The present invention is directed to a method to couple and align carbon nanotubes in a non-woven sheet. Also the present invention is directed to the formed nonwoven sheet containing aligned carbon nanotubes.
Considerable efforts have been undertaken to create useful articles having commercial applicability from carbon nanotubes. Enhanced mechanical strength, electrical or thermal properties can be theoretically obtained from such articles.
Smalley et al., U.S. Pat. No. 7,125,502 issued Oct. 24, 2006 discloses fibers of aligned single-wall carbon nanotubes and a process of making such fibers.
Lashmore et al. U. S. Publication No. 2009/0075545 published Mar. 19, 2009 discloses aligning nonwovens with a yarn or non-woven sheet by use of chemicals including solvents and surfactants.
Liang et al., U.S. Publication No. 2009/0280324, published Nov. 12, 2009 discloses a method of producing a prepreg of a nanoscale fiber film with the fibers impregnated with a resin followed by B-stage curing the resin.
Pasquali et al., U.S. Publication No. 2011/0110843, published May 12, 2011 discloses aligned carbon nanotubes employing extrusion of a super acid solution of carbon nanotubes followed by removal of the super acid solvent.
A need is present for improved nanotube containing articles wherein increased alignment of the nanotubes occurs. One such article is in the form of a sheet.
The present invention is directed to a method of aligning carbon nanotubes in a non-woven sheet comprising the steps of:
In a preferred mode a diluent liquid is employed with the coupling agent.
Also the invention is directed to a non-woven sheet containing aligned carbon nanotubes as evidenced by the full width at half maximum (FWHM) value obtained by wide angle X-ray diffraction.
The starting material is a non-woven sheet of carbon nanotubes having non-aligned nanotubes. A suitable sheet is made by Nanocomp Technologies, Inc.
In order to obtain alignment of carbon nanotubes, it is necessary to contact the non-woven sheet with a coupling agent to achieve mechanical coupling between adjacent carbon nanotubes and to allow alignment of at least a portion of the nanotubes.
It is known that an increase in alignment of a non-woven sheet of carbon nanotubes results in increased mechanical strength. The present test measures this increase in mechanical strength by failure strain which in turn correlates to alignment, i.e. increased alignment of the nanotubes.
The term “coupling agent” as defined herein is determined by a test procedure labeled Test Method A. An alternate test procedure is labeled Test Method B.
A non-woven sheet of carbon nanotubes is initially uniformly wetted with an excess of chlorosulfonic acid. Thereafter the wetted non-woven sheet is drawn until it breaks. The initial length and final length are recorded and failure strain computed employing the following equation:
Failure strain=(final length−initial length)/initial length×100.
Another non-woven sheet of carbon nanotubes is initially wetted and contacted with an excess of chlorosulfonic acid in combination with a potential coupling agent.
The chlorosulfonic acid and potential coupling agent are present in a ratio of 99 to 1 by weight. The wetted and contacted non-woven sheet is drawn until it breaks.
The initial length and final length are recorded and failure strain computed as previously employing the following equation:
Failure strain=(final length−initial length)/initial length×100.
(In the test procedures of Part I and II all variables including rate of strain and temperature are the same. The difference between Part I and Part II is the absence or presence of the coupling agent.)
The results of Part I and Part II are compared employing the following equation:
The same procedure as Part IIA is followed except the the chlorosulfonic acid and the potential coupling agent are present in a ratio of 99.9 to 0.1 by weight.
The same procedure as Part IIA is followed except the the chlorosulfonic acid and the potential coupling agent are present in a ratio of 90 to 10 by weight.
An alternate test method is identical to Test Method A except sulfuric acid is substituted for chlorosulfonic acid. The sulfuric acid and potential coupling agent are present in ratios of 99 to 1 (Test Method B Part IIA), 99.9 to 0.1 (Test Method B Part IIB) and 90 to 10 (Test Method B Part IIC).
The results are compared in the same manner as Test Method A namely
With at least one of ratios of Test Method A and Test Method B an improvement of at least 10 percent is necessary to meet a definition of “coupling agent”. Preferably the improvement due to the coupling agent will be at least 20 percent and more preferably at least 30 percent.
Examples of coupling agents include those with electron rich molecules (aromatic) with at least two aromatic moieties. Examples include diphenybenzene, triphenylmethane, triphenylbenzene, polystyrene and triphenylene. Further examples include nonaromatic polysilanes and proteins that have a strong affinity for electron rich surfaces such as the SP1 protein of Fulcrum SP Materials.
In a preferred embodiment of the present invention a diluent liquid will be employed with the coupling agent. The diluent liquid allows control of the degree of coupling between adjacent carbon nanotubes, allows movement of the carbon nanotubes with respect to each other and facilitates alignment of the carbon nanotubes. Therefore the use of a diluent liquid is highly preferred. More care is needed in the drawing operation of the non-woven sheet without the diluent liquid.
The diluent liquid allows use of less than 100% coupling agent. Dilution of the coupling agent is beneficial since the amount of coupling agent can be controlled to provide optimum results. Illustratively the diluent liquid prevents formation of an excessive number of coupled nanotubes which would interfere with alignment.
The amount of diluent liquid and coupling agent can vary widely with examples being present in a ratio of 1:99 to 99.9:0.1 by weight. A narrower ratio is 1:10 to 10:1.
The diluent liquid facilitates movement of adjacent coupled nanotubes due to stress applied in the drawing step. Therefore the diluent liquid acts as a lubricant adding such movement.
Since the diluent liquid allows control of the degree of coupling between adjacent carbon nanotube and aids movement of carbon nanotubes in the nonwoven sheet, the result is an alignment in carbon nanotubes in the non-woven sheet.
The choice of diluent liquid can vary widely. Useful diluent liquids include strong acids with an ability to protonate the electron rich carbon nanotube walls. Specific examples include chlorosulfonic acid, sulfuric acid, methanesulfonic acid and the solution of ammonium persulfate in sulfuric acid.
Suitable apparatus to undertake Test Method A and Test Method B is shown in the FIGURE. An outer support 1 contains two parallel threated rods 2. A stationary clamp 3 and moving clamp 4 hold a specimen which is a sheet of non-woven carbon nanotubes. A bearing 5 (attached to a motor or hand crank 6) allows the threated rods to rotate whereby the moving clamps apply stress to the specimen. Excessive stress causes breakage. An alternate apparatus is disclosed in Lashmore U.S. Patent No. 2009/0075545.
Non-Woven Sheet of Carbon Nanotubes with Alignment
The aligned non-woven sheet of carbon nanotubes will have a (FWHM) value obtained by wide angle X-ray diffraction. The (FWHM) value will not be greater than 20°, preferably not greater than 10° and even more preferably not greater than 5°.
The test procedure to determine the (FWHM) value is as follows:
The (FWHM) value is determined by means of wide angle X-ray diffraction using Cu Kα radiation (wavelength=0.1542 nm) with the non-woven sheet mounted perpendicular to the beam. Full width at half maximum (FWHM) value of the azimuthal intensity scan of the equatorial reflections appearing in the region of 2θ=25°
The non-woven sheet of carbon nanotubes having alignment has use wherein at least one of the following properties is needed: enhanced mechanical strength electrical application and thermal application. One use is in a lightweight protective vest to withstand penetration of a projectile such as a bullet.
To further illustrate the present invention the following prophetic example is provided.
The starting non-woven sheet containing randomly oriented carbon nanotubes is produced by Nanocomp Technologies, Inc., Merrimack, N. H. The basis weight of the sheet is 20 grams per square meter.
Cut a specimen from the non-woven sheet and wet with an excess of a coupling agent of triphenyl methane and a diluent liquid of chlorosulfonic acid (at a weight ratio of 1:99 coupling agent to chlorosulfonic acid
Allow the coupling agent and diluent liquid to thoroughly wet the non-woven sheet at a temperature of 28° C. for 5 minutes with an excess of liquid drained by gravity.
Stretch the wetted non-woven sheet in a drawing frame as shown in the FIGURE to 1.5 times its original length.
Remove the stretched non-woven sheet from the drawing frame, wash with water to remove coupling agent and diluent liquid and dry at 110° C. for 12 hours.
Determine the amount of orientation by X-ray diffraction as set forth above.
Obtain a (FWHM) value in the non-woven sheet of not greater than 20°.
Number | Date | Country | |
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61774788 | Mar 2013 | US |