly mixed, forms third solution；With vigorous stirring, the first solution is slowly added into the with the speed of 1 drop per second In three solution, stopping stirring being dripped.The collosol and gel that reaction generates is filtered under diminished pressure, and is aged under room temperature, then by product It is put into baking oven and is dried for 100 DEG C.Dried product (being in granular form) is ground, product is then put into high temperature furnace Middle calcining is allowed to lead to oxygen in 500 DEG C of calcining 2h, calcination process and nitrogen ratios is the mixed gas of 1:2 to get embodiment 2 Ni adulterates TiO₂/ MOF-5 photochemical catalyst, referring to fig. 2, electron microscope is referring to fig. 4 for the XRD test chart of embodiment 2.

Embodiment 3

It is substantially the same manner as Example 1, the difference is that, the calcination temperature in second step becomes 300 DEG C.Obtain embodiment 3 Ni adulterates TiO₂/ MOF-5 photochemical catalyst.

Comparative example 1

It is substantially the same manner as Example 1, the difference is that, it is added without Ni (NO₃)₂·6H₂O.Obtain the TiO of comparative example 1₂/ MOF-5 photochemical catalyst.

Photocatalytic Degradation of Formaldehyde test

The Ni of embodiment 1- embodiment 3 and comparative example 1 is adulterated into TiO₂/ MOF-5 photochemical catalyst carries out formaldehyde photocatalysis drop Solution test；

Test principle: TiO is carried out in homemade photocatalysis experimental box₂Formaldehyde degradation by photocatalytic oxidation process experiment, passes through ultraviolet light Catalyst is irradiated to realize the formaldehyde in degradation aqueous solution in source, and the reactivity of photochemical catalyst is by measuring illumination after a certain period of time The degradation rate of formaldehyde is evaluated.

Test method: 2mL formaldehyde stock solution and 100mL water are accurately pipetted in reaction tank, is shaken up.Accurately pipette 2.5mL Solution absorbance to be measured in test tube.Catalyst 0.25g is weighed in reaction tank, after shaking up, is put into reactor, is opened ultraviolet Lamp carries out illumination degrading 5h, wherein takes a sample per hour, first jog reaction tank is answered before taking, be uniformly mixed solution, then again A moment is stood, then pipettes about 5mL solution in absorbance to be measured in test tube with pipette.Meanwhile doing a blank that catalyst is not added Comparative experiments.

Deionized water will be added to 25mL equipped with the test tube of sampling liquid, while do a blank test, sample is replaced with 25mL water, Again plus 2.5mL acetylacetone,2,4-pentanedione solution, it shakes up, the heating water bath 10min in 909100 DEG C, takes out cooling.At wavelength 414nm, Using water as reference measurement absorbance.The light absorption value substitution resulting formula of standard curve can be calculated into concentration of formaldehyde, recycled Formula 1.3 calculates degradation rate D%:

A in formula₀, A_tAbsorbance respectively before reaction with solution when reacting t moment；Finally production degradation rate and time are bent Line compares the degradation property of catalyst, and compares with blank test, test result is as follows table 1.

Table 1

From embodiment 1- embodiment 3 it can be seen that the Ni that the above method is prepared adulterates TiO₂/ MOF-5 photochemical catalyst tool There is stronger photocatalysis.

Water resistance experiment

It respectively takes the MOF-5 (Ni) of 0.5gMOF-5 or each doping ratio to be placed in 80 DEG C of stirred in water bath to handle 2 hours, mistake It is dried in vacuo 2 hours at 80 DEG C after filter, with XRD analysis, as a result as illustrated in figs. 5-7.Wherein, Fig. 5 is the MOF-5 in comparative example 1 With the XRD comparison diagram of 2 hours front and backs of water process, Fig. 6 is the Ni doping MOF-5 (Zn in embodiment 1²⁺: Ni²⁺=1:1) at water The XRD comparison diagram of 2 hours front and backs is managed, Fig. 7 is the Ni doping MOF-5 (Zn in embodiment 2²⁺: Ni²⁺=1:2) it is small with water process 2 The XRD comparison diagram of Shi Qianhou.

As shown in Figure 5, at 80 DEG C after water process 2 hours, peak position and peak intensity change greatly MOF-5, and 7 degree, 13 degree 14 Characteristic peak near degree disappears, the slightly left avertence shifting of the characteristic peaks near 10 degree, illustrate to hydrolyze it is obvious, changes in crystal structure compared with Greatly.Work as Zn as shown in Figure 6²⁺: Ni²⁺When for 1:1, MOF-5 (Ni) is at 80 DEG C after water process 2 hours, map peak position and peak intensity Also there is large change, but characteristic peak is all retained near 9 degree, 16 degree, 18 degree, crystal form retains relatively complete, explanation MOF-5 (Ni) (1:1) water resistance will be got well with respect to MOF-5.As shown in Figure 7, work as Zn²⁺:Ni²⁺When for 1:2, MOF-5 (Ni) map peak Less, most of characteristic peak all retains, and illustrates that MOF-5 (Ni) (1:2) water resistance is more preferable at this time for position and peak intensity variation.Thus As it can be seen that water resistance is enhanced as MOF-5 as doping nickel content improves.

Each technical characteristic of embodiment described above can be combined arbitrarily, for simplicity of description, not to above-mentioned reality It applies all possible combination of each technical characteristic in example to be all described, as long as however, the combination of these technical characteristics is not deposited In contradiction, all should be considered as described in this specification.

The embodiments described above only express several embodiments of the present invention, and the description thereof is more specific and detailed, but simultaneously It cannot therefore be construed as limiting the scope of the patent.It should be pointed out that coming for those of ordinary skill in the art It says, without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to protection of the invention Range.Therefore, the scope of protection of the patent of the invention shall be subject to the appended claims.

Claims

1. a kind of Ni adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which comprises the following steps:

Step 1: zinc nitrate, nickel nitrate, terephthalic acid (TPA), n,N-Dimethylformamide and triethylamine being mixed, 1-10h is reacted Afterwards, solid is collected, washing is drying to obtain Ni doping MOF-5；

Step 2: butyl titanate, glacial acetic acid, Ni doping MOF-5 and alcohol water mixed solvent being mixed, are stirred to react, to anti- After the completion of answering, filtering collects gained filtrate and is aged, dries, calcining and adulterate TiO up to the Ni₂/ MOF-5 photochemical catalyst.

2. Ni according to claim 1 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described In step 1, the molar ratio of the zinc nitrate and the nickel nitrate is 1:(0.5-3)；And/or

The molar ratio of the terephthalic acid (TPA) and the zinc nitrate is 1:(0.8-1.5).

3. Ni according to claim 1 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described In step 2, the temperature of the calcining is 200 DEG C -700 DEG C, calcination time 1-4h.

4. Ni according to claim 3 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described to forge The atmosphere of burning is the mixed gas that oxygen and inert gas form, and the volume ratio of the oxygen and the inert gas is 1:(2-5)。

5. Ni according to claim 1-4 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, feature exist In in the step 2, by the specific of butyl titanate, glacial acetic acid, Ni doping MOF-5 and the mixing of alcohol water mixed solvent Operation are as follows:

First solution is added in the third solution and is uniformly mixed.

6. Ni according to claim 5 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described In first solution, the volume ratio of the ethyl alcohol and the water is (1.5-3): 1.

7. Ni according to claim 5 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described In second solution, the volume ratio of the glacial acetic acid and the ethyl alcohol is 1:(1.5-8).

8. Ni according to claim 5 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that described In second solution, the ratio of the volume of the total volume and butyl titanate of both the glacial acetic acid and ethyl alcohol is (2.5-4): 1。

9. Ni according to claim 5 adulterates TiO₂The preparation method of/MOF-5 photochemical catalyst, which is characterized in that will be described First solution was added in the third solution in the step of stirring evenly, and first solution is dripped with the speed of 1-3 drop per second It is added in the third solution.

10. the Ni that the described in any item preparation methods of claim 1-9 are prepared adulterates TiO₂/ MOF-5 photochemical catalyst.