CN108101009A - Titanium nitride nanopower high pressure liquid-phase synthesis process - Google Patents

Abstract

The invention discloses a kind of titanium nitride nanopower high pressure liquid-phase synthesis process, belong to titanium nitride preparing technical field.The preparation method of the present invention comprises the following steps；Step A：Prepare reaction promoter, liquefied ammonia is added in into reaction promoter, treat liquefied ammonia with after reaction promoter layering, titanium tetrachloride being added in into reaction promoter, is chemically reacted under temperature A, pressure B, reaction is washed after terminating, and obtains nitridation titanium precursors；Step B：The nitridation titanium precursors that step A is obtained are roasted, obtain titanium nitride nanopower.Wherein：35 DEG C of ＜ temperature A≤30 DEG C, pressure B are 0.2MPa~1.5MPa.The preparation method of the present invention reduces energy consumption, and production cost is relatively low, the nitride powder purity of acquisition is high, particle uniformly, narrow particle size distribution, grain size be up to nanoscale.

Description

Titanium nitride nanopower high pressure liquid-phase synthesis process

Technical field

The invention belongs to titanium nitride preparing technical field, more specifically to a kind of titanium nitride nanopower high pressure liquid It is combined to method.

Background technology

Nitride powder is the base stock for preparing titanium nitride ceramic, is the key that influence titanium nitride ceramic performance, wherein Nanoscale nitride powder is in black, and micron order nitride powder is in yellow.Titanium nitride has fusing point high, and chemical stability is good, The good physicochemical properties such as hardness is big, and conductive, heat conduction and optical property are good, make it suffer from very important use in every field On the way, especially in terms of cermet field and cash equivalent furnishing fields.Industry is more and more to the demand of titanium nitride powder, Titanium nitride is not only cheap as coating price but also wear resistant corrosion resistant, its a lot of performances are better than vacuum coating.Titanium nitride ceramic is A kind of high-performance ceramic, it has excellent physical and chemical performance, such as high intensity, high rigidity, high temperature resistant, wear-resistant, acid and alkali-resistance It corrodes, in addition with series of advantages such as good electric conductivity, thermal conductivity, is widely used.

Nano titanium nitride powder refers to nitride powder of its crystallite dimension within 100 nanometers, and micron order is replaced with it Nitride powder, which makees raw material, can reduce the sintering temperature of titanium nitride ceramic, improve sintering character；Enhancing phase is used it as, can be had Effect improves metal, the intensity and toughness of ceramic matrix.Moreover, because particle is small, large specific surface area, can be dispersed in other materials Conductive network is formed, greatly improves the electric conductivity of composite material.So Nano titanium nitride, which is one kind, has broad prospect of application Material.

With the intensification both at home and abroad to titanium nitride research, the method for preparing titanium nitride is also more and more.Such as patent discloses Number：CN 101298321A, publication date：On November 05th, 2008, invention and created name are：A kind of system of titanium nitride nanopower Preparation Method, preparation method is passed through ammonia using nanotubed titanic acid as titanium source in tube furnace disclosed in this application, from room temperature To 800-1000 DEG C of progress nitridation reaction 0.5-24H, up to titanium nitride nanopower after cooling.

At present, the preparation process of titanium nitride mainly has metallic titanium powder or TiH₂Direct nitridation method, TiO₂Carbothermal reduction-nitridation Method, microwave carbothermal reduction method, chemical vapour deposition technique, self-propagating high-temperature synthesis, mechanical alloying method, SiCl₄Liquid phase method etc.. Traditional solid phase method：Titanium nitride powder, this kind of method required temperature can be made in the processing of nitrogen high temperature in Titanium or titantium hydride It is higher, and under high temperature titanium nitride reunite caking, particle is coarse, differed with the required nanoscale titanium nitride in present market compared with Greatly, so also needing to Mechanical Crushing, total energy consumption is higher.Vapor phase method is the new technology to grow up nearest decades：With four chlorinations Titanium, ammonia, hydrogen, nitrogen are raw material, carry out chemical reaction in the reactor and prepare titanium nitride powder, this kind of method reaction compared with Soon, but reaction process is not easily controlled, and reaction temperature is higher, energy consumption is higher.

In conclusion the method that above method prepares nitride powder, all there are it is different degrees of the defects of, therefore need to research and develop Go out a kind of preparation method of low-cost titanium nitride nanopower, to overcome drawbacks described above.

The content of the invention

1. technical problems to be solved by the inivention

It is an object of the invention to overcome above deficiency of the prior art, provide a kind of titanium nitride nanopower and its Preparation method, the preparation method reduce energy consumption, and production cost is relatively low, the nitride powder purity of acquisition is high, particle uniformly, grain Narrowly distributing, grain size are spent up to nanoscale.

2. technical solution

In order to achieve the above objectives, technical solution provided by the invention is：

The titanium nitride nanopower high pressure liquid-phase synthesis process of the present invention, comprises the following steps：

Step A：Prepare reaction promoter, liquefied ammonia is added in into reaction promoter, after treating the layering of liquefied ammonia and reaction promoter, to anti- It answers and titanium tetrachloride is added in auxiliary agent, chemically reacted under temperature A, pressure B, reaction is washed after terminating, and obtains nitrogen Change titanium precursors；

Step B：The nitridation titanium precursors that step A is obtained are roasted, obtain titanium nitride nanopower.

As further improvement of the present invention, the reaction promoter for nonpolar non-aromatic hydrocarbons or one kind in halogenated hydrocarbons or The a variety of mixing of person.

As further improvement of the present invention, wherein, -35 DEG C of ＜ temperature A≤30 DEG C.

As further improvement of the present invention, the pressure B is 0.2MPa~1.5MPa.

As further improvement of the present invention, in step A chemical reaction start before, control titanium tetrachloride, liquefied ammonia and The mass ratio of reaction promoter is 1：2~4：2~6.

As further improvement of the present invention, the temperature roasted in step B is 400 DEG C~1300 DEG C.

As further improvement of the present invention, the time roasted in step B is 400 DEG C~1300 DEG C.

As further improvement of the present invention, roasted in step B under protective atmosphere.

As further improvement of the present invention, the protective atmosphere is one kind in nitrogen, helium or argon gas.

As further improvement of the present invention, the reaction promoter is toluene or dichloromethane or toluene and dichloromethane Mixture.

3. advantageous effect

Using technical solution provided by the invention, compared with prior art, there is following remarkable result：

(1) present invention is using the synthetically prepared titanium nitride nanopower of liquid phase method, and reaction is controllable, and reaction time is short, reaction temperature Spend relatively mild, therefore energy consumption of reaction is relatively low, and technical process is simple and without large scale equipment, and production cost is relatively low, can industry greatly Metaplasia is produced, and react gained nitride powder purity is high, particle uniformly, narrow particle size distribution, grain size up to nanoscale, future will Progressively substitute traditional titanium nitride preparation method, there are bright prospects, and reaction promoter used in reacting, liquefied ammonia is recyclable follows Ring uses.

(2) present invention is using one or more kinds of mixing in nonpolar non-aromatic hydrocarbons or halogenated hydrocarbons as reaction promoter, into Titanium tetrachloride is dissolved in more than reaction promoter during row chemical reaction, and titanium tetrachloride can be prevented to be dissolved in other solvents and give birth to Into similar to [(C₆R₆)TiCl₃]⁺Complex, so as to avoid that titanium nitride nanopower purity is caused when introducing carbon to drop The phenomenon that low；Further, when step A is chemically reacted, which can dissolve each other with titanium tetrachloride, and titanium tetrachloride can quilt The reaction promoter wraps up, and the reaction promoter of titanium tetrachloride outer layer can inhibit growing up for titanium nitride precursor in chemical reaction, from And be conducive to obtain nanoscale nitridation titanium valve.

(3) in the present invention, the chemical reaction of step A is carried out in -35 DEG C~30 DEG C of relatively mild temperature, at this time in liquefied ammonia Ammonia it is readily volatilized (boiling point of liquefied ammonia be 33.42 DEG C), correspondingly, maintaining the high compression ring of 0.2MPa~1.5MPa in step A Border so that the ammonia in liquefied ammonia is not volatile, so as to effectively maintain liquid-phase chemical reaction；Meanwhile the chemical reaction of step A It is carried out in -35 DEG C~30 DEG C of relatively mild temperature, reduces to maintain the low temperature environment of the chemical reaction of step A and consume The energy reduces energy consumption, reduces production cost.

Description of the drawings

It in order to illustrate the technical solution of the embodiments of the present invention more clearly, below will be to needed in the embodiment attached Figure is briefly described, it should be understood that the following drawings illustrates only certain embodiments of the present invention, therefore is not construed as pair The restriction of scope, for those of ordinary skill in the art, without creative efforts, can also be according to this A little attached drawings obtain other relevant attached drawings.

Fig. 1 is the flow chart of titanium nitride nanopower high pressure liquid-phase synthesis process in the present invention.

Specific embodiment

To make the purpose, technical scheme and advantage of the embodiment of the present invention clearer, below in conjunction with the embodiment of the present invention In attached drawing, the technical solution in the embodiment of the present invention is clearly and completely described, it is clear that described embodiment is Part of the embodiment of the present invention, instead of all the embodiments.Therefore, the embodiment of the present invention to providing in the accompanying drawings below Detailed description be not intended to limit the scope of claimed invention, but be merely representative of the present invention selected embodiment. Based on the embodiments of the present invention, what those of ordinary skill in the art were obtained without creative efforts is all Other embodiment belongs to the scope of protection of the invention.

To further appreciate that present disclosure, the present invention is described in detail in conjunction with the accompanying drawings and embodiments.

Embodiment 1

With reference to figure 1, a kind of titanium nitride nanopower high pressure liquid-phase synthesis process comprises the following steps：

Step A：Using toluene as reaction promoter, liquefied ammonia is added in into toluene, after treating that liquefied ammonia stablizes layering with toluene, to first Titanium tetrachloride is added in benzene and is chemically reacted under conditions of -34 DEG C, 0.2MPa, reaction is washed after terminating, and is obtained To nitridation titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:2:6。

Step B：The nitridation titanium precursors that step A is obtained are roasted under nitrogen protective atmosphere, calcination temperature is 400 DEG C, roasting time control finally obtains titanium nitride nanopower in 150min, and titanium nitride nanopower is averaged after testing Grain size is 40nm, average grain size 15nm.

In the present embodiment, step A chemical reactions are washed, purified after terminating, and are concretely comprised the following steps：It is anti-by liquefied ammonia After backwashing washs filtering, extracts remaining ammonium chloride, filters out remaining reaction promoter, obtains pure nitridation titanium precursors；It is pure Liquid phase after change is separated by distillation out pure ammonia, reaction promoter and ammonium chloride, recycles.

In the present invention, the chemical reaction of step A is specially TiCl₄+6NH₃=Ti (NH)₂↓+4NH4Cl, in closed reaction It is chemically reacted in container, displaces the air in reaction vessel repeatedly using protective gas, make to be in reaction vessel Anhydrous and oxygen-free state, and it is 0.2MPa~1.5MPa to maintain pressure in reaction vessel, and temperature can be realized at -35 DEG C~30 DEG C Effecting reaction effectively reduces the energy consumption.

Embodiment 2

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using toluene as reaction promoter, liquefied ammonia is added in into toluene, after treating that liquefied ammonia stablizes layering with toluene, to first Titanium tetrachloride is added in benzene and is chemically reacted under conditions of -20 DEG C, 0.3Mpa, reaction is washed after terminating, and is obtained To nitridation titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:4:2。

Step B：The nitridation titanium precursors that step A is obtained are roasted under helium protective atmosphere, calcination temperature is 800 DEG C, roasting time is controlled in 60min, finally obtains titanium nitride nanopower, after testing the average grain of titanium nitride nanopower Footpath is 70nm, average grain size 20nm.

Embodiment 3

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using toluene as reaction promoter, liquefied ammonia is added in into toluene, after treating that liquefied ammonia stablizes layering with toluene, to first Titanium tetrachloride is added in benzene and is chemically reacted under conditions of -10 DEG C, 0.4MPa, reaction is washed after terminating, and is obtained To nitridation titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:3:5。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1000 DEG C, roasting time control finally obtains titanium nitride nanopower in 60min, and titanium nitride nanopower is averaged after testing Grain size is 200nm, average grain size 60nm.

Embodiment 4

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using toluene as reaction promoter, liquefied ammonia is added in into toluene, after treating that liquefied ammonia stablizes layering with toluene, to first Titanium tetrachloride is added in benzene and is chemically reacted under conditions of 10 DEG C, 0.6MPa, reaction is washed after terminating, and is obtained Nitrogenize titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1: 2.5:4。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1200 DEG C, roasting time control finally obtains titanium nitride nanopower in 80min, and titanium nitride nanopower is averaged after testing Grain size is 300nm, average grain size 100nm.

Embodiment 5

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using toluene as reaction promoter, liquefied ammonia is added in into toluene, after treating that liquefied ammonia stablizes layering with toluene, to first Titanium tetrachloride is added in benzene and is chemically reacted under conditions of 20 DEG C, 1.5MPa, reaction is washed after terminating, and is obtained Nitrogenize titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1: 3.5:3。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1300 DEG C, roasting time control finally obtains titanium nitride nanopower in 60min, and titanium nitride nanopower is averaged after testing Grain size is 350nm, average grain size 100nm.

Embodiment 6

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using dichloromethane as reaction promoter, liquefied ammonia is added in into dichloromethane, treats that liquefied ammonia is stablized with dichloromethane After layering, titanium tetrachloride is added in into dichloromethane and is chemically reacted under conditions of -34 DEG C, 0.2MPa, reaction knot It is washed after beam, obtains nitridation titanium precursors；Wherein, before chemical reaction starts, control titanium tetrachloride, liquefied ammonia and reaction The mass ratio of auxiliary agent is 1:2:6.

Step B：The nitridation titanium precursors that step A is obtained are roasted under nitrogen protective atmosphere, calcination temperature is 800 DEG C, roasting time control finally obtains titanium nitride nanopower in 150min, and titanium nitride nanopower is averaged after testing Grain size is 80nm, average grain size 40nm.

Embodiment 7

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using dichloromethane as reaction promoter, liquefied ammonia is added in into dichloromethane, treats that liquefied ammonia is stablized with dichloromethane After layering, titanium tetrachloride is added in into dichloromethane and is chemically reacted under conditions of -20 DEG C, 0.3Mpa, reaction knot It is washed after beam, obtains nitridation titanium precursors；Wherein, before chemical reaction starts, control titanium tetrachloride, liquefied ammonia and reaction The mass ratio of auxiliary agent is 1:4:2.

Step B：The nitridation titanium precursors that step A is obtained are roasted under helium protective atmosphere, calcination temperature is 900 DEG C, roasting time control finally obtains titanium nitride nanopower in 120min, and titanium nitride nanopower is averaged after testing Grain size is 100nm, average grain size 50nm.

Embodiment 8

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using dichloromethane as reaction promoter, liquefied ammonia is added in into dichloromethane, treats that liquefied ammonia is stablized with dichloromethane After layering, titanium tetrachloride is added in into dichloromethane and is chemically reacted under conditions of -10 DEG C, 0.4MPa, reaction knot It is washed after beam, obtains nitridation titanium precursors；Wherein, before chemical reaction starts, control titanium tetrachloride, liquefied ammonia and reaction The mass ratio of auxiliary agent is 1:3:5.

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1000 DEG C, roasting time control finally obtains titanium nitride nanopower in 60min, and titanium nitride nanopower is averaged after testing Grain size is 150nm, average grain size 80nm.

Embodiment 9

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using dichloromethane as reaction promoter, liquefied ammonia is added in into dichloromethane, treats that liquefied ammonia is stablized with dichloromethane After layering, titanium tetrachloride is added in into dichloromethane and is chemically reacted under conditions of 10 DEG C, 0.8MPa, reaction terminates It is washed afterwards, obtains nitridation titanium precursors；Wherein, before chemical reaction starts, control titanium tetrachloride, liquefied ammonia and reaction help The mass ratio of agent is 1:2.5:4.

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1200 DEG C, roasting time control finally obtains titanium nitride nanopower in 60min, and titanium nitride nanopower is averaged after testing Grain size is 160nm, average grain size 90nm.

Embodiment 10

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using dichloromethane as reaction promoter, liquefied ammonia is added in into dichloromethane, treats that liquefied ammonia is stablized with dichloromethane After layering, titanium tetrachloride is added in into dichloromethane and is chemically reacted under conditions of 30 DEG C, 1.3MPa, reaction terminates It is washed afterwards, obtains nitridation titanium precursors；Wherein, before chemical reaction starts, control titanium tetrachloride, liquefied ammonia and reaction help The mass ratio of agent is 1:3.5:3.

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1300 DEG C, roasting time control finally obtains titanium nitride nanopower in 30min, and titanium nitride nanopower is averaged after testing Grain size is 140nm, average grain size 80nm.

Embodiment 11

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using the mixture of toluene and dichloromethane as reaction promoter, add into the mixture of toluene and dichloromethane Enter liquefied ammonia, after treating that liquefied ammonia is layered with the stabilized with mixture of toluene and dichloromethane, into the mixture of toluene and dichloromethane It adds in titanium tetrachloride and is chemically reacted under conditions of -34 DEG C, 0.2MPa, reaction is washed after terminating, and obtains nitrogen Change titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:2: 6。

Step B：The nitridation titanium precursors that step A is obtained are roasted under nitrogen protective atmosphere, calcination temperature is 800 DEG C, roasting time control finally obtains titanium nitride nanopower in 150min, and titanium nitride nanopower is averaged after testing Grain size is 100nm, average grain size 60nm.

Embodiment 12

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using the mixture of toluene and dichloromethane as reaction promoter, add into the mixture of toluene and dichloromethane Enter liquefied ammonia, after treating that liquefied ammonia is layered with the stabilized with mixture of toluene and dichloromethane, into the mixture of toluene and dichloromethane It adds in titanium tetrachloride and is chemically reacted under conditions of -20 DEG C, 0.3Mpa, reaction is washed after terminating, and obtains nitrogen Change titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:4: 2。

Step B：The nitridation titanium precursors that step A is obtained are roasted under helium protective atmosphere, calcination temperature is 900 DEG C, roasting time control finally obtains titanium nitride nanopower in 120min, and titanium nitride nanopower is averaged after testing Grain size is 90nm, average grain size 55nm.

Embodiment 13

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using the mixture of toluene and dichloromethane as reaction promoter, add into the mixture of toluene and dichloromethane Enter liquefied ammonia, after treating that liquefied ammonia is layered with the stabilized with mixture of toluene and dichloromethane, into the mixture of toluene and dichloromethane It adds in titanium tetrachloride and is chemically reacted under conditions of -10 DEG C, 0.4MPa, reaction is washed after terminating, and obtains nitrogen Change titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:3: 5。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1000 DEG C, roasting time control finally obtains titanium nitride nanopower in 100min, and titanium nitride nanopower is averaged after testing Grain size is 160nm, average grain size 100nm.

Embodiment 14

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using the mixture of toluene and dichloromethane as reaction promoter, add into the mixture of toluene and dichloromethane Enter liquefied ammonia, after treating that liquefied ammonia is layered with the stabilized with mixture of toluene and dichloromethane, into the mixture of toluene and dichloromethane It adds in titanium tetrachloride and is chemically reacted under conditions of 10 DEG C, 0.5MPa, reaction is washed after terminating, and is nitrogenized Titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:2.5: 4。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1200 DEG C, roasting time control finally obtains titanium nitride nanopower in 80min, and titanium nitride nanopower is averaged after testing Grain size is 200nm, average grain size 90nm.

Embodiment 15

A kind of titanium nitride nanopower high pressure liquid-phase synthesis process, comprises the following steps：

Step A：Using the mixture of toluene and dichloromethane as reaction promoter, add into the mixture of toluene and dichloromethane Enter liquefied ammonia, after treating that liquefied ammonia is layered with the stabilized with mixture of toluene and dichloromethane, into the mixture of toluene and dichloromethane It adds in titanium tetrachloride and is chemically reacted under conditions of 30 DEG C, 1.5MPa, reaction is washed after terminating, and is nitrogenized Titanium precursors；Wherein, before chemical reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1:3.5: 3。

Step B：The nitridation titanium precursors that step A is obtained are roasted under argon gas protective atmosphere, calcination temperature is 1300 DEG C, roasting time control finally obtains titanium nitride nanopower in 60min, and titanium nitride nanopower is averaged after testing Grain size is 300nm, average grain size 95nm.

Schematically the present invention and embodiments thereof are described above, this describes no restricted, institute in attached drawing What is shown is also one of embodiments of the present invention, and actual structure is not limited thereto.So if common skill of this field Art personnel are enlightened by it, without departing from the spirit of the invention, are not inventively designed and the technical solution Similar frame mode and embodiment, are within the scope of protection of the invention.

Claims (10)

1. titanium nitride nanopower high pressure liquid-phase synthesis process, which is characterized in that comprise the following steps：

Step A：Prepare reaction promoter, liquefied ammonia is added in into reaction promoter, treat liquefied ammonia with after reaction promoter layering, being helped to reaction Titanium tetrachloride is added in agent, is chemically reacted under temperature A, pressure B, reaction is washed after terminating, and obtains titanium nitride Presoma；

Step B：The nitridation titanium precursors that step A is obtained are roasted, obtain titanium nitride nanopower.

2. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 1, which is characterized in that the reaction helps Agent is one or more kinds of mixing in nonpolar non-aromatic hydrocarbons or halogenated hydrocarbons.

3. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 1, which is characterized in that wherein, -35 DEG C ＜ temperature A≤30 DEG C.

4. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 3, which is characterized in that the pressure B For 0.2MPa~1.5MPa.

5. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 4, which is characterized in that change in step A Before reaction starts, the mass ratio for controlling titanium tetrachloride, liquefied ammonia and reaction promoter is 1：2~4：2~6.

6. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 5, which is characterized in that roasted in step B The temperature of burning is 400 DEG C~1300 DEG C.

7. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 6, which is characterized in that roasted in step B The time of burning is 20min~150min.

8. the titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 1~7 any one, feature exist In being roasted in step B under protective atmosphere.

9. titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 8, which is characterized in that the protectiveness Atmosphere is one kind in nitrogen, helium or argon gas.

10. the titanium nitride nanopower high pressure liquid-phase synthesis process according to claim 1~7 any one, feature exist In the reaction promoter is toluene or dichloromethane or the mixture of toluene and dichloromethane.