CN101289182A - Method for preparing carbon nano-tubes by gas induce and products produced thereby - Google Patents

Abstract

The invention discloses a method for preparing carbon nanotube by air current inducement and a product thereof, which pertain to the technical filed of carbon nanotube. The method of the invention prepares carbon nanotube by a chemical vapor deposition method and controls the growth orientation of the carbon nanotube by arranging an air current obstructing object to change the advection flow pattern of the reaction air current that flows above a substrate. More particularly, the method of the invention can be implemented by the steps as follows: a) the air current obstructing object is arranged in a reaction container according to the target orientation of the carbon nanotube; b) reaction gas is piped into the reaction container in inert environment and reacts on the substrate at the reaction temperature, and the carbon nanotube is produced; c) the carbon nanotube produced is cooled in inert environment, and the goal-oriented carbon nanotube is obtained. The invention also requests the protection of the carbon nanotube prepared by the method. The carbon nanotube prepared by the method of the invention has controllable orientation and high concentration, and has broad application prospect.

Description

A kind of air-flow is induced method for preparing carbon nanotube and products thereof

Technical field

The present invention relates to a kind of preparation method of carbon nanotube, specifically, the present invention relates to a kind of employing chemical Vapor deposition process, preparation is orientated the method for controlled carbon nanotube under the inducing of reaction gas flow, and the controlled carbon nanotube of orientation of this method preparation, belong to the carbon nanotube technology field.

Background technology

Nanosecond science and technology have become of paramount importance science and technology in 21 century, and from the chemistry to physics, from the electronics to machinery, from the energy to the biomedicine, every field has caused that all people pay close attention to widely, and it has begun to come into gradually life.In numerous materials in the nanometer world, carbon nanotube is undoubtedly star wherein.Since 1991, Japanese scientist professor Iijima represented this unique nano material of carbon nanotube to since the common people, and the preparation of carbon nanotube, character and applied research have all obtained great advance.Some achievements in research wherein to scientific technological advance from now on, all can produce wide and far-reaching influence.

Carbon nanotube is seamless, the hollow tubular structure that is curled into by the Graphene lamella.Can be divided into Single Walled Carbon Nanotube and multi-walled carbon nano-tubes two big classes according to the tube wall Graphene number of plies.Because the atom of carbon nanotube uniqueness is arranged and electronic band structure, the special space, machinery, electronics, calorifics and the optical property that cause it to have, all there is potential to use in a lot of fields, such as Field Emission Display, field-effect transistor, photodiode, permanent memory, chemistry and biosensor, Scanning Probe Microscopy, transparent conductive film, high performance composite, energy storage or the like.Wherein, for the consideration that combines with traditional semiconductor processing technology, the controlled preparation and the property research of surface carbon nanotube are the research bases of realizing above-mentioned a lot of application, therefore become one of core realm of carbon nanotube research.

Because carbon nanotube has so wide application prospect, causes the preparation of carbon nanotube also to obtain unprecedented development.In the control of aspect such as the preparation research of carbon nanotube mainly concentrates on caliber, chirality for carbon nanotube, arrange.The preparation of carbon nanotube mainly comprises arc process, laser ablation method, chemical Vapor deposition process (CVD) or the like.Arc process can be accomplished scale production, not only prepared carbon nano pipe purity height, and also day output can reach tonne; Its shortcoming is to obtain the carbon nanotube sample of body phase.Laser ablation method can't be accomplished scale production owing to prepare the restriction of system.The advantage of chemical Vapor deposition process is that the carbon nanotube of its preparation can use easily in the research of nanoelectronics and feds, and is convenient to grow in controlled graphical substrate.For the preparation of surface carbon nanotube, adopt the method for chemical vapor deposition usually.

The control of carbon nanotube is synthetic for its research of further using, and very important meaning is arranged.The control of carbon nanotube preparation comprises its caliber, chirality, the control of the features such as trend of arranging, and becomes the difficult problem in current made of carbon nanotubes field.This wherein, the arrange control of trend of carbon nanotube is one of scientific research personnel's emphasis of making great efforts always.Consider from next step applied research: on the one hand,, all need specific, controlled arrangement model, could realize the multifunction of device as a kind of functional type device; On the other hand, in the face of the integrated requirement of element height, need be in limited substrate, the element of arranging as much as possible to improve space availability ratio, reduces manufacturing cost.

In the bibliographical information of all relevant carbon nanotube horizontal array preparations, the core of investigator's contrived experiment all is how to produce and makes the strong extraneous inducing action of carbon nanotube according to set direction growth, and the extraneous induction factor that is adopted can be air-flow, electric field and substrate etc.In adopting electric field inductive carbon nano tube growth,, be very disadvantageous for large-scale production because the needed plant and instrument of extra electric field is very expensive.In the preparation field of surface working and micro-nano device, silicon/silicon dioxide is the most ripe as the technology of substrate, also is that cost is minimum at present.Use other substrate instead, for example sapphire of Pao Guang single crystal quartz, polishing etc. has not only greatly increased cost, also is unfavorable for using existing mature technology, realizes technical linking.Air-flow is one of principal element that influences carbon nano tube growth, all reports to some extent in a lot of documents.But up to the present, the method of reporting in the document for preparing carbon nanotube, the air-flow that is adopted all be growth gasses flow through growth container the airflow pattern that forms naturally, therefore preparation-obtained just some arrangement modes are more single, are orientated comparatively fixed carbon nanotube sample.

Summary of the invention

The objective of the invention is to overcome the shortcoming that exists in the prior art, the characteristics of utilizing carbon nanotube influenced by reaction gas flow provide a kind of orientation controlled, the preparation method of the carbon nanotube that intensity is high.

The present invention prepares at existing chemical Vapor deposition process on the basis of method of carbon nanotube, by the advection flow pattern that the air-flow restraining mass changes the reaction gas flow of the substrate top of flowing through, the growth orientation of controlling carbon nanotube are set.

Particularly, the present invention can adopt and be prepared as follows step:

A) target orientation according to carbon nanotube is provided with the air-flow restraining mass in reaction vessel;

B) under inert environments, reaction gas fed reaction vessel and under temperature of reaction in substrate reaction generate carbon nanotube;

C) cooling and obtain the carbon nanotube of target orientation under inert environments.

Wherein, described air-flow restraining mass can be to be arranged at described suprabasil cylinder or cone (such as cylinder or circular cone, triangular prism or triprismo, quadrangular or rectangular pyramid etc.); It also can be irregular reaction vessel inwall; Or the prominence that is provided with on the smooth reaction vessel inwall, perhaps other can stop reaction gas flow, again not with the air-flow blocking-up, keeps its unobstructed parts or setting of flowing simultaneously.

Step a) can adopt steady state flow dynamic simulated (such as adopting Fluent software to carry out computer simulation) that the concrete set-up mode of described air-flow restraining mass is done suitable correction, so that analog result is approached required carbon nanotube target orientation as far as possible;

Step b) and c) described inert environments can adopt the technical field of the invention feeding rare gas element commonly used (such as, nitrogen, rare gas or the like) method realizes, need to prove, oxygen, perhaps water vapour or any other can and the gas that under temperature of reaction, reacts of carbon nanotube all preparation method of the present invention is harmful to, therefore, described inert environments can not comprise these detrimental impurity.

Further, the temperature of reaction of the inventive method is preferably at 700 ℃ to 1200 ℃, so reaction vessel, air-flow restraining mass, substrate and slide glass should bear the temperature in the above-mentioned scope.

Particularly, reaction vessel can be silica tube or vitrified pipe;

Substrate can be silicon chip, quartz plate, sapphire sheet, tinsel or ceramic plate or the like;

Further, the inventive method is also used catalyzer, and described catalyzer can be the metal that all can the catalytic growth carbon nanotube, and for example: copper, iron or the like, its presoma can be the material that contains this metallic element of arbitrary form.Different catalyzer has different optimal reaction temperatures.

In aforesaid method, the source of the carbon that carbon nano tube growth is required can be that hydrogen and can decomposing arbitrarily produces carbon compound () mixture for example: methane, ethene, ethanol or their mixture.

In addition, the carbon nanotube with method for preparing also is one of protection theme of the present invention.

By the carbon nanotube that present method prepares, the orientation of its growth can regulated at will.By changing the putting position and the spread pattern of air-flow restraining mass, just can obtain the carbon nano pipe array of required pattern.If change the profile of air-flow restraining mass, as triangular prism, rectangular parallelepiped etc., also can change bending takes place the carbon pipe angle and curvature, thereby realize control for its array pattern.This control is very favourable for follow-up integrated device research and development.

The trend of carbon nano pipe array only not, the density of the suprabasil carbon nanotube of whole silicon wafer also can change.Find that in experiment the air-flow restraining mass of specific configuration has makes carbon nanotube form the pattern that converges or disperse, thereby has significantly changed the arranging density of carbon nanotube.Integrated device often requires the high concentration to device, particularly at chip position.The local Auto-regulating System of Density of Heavy Medium of carbon nanotube is for realizing that this requirement is highly significant.

Compare with prior art, the present invention has the following advantages:

1, equipment is simple, easily operation;

2, raw materials cost is relatively low;

3, product is repeatable strong;

4, easily combine, thereby accelerate the practicability paces with existing silicon-based devices technology of preparing.

Description of drawings

Fig. 1 is the preparation facilities synoptic diagram that the embodiment of the invention 1 to 3 adopts;

Fig. 2 is the air-flow restraining mass placement location synoptic diagram in the embodiment of the invention 1 to 3;

Fig. 3 is modes of emplacement mimic reaction gas flow flow pattern and the velocity vector synoptic diagram according to the air-flow restraining mass among the embodiment 1 to 3;

Fig. 4 is a sem observation to the photo of the carbon nanotube of embodiment 1 to 3 and comparing embodiment 1 preparation, and the direction of growth is for from left to right;

In the above-mentioned accompanying drawing, the 1-silica tube; The 2-electric tube furnace; The 3-substrate; 4-air-flow restraining mass; The 5-slide glass

Embodiment

The invention will be further described below in conjunction with embodiment and accompanying drawing:

Method therefor is ordinary method if no special instructions among the following embodiment.

Embodiment 1: the controlled carbon nanotube of the CVD method that is rapidly heated growth orientation

Present embodiment adopts the experimental installation of routine as shown in Figure 1 to prepare carbon nanotube, and this device comprises: 1) silica tube; 2) electric tube furnace; 3) substrate; 4) air-flow restraining mass; 5) slide glass

The present embodiment method may further comprise the steps:

1, the substrate (silicon chip) that will clean up and be attached with catalyst precursor is placed on the central authorities of slide glass;

2, be oriented in the substrate both sides according to required carbon nanotube air-flow restraining mass (right cylinder) is set, and with the flow pattern of Fluent6.1 simulation reaction air-flow, position according to flow pattern correction air-flow restraining mass, approach required carbon nanotube orientation until the airflow pattern analog result that obtains, shown in Fig. 2 a and 3a;

3, slide glass is pushed into the mid-way of silica tube; Under the condition of closed quartz tube not, be heated to 700 ℃ from room temperature with 15 minutes, and constant temperature 5 minutes;

4, silica tube is pulled out from electric tube furnace, just pull out burner hearth to slide glass, as shown in Figure 1a;

5, the argon gas that feeds 500 cc/min is to drive air residual in the pipe away, and electric tube furnace continues to heat up simultaneously, reaches 975 ℃ in 10 minutes;

6, close argon gas, and feed the hydrogen of 400 cc/min and the methane blended gas of 400 cc/min, push silica tube, make slide glass arrive the burner hearth middle position, shown in Fig. 1 b, and 970 ℃ of following constant temperature 15 minutes;

7, close hydrogen and methane, the argon gas that recovers 500 cc/min is as protection gas, and closes heating, is cooled to 700 ℃;

8, open electric stove hearth, be cooled to room temperature, obtain the carbon nanotube of required orientation, shown in accompanying drawing 4a with blower is auxiliary.

Embodiment 2

Present embodiment adopts device and the step identical with embodiment 1, difference is that the setting of air-flow restraining mass is shown in Fig. 2 b, the analog result of reaction gas flow flow pattern is shown in Fig. 3 b, and the carbon nanotube that obtains characterizes through electron microscope, obtains the Electronic Speculum figure shown in Fig. 4 b.

Embodiment 3

Present embodiment adopts device and the step identical with embodiment 1, difference is that the setting of air-flow restraining mass is shown in Fig. 2 c, the analog result of reaction gas flow flow pattern is shown in Fig. 3 c, and the carbon nanotube that obtains characterizes through electron microscope, obtains the Electronic Speculum figure shown in Fig. 4 c.

Comparing embodiment 1

Present embodiment adopts method and the step identical with embodiment 1, difference is not to be provided with the air-flow restraining mass, that is to say, adopts conventional chemical gaseous phase depositing process to prepare carbon nanotube, the carbon nanotube that obtains characterizes through electron microscope, obtains the Electronic Speculum figure shown in Fig. 4 d.

As can be seen from the above-described embodiment, controlled by the carbon nanotube orientation of the inventive method preparation, the intensity height has been realized the object of the invention well.

Claims (10)

1, a kind of preparation method of carbon nanotube adopts the chemical gaseous phase depositing process preparation, it is characterized in that by the advection flow pattern that the air-flow restraining mass changes the reaction gas flow of the substrate top of flowing through, the growth orientation of controlling carbon nanotube are set.

2, preparation method as claimed in claim 1 is characterized in that, comprises the steps:

A) the target growth orientation according to carbon nanotube is provided with the air-flow restraining mass in reaction vessel;

B) under inert environments, reaction gas fed reaction vessel and under temperature of reaction in substrate reaction generate carbon nanotube;

C) cooling and obtain the carbon nanotube of target orientation under inert environments.

3, preparation method as claimed in claim 2 is characterized in that, described air-flow restraining mass is for being arranged at described suprabasil one or more cylinders or cone.

4, preparation method as claimed in claim 2 is characterized in that, described air-flow restraining mass is irregular reaction vessel inwall.

5, preparation method as claimed in claim 2 is characterized in that, described air-flow restraining mass is the one or more prominences that are arranged on the smooth reaction vessel inwall.

As any described preparation method of claim 2 to 5, it is characterized in that 6, described reaction gas is the gas mixture of the gas of hydrogen and the set that is selected from methane, ethene, ethanol or their mixture composition.

As any described preparation method of claim 2 to 5, it is characterized in that 7, described temperature of reaction is in 700 ℃ to 1200 ℃ scope, described reaction vessel and described substrate all can be born described temperature of reaction.

8, as any described preparation method of claim 2 to 5, it is characterized in that described reaction vessel is silica tube or vitrified pipe, described substrate is silicon chip or quartz plate or or sapphire sheet or tinsel or ceramic plate.

As any described preparation method of claim 2 to 5, it is characterized in that 9, catalyzer is used in described reaction, described catalyzer contain can the catalyzed carbon nanotube growth metallic element.

10, a kind of carbon nanotube is characterized in that, according to preparing as any described method of claim 1 to 5.

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