CN101213020A

CN101213020A - Method for synthesis of carbon nanotubes

Info

Publication number: CN101213020A
Application number: CNA2006800040835A
Authority: CN
Inventors: S·博德尔; D·科查德; E·杜蒂尔; P·盖拉德; D·普利
Original assignee: Arkema SA
Current assignee: Arkema France SA; Arkema SA
Priority date: 2005-02-07
Filing date: 2006-02-03
Publication date: 2008-07-02
Anticipated expiration: 2026-02-03
Also published as: CN101213020B; FR2881734B1; FR2881734A1

Abstract

The invention concerns a method for preparing carbon nanotubes by contacting a carbon source with a multivalent metal and/or metal oxide based catalyst deposited on an inorganic substrate of BET specific surface greater than 50m<2>/g. The resulting carbon nanotubes can be used as agents for improving the mechanical and electrical conductivity properties in polymer compositions.

Description

The synthetic method of CNT

The synthetic method that the objective of the invention is CNT (NTC), this method are to carry out in gas phase in the presence of the metallic catalyst that carries with specific inorganic matrix.

Prior art

Today, people know that CNT is because of its mechanical performance, very high shape ratio (length/diameter) and electrical property but the material with lot of advantages.

They are made up of hemisphere end-blocking winding graphite linings, and this hemisphere is made up of pentagon and hexagon near fullerene structure.

People know the nanotube of being made up of individual layer: therefore be referred to as SWNT (english abbreviation of single-walled nanotube), or know the nanotube of being made up of concentric multilayer, therefore be referred to as MWNT (english abbreviation of multiple wall nanotube).Generally speaking, the production of SWNT is than the production difficulty of MWNT.

Can produce CNT according to diverse ways, for example electric discharge, laser ablation method or vapor phase chemical deposition (CVD).

In these technology, this is the seemingly unique technology that can guarantee to produce in large quantities CNT easily of a kind of technology afterwards, guarantees to reach to make them be used for the necessary condition of the cost of polymer and resin application in large quantities.

According to this method, the carbon source with relatively-high temperature degree is injected in the catalyst, described catalyst can be made up of the metal of inoganic solids carrying.In these metals, preferably enumerate iron, cobalt, nickel, molybdenum and in these carriers, often aluminium oxide, silica or magnesia.

The carbon source that can consider is methane, ethane, ethene, acetylene, ethanol, methyl alcohol, acetone, even forming gas CO+H ₂(HIPCO method).

In relating to the synthetic file of CNT; can enumerate the WO 86/03455A1 of Hyperion Catalysis International Inc.; it is corresponding to EP 225.556B1; this document can be thought one of basic patent of synthetic NTC; its claimed almost columniform carbon fibrils (the former title of NTC); its diameter is 3.5-70nm, and the shape ratio is greater than or equal to 100, and their preparation method.

Make and contain iron (Fe for example ₃O ₄, carbon carrier carrying Fe, alumina support carrying Fe or contain the Fe of the carrier carrying that carbon fibrils makes) catalyst contact with the gaseous compound that contains carbon (preferably CO or hydro carbons) and carries out this synthesizing, advantageously can react generation gaseous products (for example CO, H with carbon ₂Or H ₂O) compound exists down.In these embodiments, these catalyst are to adopt dried dipping, precipitation or the preparation of wet impregnation method.

Corresponding to same applicant's EP 270, WO 87/07559 claimed same reactant and the Catalyst Production diameter of using of 666B1 is 3.5-70nm, and shape ratio L/D is the fibriilar method of 5-100.

Except being under the situation of benzene, outside operating more than 800 ℃, do not provide any information of relevant productive rate (it should be expressed as every gram catalyst time per unit and generate fibriilar quality) at the gaseous compound that contains carbon.

Some other documentation requirements protects it to improve one's methods; continuous fluidized bed for example; it can control the coherent condition (for example referring to the WO02/94713A1 with Tsing-Hua University's name application) of the carbonaceous material of catalyst and generation; or claimed its improves product; for example with the WO 02/095097A1 of Trustees Of Boston College name application, it prepares the nanotube of the different shape of non-alignment by relying on catalyst property and these reaction conditions.

The US 2001/0036549A1 of Hyperion Catalysis International Inc. described by with the multivalence transition metal or preferably the decomposition of the carbon source that contacts of metal mixture (for example Fe and Mo, Cr, Mn and/or Ce) prepare improving one's methods of NTC, the transition metal that its improvements are to form the catalytic site of a large amount of 3.5-70nm of being of a size of is carried on the inorganic matrix of size less than 400 μ m.

In these examples, this carbon source is hydrogen/mixture of ethylene, its separately dividing potential drop be 0.66 and 0.33,650 ℃ reaction time is 30 minutes, this catalyst is to use ferric nitrate dipping alumina (not provide iron content in the presence of methyl alcohol, estimate 15%) prepare, the amount of its methyl alcohol is enough to obtain stick with paste; Productive rate is at 30 minutes 6.9g/g, and when adding molybdenum salt, during for about 9-10% of iron content and molybdenum content 1-2%, its productive rate reaches 10.9-11.8.When altogether-when metal was cerium, chromium, manganese, the productive rate of nanotube was respectively 8,3,9.7 and 11.

Confirm that also the efficient of pentanedione iron is not as ferric nitrate.

In embodiment 16, equal substantially at 6 o'clock at pH, flood by adding the wet method that ferric nitrate and sodium bicarbonate solution precipitate simultaneously.When iron content is 15% to add fashionablely with semicontinuous in this reactor, the selectivity that this catalyst reaches is 10.5.

Adopt another embodiment of iron and molybdenum wet impregnation to obtain and the same good result of methyl alcohol method.

This file shows that also the molybdenum that is higher than 2.5% content in order to the Mo meter replaces iron disadvantageous more precisely, because the productive rate of equal proportion Fe and Mc (total amount=16.7%) mixture in 30 minutes reaches 8.8.

When using non-porous carrier, for example employed specific area=100m of Hyperion ²During the Degussa alumina of/g, confirm that a large amount of iron of dipping is difficult, because just skin is that gas is accessibility, these internal layers do not have sufficient catalytic action.

In addition, the technology of using this class carrier is complicated, because the size of these particulates is 20nm, its bulk density is 0.06, has increased the difficulty of industrial use like this.

The objective of the invention is by decomposing the method for the synthetic NTC of carbon source, carbon source is placed reactor, preferably in fluidized-bed reactor, under temperature 500-1500 ℃, make this carbon source and one or more oxidizabilities be zero and/or the multivalence transition metal that is oxide form (positive oxidizability) contact, and reclaim described NTC, it is characterized in that this or these transition metal and/or its one or more oxides are to be higher than 50m with specific area BET ²/ g, preferably 70m ²/ g to 300m ²The matrix carrying of/g; In these carriers, preferably can enumerate these inorganic carriers, advantageously be γ or θ type aluminium oxide.

According to preferred embodiment a kind of, these carriers are easy to flood a certain amount of multivalence transition metal and/or transition metal oxide, for example, the quality of transition metal can be 50 weight % up to this final catalyst, advantageously be the 15-50 weight % of final catalyst, preferably 3040 weight %.

Advantageously select the size of carrier particles, so that this catalyst has good fluidisation when the NTC synthetic reaction.In practice, in order to guarantee reasonable productive rate, the about in a broad sense 20-500 μ of carrier particles diameter m is preferred.Certainly, if the size of this carrier particles is outside the pointed in front scope, also not exceed scope of the present invention.

Advantageously, under dry gas purges, carry out the dipping of carrier particles, for example in room temperature to the temperature of this solution boiling temperature, when this transition metal is iron in the iron nitrate aqueous solution mode; Select the amount of dipping solution,, thereby guarantee on described carrier particles, to form skin covering of the surface so that these carrier particles contact with the solution of q.s at any time.

It is true " to do " processing, at any time have just in time promptly that to form the necessary amount of liquid of liquid film at the catalytic carrier microparticle surfaces be favourable, because when heating, can avoid these aqueous effluents (nitrate aqueous effluent when this dipping solution contains ferric nitrate for example like this in dry air purging mode; Behind the dipping, the product that obtains is heated to about 300 ℃ with inertia or non-inert gas form, to remove these nitrate).

According to preferred embodiment, in this synthesis reactor, advantageously original position is carried out the reduction reaction of this catalyst in the fluid bed synthesis reactor, and this catalyst ingress of air no longer, therefore, this or these transition metal, preferred subway keeps metallic forms.

Using the metal oxide form, preferably under the situation of synthetic NTC, this catalyst can directly inject this reaction medium to the catalyst of form of iron oxide, need not pass through reduction step continuously.Therefore advantageously avoid installing the catalyst that reduction reactor and/or storage are the reduction form, and this catalyst should use under inert gas.

This carbon source can be selected from the carbonaceous material of any kind of, for example methane, ethane, propane, butane, other higher aliphatic alkane, benzene, cyclohexane, ethene, propylene, butylene, isobutene, other higher aliphatic alkene, toluene, dimethylbenzene, cumene, ethylbenzene, naphthalene, phenanthrene, anthracene, acetylene and senior alkynes, formaldehyde, acetaldehyde, acetone, methyl alcohol, ethanol, carbon monoxide etc., they are independent or mix.

The NTC that obtains according to said method can be used for many technical fields, especially electronics is (according to temperature and its structure, they can be conductor, semiconductor and insulator), machinery, for example be used for reinforced composite (these NTC than steel firm 100 times and light six times) and motor machine (can or shrink their elongations) technical field by injecting filler.For example can enumerate the purposes of NTC in macromolecule compositions, these macromolecule compositions are used for the purposes of for example production of packing, oil pipe (fuel line), antistatic coating or the coating of electronic building brick and in the purposes of thermistor, super capacity electrode etc.

Embodiment 1

Use Puralox NWA 155 gamma-aluminas to prepare catalyst, the following particulate of 5 weight % of these Puralox NWA 155 gamma-aluminas is less than 100 μ m, and below 2% greater than 500 μ m, median diameter is about 250 μ m.Below these surface characteristics and voidage feature are listed in:

Surface BET (m ²/ g) 154

Total pore volume (cm ³/ g) 0.45 (adopt DFT to measure the hole of 0-200nm)

Micro pore volume (cm ³/ g) 0.005 (adopt t-plot to measure the hole of 0-2nm).

In being heated to 100 ℃ 3L jacketed reactor, add the 300g aluminium oxide, use air purge.Utilize pump to inject the ferrous solution that 700ml contains 545g/1 anhydrous nitric acid iron continuously then.Target is 15% ferrous metal than (metal quality/catalyst quality), and the interpolation time of this ferrous solution is 10 hours, and this liquid interpolation speed equals evaporation of water speed.

This catalyst placed 100 ℃ of baking ovens 16 hours then.

Embodiment 2

Use the Puralox SCCA 5-150 gamma-alumina of the about 85 μ m of median diameter to prepare catalyst.

Below these surface characteristics and voidage feature are listed in:

Surface BET (m ²/ g) 148

Total pore volume (cm ³/ g) 0.47 (adopt DFT to measure the hole of 0-200nm)

Micro pore volume (cm ³/ g) 0.0036 (adopt t-plot to measure the hole of 0-2nm)

To be prepared catalyst and dipping with embodiment 1 same way as.

Embodiment 3

Use same SCCA 5-150 aluminium oxide, contain the catalyst of 25% iron by dipping preparation under the condition that approaches embodiment 2: the ratio of the iron content of setting in hope is regulated interpolation time and liquor capacity, promptly 16 hours simply.

This catalyst placed 100 ℃ of baking ovens 16 hours then.

Embodiment 4

The catalyst that contains 35% iron by the preparation of dipping SCCA 5-150 aluminium oxide.The ratio of the iron content of setting in hope is regulated interpolation time and liquor capacity, promptly 23 hours simply.

This catalyst placed 100 ℃ of baking ovens 16 hours then.

Embodiment 5

The catalyst that contains 50% iron by the preparation of dipping SCCA 5-150 aluminium oxide.The ratio of the iron content of setting in hope is regulated interpolation time and liquor capacity, promptly 32 hours simply.

This catalyst placed 100 ℃ of baking ovens 16 hours then.

Embodiment 6

The use median diameter is that the C 500-511 gamma-alumina of the Engelhard of 150 μ m prepares catalyst.

Below these surface characteristics and voidage feature are listed in:

Surface BET (m ²/ g) 206

Total pore volume (cm ³/ g) 0.48 (adopt DFT to measure the hole of 0-200nm)

Micro pore volume (cm ³/ g) 0 (adopt t-plot to measure the hole of 0-2nm)

Adopt the condition of embodiment 3, preparation contains the catalyst of 25% iron.This catalyst place 100 ℃ following 16 hours.

Embodiment 7

The use median diameter is that the C 500-512 θ aluminium oxide of the Engelhard of 70 μ m prepares catalyst.

Below these surface characteristics and voidage feature are listed in:

S BET(m ²/g) 93

Total pore volume (cm ³/ g) 0.37 (adopt DFT to measure the hole of 0-200nm)

Micro pore volume (cm ³/ g) 0.003 (adopt t-plot to measure the hole of 0-2nm)

With the same terms of embodiment 3 under, adopt immersion process for preparing to contain the catalyst of 25% iron.

Embodiment 8

With the layered catalyst of the about 150g of the quality diameter of packing into is that 25cm, effective depth are to carry out the catalysis test in the reactor of 1m, and this reactor has been equipped with the separator that is used to avoid fine particles is taken to the downstream.Under nitrogen, these nitrate are decomposed, under hydrogen and nitrogen (20%/80% volume/volume), be heated to 650 ℃ then 300 ℃ of heating.Under this temperature, setting the ethene flow is 3000NL/ hour, and hydrogen flowing quantity is 1000NL/ hour, and this is 0.75 corresponding to ethylene partial pressure.

Gas flow should be enough to make this solid to substantially exceed the fluidisation limit velocity, still is lower than the speed of flying out simultaneously.

After 60 minutes, stop heating, estimate to generate product amount result.Simultaneously, adopt the microscopic method assessment to generate nanotube amount (generation NTC type: SWNT or MWNT; : other form that has C).

These results come together in the following table:

The catalyst of embodiment	Productive rate	Generate the NTC type
The catalyst of embodiment	Productive rate	Generate the NTC type	1	6.6	MWNT/ : 10-30nm, other form of no C
2	8	MWNT/ : 10-30nm, other form of no C	1	6.6	MWNT/ : 10-30nm, other form of no C
2	8	MWNT/ : 10-30nm, other form of no C	3	11.4	MWNT/ : 10-30nm, other form of no C
4	20	MWNT/ : 10-30nm, other form of no C	3	11.4	MWNT/ : 10-30nm, other form of no C
4	20	MWNT/ : 10-30nm, other form of no C	5	15	MWNT/ : 10-30nm, other form of no C
6	10	MWNT/ : 10-30nm, other form of no C	5	15	MWNT/ : 10-30nm, other form of no C
6	10	MWNT/ : 10-30nm, other form of no C	7	9	MWNT/ : 10-30nm, other form of no C

As a comparison, the embodiment 10 of US 2001/0036549 has described by hydrogen/mixture of ethylene and has contacted synthetic NTC with the catalyst that contains 12% iron, and this catalyst is to prepare with the alumina that ferric nitrate floods; NTC productive rate at 30 minutes inner catalysts is 5.5.

Embodiment 9

The catalyst of embodiment 4 preparation is added in the reactor of embodiment 8, and 300 ℃ of heating to decompose these nitrate.Cool off this reactor and reclaim this catalyst with air.Therefore that does not stand reduction step also is this catalyst of ferriferous oxide form, and then is added in embodiment 8 reactors that are heated to 650 ℃, and directly in ethene and hydrogen stream, the therein ethylene dividing potential drop is 0.8.React after 60 minutes, stop heating, assessment generates the amount and the quality results of product.Obtain 14.6 productive rate, this result and the result who uses reducing catalyst to obtain are comparable; The NTC that generates is MWNT type/: 10-30nm, and they do not contain other form of carbon.

Claims

1. by decomposing the method for the synthetic NTC of carbon source, under temperature 500-1500 ℃, make this carbon source of placing fluidized-bed reactor and one or more oxidizabilities be zero and/or the multivalence transition metal that is oxide form (positive oxidizability) contact, and reclaim described NTC, it is characterized in that:

-this or these transition metal and/or its oxide are to be 70m with specific area BET ²/ g-300m ²The matrix carrying of/g; Preferably be selected from these inorganic carriers, advantageously be selected from γ or θ type aluminium oxide.

The amount of-transition metal is the 15-50 weight % of final catalyst.

2. method according to claim 1, the amount that it is characterized in that transition metal is the 30-40 weight % of final catalyst advantageously.

3. method according to claim 1 and 2, the diameter that it is characterized in that these catalyst particles are the about 500 μ m of about 20-in a broad sense.

4. according to the described method of each claim among the claim 1-3, it is characterized in that using the dipping solution that contains at least a transition metal salt, preferably under dry gas purges, flood this matrix and prepare this catalyst.

5. the method for use ferrum-based catalyst according to claim 4, it is characterized in that described catalyst is by using iron nitrate aqueous solution, preferably in room temperature to the temperature between this dipping solution boiling temperature, impregnation matrix is prepared, and its feature is that also the amount at any time of the liquid that contacts with this matrix should be just in time enough to guarantee forming skin covering of the surface on these particulates.

6. according to the described method of each claim in claim 4 or 5, it is characterized in that this catalyst original position reduces, and it contacts no longer with air, and preferably its feature is that also this catalyst is an iron-based.

7. according to the described method of each claim among the claim 1-6, it is characterized in that it is continuous.

8. according to the described method of each claim in claim 4 or 5, it is characterized in that this catalyst is that one or more are metal oxide based, preferably iron oxide based.

9. method according to claim 8 is characterized in that it is continuous.

10. as the getable NTC of method according to each claim limited among the claim 1-9.

11. the described NTC of claim 10 is as the purposes of the improver of machinery and/or conductance performance, particularly in polymer-based composition and use thereof in packaging.

12. the purposes of the described NTC of claim 11 in oil pipe, antistatic coating, thermistor, super capacity electrode.