U.S. patent application number 11/004236 was filed with the patent office on 2006-03-23 for coatings comprising carbon nanotubes and methods for forming same.
Invention is credited to Paul J. Glatkowski.
Application Number | 20060060825 11/004236 |
Document ID | / |
Family ID | 27501222 |
Filed Date | 2006-03-23 |
United States Patent
Application |
20060060825 |
Kind Code |
A1 |
Glatkowski; Paul J. |
March 23, 2006 |
Coatings comprising carbon nanotubes and methods for forming
same
Abstract
An electrically conductive film is disclosed. According to one
embodiment of the present invention, the film includes a plurality
of single-walled nanotubes having a particular diameter. The
disclosed film demonstrates excellent conductivity and
transparency. Methods of preparing the film as well as methods of
its use are also disclosed herein.
Inventors: |
Glatkowski; Paul J.;
(Littleton, MA) |
Correspondence
Address: |
POWELL GOLDSTEIN LLP;INTELLECTUAL PROPERTY GROUP
901 NEW YORK AVENUE, N.W.
THIRD FLOOR
WASHINGTON
DC
20001
US
|
Family ID: |
27501222 |
Appl. No.: |
11/004236 |
Filed: |
December 6, 2004 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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10105623 |
Mar 26, 2002 |
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11004236 |
Dec 6, 2004 |
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60278419 |
Mar 26, 2001 |
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60311810 |
Aug 14, 2001 |
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60311811 |
Aug 14, 2001 |
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60311815 |
Aug 14, 2001 |
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Current U.S.
Class: |
252/500 |
Current CPC
Class: |
C09D 185/02 20130101;
C09D 179/08 20130101; Y10T 428/24994 20150401; B82Y 10/00 20130101;
C08K 3/041 20170501; C08K 3/041 20170501; B82Y 30/00 20130101; C08K
3/041 20170501; C09D 185/02 20130101; Y10T 428/249942 20150401;
C09D 179/08 20130101; C08K 2201/013 20130101; C08J 2379/08
20130101; Y10T 428/249945 20150401; H01B 1/24 20130101; C09D 5/24
20130101; C08J 5/18 20130101 |
Class at
Publication: |
252/500 |
International
Class: |
H01B 1/12 20060101
H01B001/12 |
Claims
1-41. (canceled)
42. A multi-layered structure comprising: an electrically
conductive film comprising a plurality of nanotubes with an outer
diameter of less than 3.5 nm; and a polymeric layer disposed on at
least a portion of said electrically conductive film.
43. The multi-layered structure of claim 42, wherein said nanotubes
have an outer diameter of about 0.5 to 3.5 nm.
44. The multi-layered structure of claim 42, wherein said nanotubes
are selected from the group consisting of single-walled nanotubes
(SWNTs), double-walled nanotubes (DWNTs), multi-walled nanotubes
(MWNTs), and mixtures thereof.
45. The multi-layered structure of claim 42, wherein said nanotubes
are substantially single-walled nanotubes (SWNTs).
46. The multi-layered structure of claim 42, wherein said nanotubes
are present in said film at about 0.001 to about 1% based on
weight.
47. The multi-layered structure of claim 42, wherein the film has a
volume resistances in the range of about 10.sup.-2 ohms/cm to about
10.sup.10 ohms/cm.
48. The multi-layered structure of claim 42, wherein the film is in
the form of a solid film, a foam, or a fluid.
49. The multi-layered structure of claim 42, further comprising a
polymeric material, wherein the polymeric material comprises a
material selected from the group consisting of thermoplastics,
thermosetting polymers, elastomers, conducting polymers and
combinations thereof.
50. The multi-layered structure of claim 42, further comprising a
polymeric material, wherein the polymeric material comprises a
material selected from the group consisting of ceramic hybrid
polymers, phosphine oxides and chalcogenides.
51. The multi-layered structure of claim 42, further comprising a
polymeric material wherein the nanotubes are dispersed
substantially homogenously throughout the polymeric material.
52. The multi-layered structure of claim 42, further comprising a
polymeric material wherein the nanotubes are present in a gradient
fashion.
53. The multi-layered structure of claim 42, further comprising a
polymeric material wherein the nanotubes are present on a surface
of said polymeric material.
54. The multi-layered structure of claim 42, further comprising a
polymeric material wherein the nanotubes are formed in an internal
layer of said polymeric material.
55. The multi-layered structure of claim 42, further comprising an
opaque substrate, wherein the nanotubes are present on a surface of
said opaque substrate.
56. The multi-layered structure of claim 42, further comprising an
additive selected from the group consisting of a dispersing agent,
a binder, a cross-linking agent, a stabilizer agent, a coloring
agent, a UV absorbent agent, and a charge adjusting agent.
57. The multi-layered structure of claim 42, wherein the film has a
total transmittance of at least about 60%.
58. The multi-layered structure of claim 42, wherein said film has
a thickness between about 0.005 to about 1,000 microns.
59. The multi-layered structure of claim 42, wherein the nanotubes
are oriented.
60. The multi-layered structure of claim 42, wherein the nanotubes
are oriented in the plane of the film.
61-72. (canceled)
Description
REFERENCE TO RELATED APPLICATIONS
[0001] This application claims priority to U.S. Provisional
Application No. 60/278,419 entitled "Electrodissipative Transparent
Coatings Comprising Single-Wall Nanotubes and Methods for Forming
Same" filed Mar. 26, 2001, U.S. Provisional Application No.
60/311,810 entitled "EMI IR Materials" filed Aug. 14, 2001, U.S.
Provisional Application No. 60/311,811 entitled "Biodegradable
Film" filed Aug. 14, 2001, and U.S. Provisional Application No.
60/311,815 entitled "EMI Optical Materials" filed Aug. 14, 2001,
each of which is entirely and specifically incorporated by
reference.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates electrically conductive
coatings.
[0004] More particularly, the invention relates to transparent
electrically conductive coatings comprising carbon nanotubes.
[0005] 2. Description of the Related Art
[0006] Electrically conductive transparent films are known in the
art. In general, such films are generally formed on an electrical
insulating substrate by either a dry or a wet process. In the dry
process, PVD (including sputtering, ion plating and vacuum
deposition) or CVD is used to form a conductive transparent film of
a metal oxide type, e.g., tin-indium mixed oxide (ITO),
antimony-tin mixed oxide (ATO), fluorine-doped tin oxide (FTO),
aluminum-doped zinc oxide (FZO). In the wet process, a conductive
coating composition is formed using an electrically conductive
powder, e.g., one of the above-described mixed oxides and a binder.
The dry process produces a film having both good transparency and
good conductivity. However, it requires a complicated apparatus
having a vacuum system and has poor productivity. Another problem
of the dry process is that it is difficult to apply to a continuous
or big substrate such as photographic films or show windows.
[0007] The wet process requires a relatively simple apparatus, has
high productivity, and is easy to apply to a continuous or big
substrate. The electrically conductive powder used in the wet
process is a very fine powder having an average primary particle
diameter of 0.5 .mu.m or less so as not to interfere with
transparency of the resulting film. To obtain a transparent coating
film, the conductive powder has an average primary particle
diameter of half or less (0.2 .mu.m) of the shortest wave of
visible light so as not to absorb visible light, and to controlling
scattering of the visible light.
[0008] The development of intrinsically conductive organic polymers
and plastics has been ongoing since the late 1970's. These efforts
have yielded conductive materials based on polymers such as
polyanaline, polythiophene, polypyrrole, and polyacetylene. (See
"Electrical Conductivity in Conjugated Polymers." Conductive
Polymers and Plastics in Industrial Applications", Arthur E.
Epstein; "Conductive Polymers." Ease of Processing Spearheads
Commercial Success. Report from Technical Insights. Frost &
Sullivan; and "From Conductive Polymers to Organic Metals."
Chemical Innovation, Bernhard Wessling.
[0009] A significant discovery was that of carbon nanotubes, which
are essentially single graphite layers wrapped into tubes, either
single walled nanotubes (SWNTs) or double walled (DWNTs) or multi
walled (MWNTs) wrapped in several concentric layers. (B. I.
Yakobson and R. E. Smalley, "Fullerene Nanotubes: C.sub.1,000,000
and Beyond", American Scientist v. 85, July-August 1997). Although
only first widely reported in 1991, (Phillip Ball, "Through the
Nanotube", New Scientist, 6 July 1996, p. 28-31.) carbon nanotubes
are now readily synthesized in gram quantities in the laboratories
all over the world, and are also being offered commercially. The
tubes have good intrinsic electrical conductivity and have been
used in conductive materials.
[0010] U.S. Pat. No. 5,853,877, the disclosure of which is
incorporated by reference in its entirety, relates to the use of
chemically-modified multiwalled nanotubes (MWNT). The coating and
films disclosed in U.S. Pat. No. 5,853,877 are optically
transparent when formed as a very thin layer. As the thickness of
the films increases to greater than about 5 .mu.m, the films lose
their optical properties.
[0011] U.S. Pat. No. 5,853,877 also relates to films that are
formed with and without binders. The films include binders with a
very high nanotube concentration and are extremely thin in order to
maintain the optical properties. For example, the patent discloses
a film with 40% wt MWNT loading to get good ESD conductivities.
[0012] U.S. Pat. No. 5,908,585, the disclosure of which is
incorporated by reference in its entirety, relates the use of two
conductive additives, both MWNT and an electrically conductive
metal oxide powder.
SUMMARY OF THE INVENTION
[0013] Therefore, a need has arisen for an electrically conductive
film comprising nanotubes with a particular diameter that overcome
those drawbacks of the related art.
[0014] Accordingly, in a preferred embodiment, the invention
provides electrostatic dissipative transparent coatings comprising
nanotubes.
[0015] Accordingly, in another preferred embodiment, the invention
provides an electrically conductive film comprising: a plurality of
nanotubes with an outer diameter of less than 3.5 nm.
[0016] In another preferred embodiment, the invention provides a
method for making an electrically conductive film of claim 1
comprising: providing a plurality of nanotubes with an outer
diameter of less than 3.5 nm; and forming a film of said nanotubes
on a surface of a substrate.
[0017] In another preferred embodiment, the invention provides a
multi-layered structure comprising: an electrically conductive
film, and a polymeric layer disposed on at least a portion of said
electrically conductive film.
[0018] In another preferred embodiment, the invention provides
dispersions of nanotubes suitable for forming films and other
compositions. Such compositions may contain additional conductive,
partially conductive or non-conductive materials. The presence of
nanotubes reduces the manufacturing costs of conventional materials
that do not contain nanotubes while increasing product
effectiveness, preferably product conductivity. Compositions may be
in any form such as a solid or liquid, and is preferably a powder,
a film, a coating, an emulsion, or mixed dispersion.
[0019] Other objects, features and advantages of the present
invention will become apparent from the following detailed
description. It should be understood, however, that the detailed
description and the specific examples, while indicating preferred
embodiments of the invention, are given by way of illustration
only, since various changes and modifications within the spirit and
scope of the invention will become apparent to those skilled in the
art from this detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
[0020] The accompanying drawings, which are incorporated in and
constitute a part of the specification, illustrate a presently
preferred embodiment of the invention, and, together with the
general description given above and the detailed description of the
preferred embodiment given below, serve to explain the principles
of the invention. Thus, for a more complete understanding of the
present invention, the objects and advantages thereof, reference is
now made to the following descriptions taken in connection with the
accompanying drawings in which:
[0021] FIG. 1 is a plot of conductivity verses thickness for SWNT
coatings according to one embodiment of the present invention;
[0022] FIG. 2 depicts a plot of the affect of high humidity on an
ESD coating over an extended period of time according to one
embodiment of the present invention;
[0023] FIG. 3 depicts a plot of surface resistivity versus
temperature data for Si-DETA-50-Ti with 0.30% SWNT cast on to a
glass slide according to one embodiment of the present
invention;
[0024] FIG. 4 depicts a plot of surface resistivity versus
temperature data for Si-DETA-50-Ti with 0.20% SWNT cast on to a
glass slide according to one embodiment of the present
invention;
[0025] FIG. 5 depicts a plot of surface resistivity versus test
voltage data for Si-DETA-50-Ti with 0.3% SWNT cast on to a glass
slide according to one embodiment of the present invention; and
[0026] FIG. 6 depicts the percent nanotubes cast on glass slides
labeled with resistance measurements according to one embodiment of
the present invention.
[0027] FIG. 7 depicts advantages of SWNTs used to impart electrical
properties to films.
[0028] FIG. 8 depicts results showing how each of the three films
resistivity (@500V) varied with temperature from -78 to
+300.degree. C.
[0029] FIG. 9 depicts resistivity in Ohms/Sq. for 1 mil POLYIMIDE-1
film as voltage is reduced.
[0030] FIG. 10 depicts tensile properties for POLYIMIDE-1,
POLYIMIDE-2, and TPO resins with and without nanotubes.
[0031] FIG. 11 depicts CTE Data on POLYIMIDE-1, POLYIMIDE-2, and
TPO 1 mil films with and without 0.1% SWnTs.
[0032] FIG. 12 depicts a POLYIMIDE-1 coating with 0.3% SWNTs @ 1.5
.mu.m thick, slide is tilted off the paper/pavement by piece of
mica, and is illuminated by sunlight. Stats: 96% T, 0.6% Haze,
resistivity 3.times.10.sup.8 Ohms/sq.
DETAILED DESCRIPTION OF THE INVENTION
[0033] The preferred embodiments of the present invention and its
advantages are understood by referring to the Figs. of the
drawings, wherein like numerals being used for like and
corresponding parts of the various drawings.
[0034] The instant invention relates to particular electrically
conductive films comprising nanotubes and methods of forming the
same. The instant films comprising nanotubes demonstrate
advantageous light transmissions over those materials comprising
nanotubules disclosed heretofore. In this connection the instant
invention relies on nanotubes with a particular diameter which
impart surprising advantages over those films disclosed in the
prior art.
[0035] In relation to the above, it has surprisingly been found
that nanotubes with an outer diameter of less than 3.5 nm are
particularly good candidates to impart conductivity and
transparency at low loading doses. These nanotubes can exhibit
electrical conductivity as high as copper, thermal conductivity as
high as diamond, strength 100 times greater than steel at one sixth
the weight, and high strain to failure. However, heretofore, there
has been no report of such nanotubes in an electrically conductive
and transparent film.
[0036] Nanotubes are known and have a conventional meaning. (R.
Saito, G. Dresselhaus, M. S. Dresselhaus, "Physical Properties of
Carbon Nanotubes," Imperial College Press, London U.K. 1998, or A.
Zettl "Non-Carbon Nanotubes" Advanced Materials, 8, p. 443
(1996)).
[0037] In a preferred embodiment, nanotubes of this invention
comprises straight and bent multi-walled nanotubes (MWNTs),
straight and bent double-walled nanotubes (DWNTs) and straight and
bent single-walled nanotubes (SWNTs), and various compositions of
these nanotube forms and common by-products contained in nanotube
preparations such as described in U.S. Pat. No. 6,333,016 and WO
01/92381, which are incorporated herein by reference in their
entirety.
[0038] The nanotubes of the instant invention have an outer
diameter of less than 3.5 nm. In another preferred embodiment,
nanotubes of the instant invention have an outer diameter of less
than 3.25 nm. In another preferred embodiment, nanotubes of the
instant invention have an outer diameter of less than 3.0 nm. In
another preferred embodiment, the nanotubes have an outer diameter
of about 0.5 to about 2.5 nm. In another preferred embodiment, the
nanotubes have an outer diameter of about 0.5 to about 2.0 nm. In
another preferred embodiment, the nanotubes have an outer diameter
of about 0.5 to about 1.5 nm. In another preferred embodiment, the
nanotubes have an outer diameter of about 0.5 to about 1.0 rm. The
aspect ratio may be between 10 and 2000.
[0039] In a preferred embodiment, the nanotubes comprise single
walled carbon-based SWNT-containing material. SWNTs can be formed
by a number of techniques, such as laser ablation of a carbon
target, decomposing a hydrocarbon, and setting up an arc between
two graphite electrodes. For example, U.S. Pat. No. 5,424,054 to
Bethune et al. describes a process for producing single-walled
carbon nanotubes by contacting carbon vapor with cobalt catalyst.
The carbon vapor is produced by electric arc heating of solid
carbon, which can be amorphous carbon, graphite, activated or
decolorizing carbon or mixtures thereof. Other techniques of carbon
heating are discussed, for instance laser heating, electron beam
heating and RF induction heating. Smalley (Guo, T., Nikoleev, P.,
Thess, A., Colbert, D. T., and Smally, R. E., Chem. Phys. Lett.
243: 1-12 (1995)) describes a method of producing single-walled
carbon nanotubes wherein graphite rods and a transition metal are
simultaneously vaporized by a high-temperature laser. Smalley
(Thess, A., Lee, R., Nikolaev, P., Dai, H., Petit, P., Robert, J.,
Xu, C., Lee, Y. H., Kim, S. G., Rinzler, A. G., Colbert, D. T.,
Scuseria, G. E., Tonarek, D., Fischer, J. E., and Smalley, R. E.,
Science, 273: 483-487 (1996)) also describes a process for
production of single-walled carbon nanotubes in which a graphite
rod containing a small amount of transition metal is laser
vaporized in an oven at about 1200.degree. C. Single-wall nanotubes
were reported to be produced in yields of more than 70%. U.S. Pat.
No. 6,221,330, which is incorporated herein by reference in its
entirety, discloses methods of producing single-walled carbon
nanotubes which employs gaseous carbon feedstocks and unsupported
catalysts.
[0040] SWNTs are very flexible and naturally aggregate to form
ropes of tubes. The formation of SWNT ropes in the coating or film
allows the conductivity to be very high, while loading is very low,
and results in a good transparency and low haze.
[0041] The instant films provide excellent conductivity and
transparency at low loading of nanotubes. In a preferred
embodiment, the nanotubes are present in the film at about 0.001 to
about 1% based on weight. Preferably, the nanotubes are present in
said film at about 0.01 to about 0.1%, which results in a good
transparency and low haze.
[0042] The instant films are useful in a variety of applications
for transparent conductive coatings such as ESD protection, EMI/RFI
shielding, low observability, polymer electronics (e.g.,
transparent conductor layers for OLED displays, EL lamps, plastic
chips, etc.). The surface resistance of the instant films can
easily be adjusted to adapt the films to these applications that
have different target ranges for electrical conductivity. For
example, it is generally accepted that the resistance target range
for ESD protection is 10.sup.6-10.sup.10 ohms/square. It is also
generally accepted that a resistance for conductive coatings for
EMI/RFI shielding should be <10.sup.4 ohms/square. It is also
generally accepted that low observability coatings for
transparencies is typically <10.sup.3 ohms/square, preferably
<10.sup.2 ohms/square. For polymer electronics, and inherently
conductive polymers (ICPs), the resistivity values typically are
<10.sup.4 ohms/square.
[0043] Accordingly, in a preferred embodiment, the film has a
surface resistance in the range of less than about 10.sup.10
ohms/square. Preferably, the film has a surface resistance in the
range of about 10.sup.0-10.sup.10 ohms/square. Preferably, the film
has a surface resistance in the range of about 10.sup.1-10.sup.4
ohms/square. Preferably, the film has a surface resistance in the
range of less than about 10.sup.3 ohms/square. Preferably, the film
has a surface resistance in the range of less than about 10.sup.2
ohms/square. Preferably, the film has a surface resistance in the
range of about 10.sup.-2-10.sup.0 ohms/square.
[0044] The instant films also have volume resistances in the range
of about 10.sup.-2 ohms-cm to about 10.sup.10 ohms-cm. The volume
resistances are as defined in ASTM D4496-87 and ASTM D257-99.
[0045] The instant films demonstrate excellent transparency and low
haze. For example, the instant film has a total transmittance of at
least about 60% and a haze value of visible light of about 2.0% or
less. In a preferred embodiment, the instant films have a haze
value of 0.5% or less.
[0046] In a preferred embodiment, the film has a total light
transmittance of about 80% or more. In another preferred
embodiment, the film has a total light transmittance of about 85%
or more. In another preferred embodiment, the film has a total
light transmittance of about 90% or more. In another preferred
embodiment, the film has a total light transmittance of about 95%
or more. In another preferred embodiment, has a haze value less
than 1%. In another preferred embodiment, film has a haze value
less than 0.5%.
[0047] Total light transmittance refers to the percentage of energy
in the electromagnetic spectrum with wavelengths less than
1.times.10.sup.-2 cm that passes through the films, thus
necessarily including wavelengths of visible light.
[0048] The instant films range from moderately thick to very thin.
For example, the films can have a thickness between about 0.5 nm to
about 1000 microns. In a preferred embodiment, the films can have a
thickness between about 0.005 to about 1000 microns. In another
preferred embodiment, the film has a thickness between about 0.05
to about 500 microns. In another preferred embodiment, the film has
a thickness between about 0.05 to about 500 microns. In another
preferred embodiment, the film has a thickness between about 0.05
to about 400 microns. In another preferred embodiment, the film has
a thickness between about 1.0 to about 300 microns. In another
preferred embodiment, the film has a thickness between about 1.0 to
about 200 microns. In another preferred embodiment, the film has a
thickness between about 1.0 to about 100 microns. In another
preferred embodiment, the film has a thickness between about 1.0 to
about 50 microns.
[0049] In another preferred embodiment, the film further comprises
a polymeric material. The polymeric material may be selected from a
wide range of natural or synthetic polymeric resins. The particular
polymer may be chosen in accordance with the strength, structure,
or design needs of a desired application. In a preferred
embodiment, the polymeric material comprises a material selected
from the group consisting of thermoplastics, thermosetting
polymers, elastomers and combinations thereof. In another preferred
embodiment, the polymeric material comprises a material selected
from the group consisting of polyethylene, polypropylene, polyvinyl
chloride, styrenic, polyurethane, polyimide, polycarbonate,
polyethylene terephthalate, cellulose, gelatin, chitin,
polypeptides, polysaccharides, polynucleotides and mixtures
thereof. In another preferred embodiment, the polymeric material
comprises a material selected from the group consisting of ceramic
hybrid polymers, phosphine oxides and chalcogenides.
[0050] Films of this invention may be easily formed and applied to
a substrate such as a dispersion of nanotubes alone in solvents
such as acetone, water, ethers, and alcohols. The solvent may be
removed by normal processes such as air drying, heating or reduced
pressure to form the desired film of nanotubes. The films may be
applied by other known processes such as spray painting, dip
coating, spin coating, knife coating, kiss coating, gravure
coating, screen printing, ink jet printing, pad printing, other
types of printing or roll coating.
[0051] A dispersion is a composition comprising preferably, but not
limited to, a uniform or non-uniform distribution of two or more
heterogeneous materials. Those materials may or may not chemically
interact with each other or other components of the dispersion or
be totally or partially inert to components of the dispersion.
Heterogeneity may be reflected in the chemical composition, or in
the form or size of the materials of the dispersion.
[0052] The instant films may be in a number and variety of
different forms including, but not limited to, a solid film, a
partial film, a foam, a gel, a semi-solid, a powder, or a fluid.
Films may exist as one or more layers of materials of any thickness
and three-dimensional size.
[0053] The substrate is not critical and can be any conductive or
non-conductive material, for example, metals, organic polymers,
inorganic polymers, glasses, crystals, etc. The substrate for
example, maybe, transparent, semi-transparent, or opaque. For
example, the substrate may be a woven carbon or glass fabric to
form a prepreg (resin coated fabric) wherein the instant conductive
films enhance visual quality inspection of the prepreg.
Alternatively, the substrate may be an electronic enclosure with a
conductive film to render the surface conductive without
significantly changing the appearance of the enclosure.
[0054] The instant films comprising nanotubes in a proper amount
mixed with a polymer can be easily synthesized. At most a few
routine parametric variation tests may be required to optimize
amounts for a desired purpose. Appropriate processing control for
achieving a desired array of nanotubes with respect to the plastic
material can be achieved using conventional mixing and processing
methodology, including but not limited to, conventional extrusion,
multi-dye extrusion, press lamination, etc. methods or other
techniques applicable to incorporation of nanotubes into a
polymer.
[0055] The nanotubes may be dispersed substantially homogeneously
throughout the polymeric material but can also be present in
gradient fashion, increasing or decreasing in amount (e.g.
concentration) from the external surface toward the middle of the
material or from one surface to another, etc. Alternatively, the
nanotubes can be dispersed as an external skin or internal layer
thus forming interlaminate structures.
[0056] In a preferred embodiment, the instant nanotube films can
themselves be over-coated with a polymeric material. In this way,
the invention contemplates, in a preferred embodiment, novel
laminates or multi-layered structures comprising films of nanotubes
over coated with another coating of an inorganic or organic
polymeric material. These laminates can be easily formed based on
the foregoing procedures and are highly effective for distributing
or transporting electrical charge. The layers, for example, may be
conductive, such as tin-indium mixed oxide (ITO), antimony-tin
mixed oxide (ATO), fluorine-doped tin oxide (FTO), aluminum-doped
zinc oxide (FZO) layer, or provide UV absorbance, such as a zinc
oxide (ZnO) layer, or a doped oxide layer, or a hard coat such as a
silicon coat. In this way, each layer may provide a separate
characteristic.
[0057] In a preferred embodiment, the multi-layered structures have
alternating layers of nanotube-containing and non-nanotube
containing layers.
[0058] In a preferred embodiment, the nanotubes are oriented by
exposing the films to a shearing, stretching, or elongating step or
the like, e.g., using conventional polymer processing methodology.
Such shearing-type processing refers to the use of force to induce
flow or shear into the film, forcing a spacing, alignment,
reorientation, disentangling etc. of the nanotubes from each other
greater than that achieved for nanotubes simply formulated either
by themselves or in admixture with polymeric materials. Oriented
nanotubes are discussed, for example in U.S. Pat. No. 6,265,466,
which is incorporated herein by reference in its entirety. Such
disentanglement etc. can be achieved by extrusion techniques,
application of pressure more or less parallel to a surface of the
composite, or application and differential force to different
surfaces thereof, e.g., by shearing treatment by pulling of an
extruded plaque at a variable but controlled rate to control the
amount of shear and elongation applied to the extruded plaque. It
is believed that this orientation results in superior properties of
the film, e.g., enhanced electromagnetic (EM) shielding.
[0059] Oriented refers to the axial direction of the nanotubes. The
tubes can either be randomly oriented, orthoganoly oriented
(nanotube arrays), or preferably, the nanotubes are oriented in the
plane of the film.
[0060] In a preferred embodiment, the invention contemplates a
plurality of differentially-oriented nanotube film layers wherein
each layer can be oriented and adjusted, thus forming filters or
polarizers.
[0061] In a preferred embodiment, the invention also provides
dispersions comprising nanotubes. Preferably, the nanotubes have an
outer diameter less than 3.5 nm. The instant dispersions are
suitable for forming films as described herein. Accordingly, the
instant dispersions may optionally further comprise a polymeric
material as described herein. The instant dispersions may
optionally further comprise an agent such as a plasticizer,
softening agent, filler, reinforcing agent, processing aid,
stabilizer, antioxidant, dispersing agent, binder, a cross-linking
agent, a coloring agent, a UV absorbent agent, or a charge
adjusting agent.
[0062] Dispersions of the invention may further comprise additional
conductive organic materials, inorganic materials or combinations
or mixtures of such materials. The conductive organic materials may
comprise particles containing buckeyballs, carbon black,
fullerenes, nanotubes with an outer diameter of greater than about
3.5 nm, and combinations and mixtures thereof. Conductive inorganic
materials may comprise particles of aluminum, antimony, beryllium,
cadmium, chromium, cobalt, copper, doped metal oxides, iron, gold,
lead, manganese, magnesium, mercury, metal oxides, nickel,
platinum, silver, steel, titanium, zinc, or combinations or
mixtures thereof. Preferred conductive materials include tin-indium
mixed oxide, antimony-tin mixed oxide, fluorine-doped tin oxide,
aluminum-doped zinc oxide and combinations and mixtures thereof.
Preferred dispersion may also contain fluids, gelatins, ionic
compounds, semiconductors, solids, surfactants, and combinations
and mixtures thereof.
[0063] The present invention, thus generally described, will be
understood more readily by reference to the following examples,
which are provided by way of illustration and are not intended to
be limiting of the present invention.
EXAMPLES
[0064] Comparison of Electrical Properties for MWNT (Hyperion and
Carbolex) and SWNT (CNI (Laser Ablated and HiPCO))
[0065] The nanotubes in Table 1 were sonicated for eight minutes
into Titanium SI-DETA (ceramer hybrid resin, this work has been
repeated for other resin systems like epoxy and urethane) and then
cast onto a glass or polycarbonate slide. A set of Hyperion MWNT
was sonicated in toluene then rinsed in IPA and added to the
Titanium SI-DETA were it was sonicated for another 4 minutes. The
thickness of the cast films is 0.5 mils thick. TABLE-US-00001 TABLE
1 Hyperion Wt. % MWnT % T Bucky Nanotubes Hyperion Toluene Toluene
USA CNI Dry Wt. MWnT % T Extracted Extracted MWnT* % T SWnT % T
0.04 2.2E+9 84.5 0.06 3.5E+7 73.5 0.08 3.5E+7 76.2 0.10 >1.0E+11
92 >1.0E+11 85.5 >1.0E+11 94.4 4.5E+7 80.2 0.20 >1.0E+11
88.1 >1.0E+11 77.4 >1.0E+11 94.2 1.0E+7 70.0 0.30 >1.0E+11
88.7 >1.0E+11 74.1 >1.0E+11 93.1 7.5E+6 59.4 10.40
>1.0E+11 85.7 >1.0E+11 92.5 1.7E+6 54.8 0.50 >1.0E+11 82.2
>1.0E+11 63.4 >1.0E+11 92 1.00 >1.0E+11 68.5 3.5E+9 37.5
>1.0E+11 84.7 2.00 >1.0E+11 46.9 6.0E+6 15.2 >1.0E+11 81.5
3.00 >1.0E+11 41.6 3.25E+6 5.4 >1.0E+11 79.8
[0066] As discussed above, U.S. Pat. No. 5,908,585 discloses a film
having two conductive additives. In this table they did not create
a film with high enough conductivity to qualify as an ESD films
(<10E10 Ohms/sq). Only when they add a substantial (>20%)
loading of conductive metal oxide does the films function as
claimed. All claims are founded on this use of both fillers.
[0067] Optical Properties, Transmission, Color and Haze for Three
Coatings. 0.1%, 0.2%, and 0.3% SWNT in Ceramer Coating
TABLE-US-00002 TABLE 2 Haze Test Results for Si-DETA-50-Ti coatings
on glass at 18 um thickness Sample Thickness Total Luminous Diffuse
Name Number inches Haze % Transmittance(%) Trans % Blank 1 0.044
0.1 92.0 0.1 2 0.044 0.1 92.0 0.1 3 0.044 0.1 92.0 0.1 0.1% SWNT 1
0.044 3.2 85.2 3.8 2 0.044 3 85.0 3.5 3 0.044 3 85.2 3.5 0.2% SWNT
1 0.044 3.8 81.9 4.6 2 0.044 4.3 81.3 5.3 3 0.044 3.7 81.9 4.5 0.3%
SWNT 1 0.044 5.7 76.8 7.4 2 0.044 5.5 77.3 7.1 3 0.044 5.6 76.9 7.3
Color Scale XYZ 1 2 3 AVE BLANK C2 X 90.18 90.19 90.18 90.18 Y
91.99 92.00 91.99 91.99 Z 108.52 108.53 108.52 108.52 F2 2 X 16.18
16.18 16.18 16.18 Y 26.98 26.99 26.99 26.99 Z 124.83 124.84 124.83
124.83 A2 X 101.05 101.06 101.05 101.05 Y 91.99 92.00 92.00 92.00 Z
32.67 32.67 32.67 32.67 0.1% SWNT C2 X 83.31 83.13 83.23 83.22 Y
85.23 85.04 85.15 85.14 Z 97.89 97.75 97.76 97.80 F2 2 X 15.01
14.97 14.99 14.99 Y 25.18 25.12 25.16 25.15 Z 115.77 115.50 115.65
115.64 A2 X 93.87 93.65 93.78 93.77 Y 85.38 85.18 85.30 85.29 Z
29.57 29.52 29.53 29.54 0.2% SWNT C2 X 80.21 79.55 80.17 79.98 Y
81.93 81.25 81.89 81.69 Z 95.01 94.15 94.96 94.71 F2 2 X 14.43
14.30 14.42 14.38 Y 24.19 23.99 24.18 24.12 Z 111.26 110.32 111.20
110.93 A2 X 90.20 89.46 90.15 89.94 Y 82.04 81.37 82.00 81.80 Z
38.65 28.40 28.64 31.90 0.3% SWNT C2 X 75.13 75.65 75.24 75.34 Y
76.78 77.32 76.90 77.00 Z 88.29 88.96 88.42 88.56 F2 2 X 13.53
13.62 13.55 13.57 Y 22.74 22.88 22.77 22.80 Z 104.30 105.02 104.46
104.59 A2 X 84.63 85.20 84.74 84.86 Y 76.94 77.47 77.06 77.16 Z
26.65 26.85 26.69 26.73
[0068] Referring to FIG. 1, a plot of conductivity verses thickness
for SWNT coatings is provided. Note that new HiPCO CNI nanotubes
provide lower resistance.
[0069] Conductivity Verses Humidity for SWNT Coatings
[0070] Referring to Table 3 and FIG. 2, humidity does not affect
the electrical conductivity of the SWNT/Si-DETA coating. FIG. 2
shows the affect of high humidity over an extended period of time.
The resistance was unchanged over a month at saturated conditions.
TABLE-US-00003 TABLE 3 Percent Date Temperature Humidity
Ohms/Square Nov. 4, 2000 23 40 1.2E+5 Nov. 6, 2000 23 6 1.38E+5
Nov. 7, 2000 23 98 4.0E+5 Nov. 8, 2000 23 98 3.8E+5 Nov. 14, 2000
23 98 1.35E+5 Nov. 17, 2000 23 98 1.52E+5 Nov. 30, 2000 22 98
2.2E+5 Dec. 7, 2000 21 98 2.8E+5
[0071] Referring to FIG. 3, surface resistivity data for
Si-DETA-50-Ti with 0.3% SWNT cast on to a glass slide is shown. The
test period was over eight days with long soak times at each
temperature. Very little hysteresis was observed, from starting
values, when the sample was removed from the apparatus and returned
to room temperature several times during the test. Note that the
sample turned dark brown and cracked once the temperature exceeded
300.degree. C. It is also interesting to note that even though the
sample looked destroyed after testing it still have nearly the same
resistivity as prior to testing. This test was repeated using a
sample with lower loading of SWNT (0.2%) cast form the same batch
of ceromer resin, see FIG. 4. The dependence on test voltage is
also depicted. The ASTM test voltage is 500V, preferred. Actual
static charge is much higher, up to 20,000V. Apparently, the
ceromer ESD coating has reduced resistivity with increasing
voltage. The peak at 50 to 100.degree. C. may be due to moisture.
The present inventors have noted reduced magnitude during second
cycle of testing the same specimen. The voltage dependence is shown
in detail in FIG. 5.
[0072] Based on the foregoing, it is projected that the surface
resistivity of the nanotubes will remain constant after exposure to
temperatures exceeding 800.degree. C, and at temperatures exceeding
1000.degree. C. Thus, the coating provides substantially the same
ESD protection even after high temperature exposure.
[0073] FIG. 6 shows the percent nanotubes cast on glass slides
labeled with resistance measurements.
[0074] ESD Coatings
[0075] Electrical conductivity to a resin system without adversely
affecting the other physical properties is demonstrated. This data
presented in this section was obtained using three polyimides;
POLYIMIDE-1 (CP-1 from SRS), POLYIMIDE-2 (CP-2 from SRS), and TPO
(triphenyl phosphine oxide polymer from Triton Systems, Inc.).
Similar results to those presented below, have been collected on
other resins and are expected from most other polymer resins useful
for film forming and coatings applications.
[0076] Summary of Results
[0077] Electrical conductivity has been imparted to a resin system
without adversely affecting other physical properties. Data
presented in this section demonstrate three polyimides;
POLYIMIDE-1, POLYIMIDE-2, and TPO. Similar results to those
presented below, have been collected on other resins and are
expected from most other polymer resins useful for film forming and
coatings applications.
[0078] Successful incorporation of SWNTs into ESD films and
coatings are listed here with a brief summary of some of the
results obtained:
[0079] A) Electrical resistivity; concentration, and thickness of
nanotube filled films. Resistivity easily adjusted from 10.sup.2 to
10.sup.12 at any thickness greater than 1 micron. Resistivity
through bulk or surface of films demonstrated with very high
optical clarity and low haze.
[0080] B) Thermal effect on conductivity. Resistivity insensitive
to temperature and humidity from at least -78 to +300.degree. C.
Resistivity lowers with increasing voltage. Resistivity insensitive
to temperature cycling and soak.
[0081] C) Optical transparency of SWNT filled matrix for window and
lens applications. Transmission loss of only 10-15% for 25 micron
thick films with bulk conductivity. Transmission loss of only 1-5%
for thinner 2-10 micron conductive films. Haze values typically
<1%. Mechanical property changes to the resin and final films
due to presence of nanotubes. Tensile, modulus, and elongation to
break unaffected by addition of nanotubes. Coefficient of thermal
expansion unaffected by addition of nanotubes. No other qualitative
differences between films with or without nanotubes observed.
[0082] D) Processing of resin and films unaffected by incorporation
of nanotubes. Viscosity, surface tension, wetting, equivalent to
unfilled resin. Casting, drying, curing, film parting, and final
surface appearance identical. In special cases of high nanotube
loading some viscosity increase is observed.
[0083] E) Formulation of the SWNT homogeneously throughout the
matrix for uniform properties. Large area (2 ft. sq.) films have
very uniform electrical characteristics. Processing used in phase I
is scalable using continuous homogenizers and mixers. Some
inclusions due in part to impurities in nanotubes still present a
challenge.
[0084] Each of these key areas is presented in detail following a
brief discussion on experimental plan.
[0085] The films and coatings used for testing form two classes.
The first class of films are those made for comparative properties
testing between POLYIMIDE-1, POLYIMIDE-2, and TPO films with and
without nanotubes. In this matrix of films samples, all preparation
conditions, procedures, and materials where identical for the films
made with or without nanotubes. A uniform final film thickness of
25 microns was also maintained. The loading concentration of SWNTs
was determined from preliminary test films created with nanotube
filling weight percentage between 0.03 to 0.30%. From this test,
the films were standardized to 0.1% to give films with resistivity
between 10.sup.5-10.sup.9 Ohms/sq. During the concentration test
films with resistivity from 50 Ohms/sq to over 10.sup.12 Ohms/Sq
were able to be made. Lastly, the film thickness was selected to be
1 mil (25 um) since current application make use of this thickness
and based on observations that resistivity, at a set concentration
of nanotubes, does not vary with thickness unless film is below 2
microns. This resulting set of specimens was used in a test matrix
comparing: 1) electrical resistivity at various temperatures, 2)
optical transmittance and haze, 3) mechanical properties of
tensile, modulus, elongation, and 4) coefficient of thermal
expansion (CTE). The preparation and results of testing the films
in this matrix are presented as listed above.
[0086] The second class of films and coatings for testing were
prepared by various means and represent special coatings and films
which demonstrate the wide variety of properties attainable using
this nanotechnology enhancement to these resins. For example, these
samples include measurement of resistivity as a function of the
film thickness and nanotube loading level. The methods used for
preparation of these special demonstrations are presented.
[0087] Preparation and Test Results for Films in Comparative
Matrix
[0088] The materials used were POLYIMIDE-1 and POLYIMIDE-2, and
TPO. Both POLYIMIDE-1 and POLYIMIDE-2 were cast at a final
concentration of 15% while TPO was cast at a final concentration of
20% in NMP. To prepare the resins for casting, each resin was
placed in a three-neck round bottom flask with enough NMP to make
more concentrated 20% solution for POLYIMIDE-1 and POLYIMIDE-2 and
a 25 % solution for TPO. This concentrate is later reduced by the
addition of NMP and nanotubes. The resins were made in large
batches, purged with nitrogen and stirred at 30 RPM for 18 hours.
Each batch of resin was split in half and placed into two fresh
flasks. Then two aliquots of NMP were placed in small jars for
cutting the concentration of resin to casting viscosity. SWNTs were
weighed out and added to pure NMP. The SWNTs and NMP were sonicated
for 12 minutes. To one flask of resin concentrate, an aliquot of
pure NMP was added to the concentrate while the other half of the
resin solution an aliquot of NMP containing SWNTs was added. Both
flasks were stirred at 30 RPM for half an hour, filtered and placed
in jars for casting. Through the task of preparing the resins for
casting, attention to stirring, mixing and other details were
standardized to keep processing of the virgin and 0.1% SWNT resins
the same.
[0089] The samples were cast onto 1/4 inch thick glass panels that
were cleaned with soap and water and then rinsed in pure water and
allowed to dry. The glass was washed and with methanol and a lint
free cloth. When the methanol dried the samples were cast two
inches wide using a casting knife to make a final thickness of 1
mil final thickness. For POLYIMIDE-1 and POLYIMIDE-2 a 12.5 mil
casting thickness was used while TPO required 10-mil casting to
achieve 1 mil. The cast samples were died at 130.degree. C.
overnight and then at 130.degree. C. under vacuum for an hour. The
thin samples prepared for optical testing were not removed from the
glass but dried and heated like all the other coatings. The films
were then floated off the glass by using purified water, to reduce
water spots. After drying, the samples were tested for residual
solvents using a TGA. The remaining solvent was about 10, which was
too high. The samples were then taped on the glass panels using
Kapton tape and heated to 130.degree. C. under vacuum for 18 hours.
Using the TGA again to check for solvent content it was found that
the coatings were reduced to about 3-6% solvent. The samples were
placed back into the oven and heated to 160.degree. C. under vacuum
for 18 hours. After this heating process the solvent levels were
below 2% and used for testing.
[0090] The following test results were obtained: 1) electrical
resistivity at various temperatures; 2) optical transmittance and
haze; 3) mechanical properties of tensile, modulus, elongation; and
4) coefficient of thermal expansion (CTE).
[0091] Resistivity in Comparative Matrix as a Function of
Temperature, Voltage, and Humidity.
[0092] Background:
[0093] To impart the conductive path throughout a structure, a
three-dimensional network of filler particles was required. This is
referred to as percolation threshold and is characterized by a
large change in the electrical resistance. Essentially, the theory
is based on the agglomeration of particles, and
particle-to-particle interactions resulting in a transition from
isolated domains to those forming a continuous pathway through the
material. Nanotubes have a much lower percolation threshold than
typical fillers due to their high aspect ratio of >1000 and high
conductivity. As and example, the calculated percolation threshold
for carbon black is 3-4% while for typical carbon nanotubes the
threshold is below 0.04% or two orders of magnitude lower. This
threshold value is one of the lowest ever calculated and confirmed.
(See J. Sandler, M. S. P. Shaffer, T. Prasse, W. Bauhofer, A. H.
Windle and K. Schulte, "Development of a dispersion process for
catalytically grown carbon nanotubes in a epoxy matrix and the
resulting electrical properties", University of Cambridge, United
Kingdom, and the Technical University Hamburg-Hamburg,
Germany).
[0094] The high conductivity imparted when NT's are dispersed in a
polymer at low concentrations (0.05 to 2-wt. %) is not typically
observed in a filled material. This is one of the most attractive
aspects to using NT to make conductive materials. For a typical
filled system, like polyaniline (PAN) particles in a polymer
matrix, a 6 to 8% volume fraction is required to reach percolation
threshold for conductivity. Even when PAN is solution blended the
loading exceeds 2 wt. %. Another, more common example is found in
ESD plastics used in the electronics industry were polymers are
filled with carbon black to a loading of 10 to 30-wt. %.
[0095] The high conductivity at low concentration is due to the
extraordinarily high aspect ration of SWNTs and the high tube
conductivity. In fact, the electrical conductivity of individual
tubes has been measured and determined to exhibit metallic
behavior.
[0096] Electrical Resistivity and Thermal Stability.
[0097] To demonstrate the thermal stability through a wide range of
temperatures we mounted samples from each film in the test matrix
onto glass slides using Kapton tape. These slides were placed in an
environmental test chamber with leads attached to silver-metal
painted stripes on each of the three types, POLYIMIDE-1,
POLYIMIDE-2, and TPO. The results showing how each of the three
films resistivity varied with temperature from -78 to +300.degree.
C., are presented in FIG. 8.
[0098] The results indicate that electrical resistivity in all
three films is insensitive to a wide range of temperatures. The
relative value of resistivity between the films is not important
since it can be adjusted easily by changing the concentration of
the tubes.
[0099] However, in general TPO has a high resistivity at a given
nanotube concentration in all the samples made in the phase I. This
data also indicates that imparting conductivity to polymer by
addition of SWNTs will produce a film with excellent thermal
stability, at least as good as the base resins. These films were
cycled through this test several times without any notable change
in resistivity. In addition, we left then to soak for a period of
63 hours in air at 250.degree. C. to observe the long-term
stability as shown in Table 4 below: TABLE-US-00004 TABLE 4
Resistivity (Ohms/sq.) vs. Time Hours at 250 C. POLYIMIDE-1
POLYIMIDE-2 TPO 0 3.0E+6 5.4E+6 6.3E+6 63 4.4E+6 6.1E+6 7.8E+6
[0100] Also of interest was the relationship between test voltage
and measure resistivity. The resistivity was calculated by holding
the test voltage constant and recording the current across the
sample using ohms law. POLYIMIDE-1 coated on glass with 0.1% SWNTs
was tested from 1 Volt to 20 KV, with the calculated resistivity,
normalized to Ohms/sq, plotted in FIG. 9. This graph shows that the
resistance of these films reduces with increasing voltage. This is
also observed at elevated temperatures. From a design stand point,
this meant those films tested using low voltage meters is adequate,
since the resistance was only going to reduce is the film is
subject to higher voltage in the application. In fact these carbon
nanocomposite films may be developed for lightening protection.
[0101] To test thermal stability, samples of each of the six films
in the test matrix were scanned by TGA and DSC to evaluate how they
behave with and without nanotube present. The percent weight loss
at 350.degree. C. and the glass transition temperature was
recorded. See the Tables 6 and 7 below for results: TABLE-US-00005
TABLE 6 TGA Data on POLYIMIDE-1, POLYIMIDE-2 and TPO films with and
with nanotubes % Weight Sample loss Description @ 350.degree. C.
Virgin 1.57 POLYIMIDE-1 POLYIMIDE-1 1.46 w/SWnT Virgin 3.50
POLYIMIDE-2 POLYIMIDE-2 4.57 w/SWnT Virgin TPO 3.64 TPO w/SWnT
4.65
[0102] TABLE-US-00006 TABLE 7 DSC Data on POLYIMIDE-1, POLYIMIDE-2,
TPO Films Glass Transition Sample Temperature T.sub.g Reported
T.sub.g Description (.degree. C.) (.degree. C.) POLYIMIDE-1 248.3
263 Virgin POLYIMIDE-1 249.7 w/SWnT POLYIMIDE-2 163.8 209 Virgin
POLYIMIDE-2 162.4 w/SWnT TPO Virgin 172.4 N/A TPO w/SWnT 186.8
[0103] The decrease in the TGA and T.sub.g of the films is a result
of residual NMP trapped in the film. The TPO resin did not give a
clean or good DSC curve until thermally cycled a couple times.
[0104] Summary of Electrical Test Results.
[0105] Films have electrical resistivity much lower than required
for ESD applications and can be easily designed for any level of
electrical resistance above a 100 Ohms/sq. using very low loading
level of nanotubes. Electrical properties are insensitive to
temperature, humidity, ageing. The presence of the nanotube does
not harm the other thermal properties of the films.
[0106] Optical Transmittance and Haze.
[0107] SWNTs are excellent additives to impart conductivity to
polymeric systems and consequently function well in an ESD role.
However, for application to optics and windows, the resulting films
or coatings must also be transparent. Samples of each film made for
the comparative test matrix were tested using ASTM D 1003 "Standard
Test Method for Haze and Luminous Transmittance of Transparent
Plastics" This test method covers the evaluation of specific
light-transmitting and wide-angle-light-scattering properties of
planar sections of materials such as essentially transparent
plastic. A procedure is provided for the measurement of luminous
transmittance and haze. We also tested thinner films made from the
same resin batch. This data is presented in the Table 8 below. For
comparison, the same films were tested for % T at fixed frequency
of 500 nm using a Beckman UV-Vis spectrometry on both glass, see
Table 9, and as free standing films, see Table 10. TABLE-US-00007
TABLE 8 ASTM D1003-00B, optical haze, luminous and diffuse
transmittance data for films with and without nanotubes. Note all
thee films are conductive in the ESD range Ohms Total Thickness per
Luminous Diffuse Sample Identification Microns Square Haze % Trans
% Trans % Test Matrix Films, Free Standing POLYIMIDE-2 Virgin film
27 >1.0 .times. 10.sup.12 1.4 88.9 1.6 POLYIMIDE-2 With 0.1% 27
1.6 .times. 10.sup.6 3.1 62.7 5.0 SWnT film TPO Virgin film 30
>1.0 .times. 10.sup.12 1.5 86.8 1.7 TPO With SWnT film 30 5.0
.times. 10.sup.8 1.0 70.7 1.4 POLYIMIDE-1 Virgin film 25 >1.0
.times. 10.sup.12 0.7 90.2 0.8 POLYIMIDE-1With SWnT 25 1.4 .times.
10.sup.7.sup. 1.1 64.8 1.7 film Thin Films/Coatings on Glass Blank
NA NA 0.3 88.5 NA POLYIMIDE-1 Virgin 4 >1.0 .times. 10.sup.12
0.1 99.2 0.1 POLYIMIDE-1 With 0.1% 4 3.0 .times. 10.sup.8 0.3 93.6
0.3 SWnT POLYIMIDE-1 Virgin 12 >1.0 .times. 10.sup.12 0.3 99.0
0.3 POLYIMIDE-1 With 0.1% 12 1.9 .times. 10.sup.7 0.4 85.0 0.4
SWnT
[0108] POLYIMIDE-1 was cast onto glass substrates with and without
SWNTs at 2 and 6 mils thick. An additional ultrathin sample was
prepared using POLYIMIDE-1 compounded with 0.3% SWNTs and cast at
0.5 mil thick. These samples were tested on the UV-Vis spectrometer
for percent transmission at 500 nm, an industry standard for
comparison. The glass was subtracted out of each sample. Table 9
presents the optical and resistivity data for these samples cast on
glass. The same tests were run on POLYIMIDE-2 and TPO, with very
similar results. TABLE-US-00008 TABLE 9 POLYIMIDE-1 on glass % T @
Resistivity in Sample Description 500 nm Ohms/Sq. POLYIMIDE-1 with
0.1% 77.3 3.0E+8 SWnT at 4 um POLYIMIDE-1 with 0.1% 75.2 1.9E+7
SWnT at 12 um Virgin POLYIMIDE-1 at 4 um 83.7 >10.sup.13 Virgin
POLYIMIDE-1 at 12 um 89.2 >10.sup.13
[0109] Another set of samples were cast at the same thickness and
removed from the glass. The freestanding films were also analyzed
using the UV-Vis at 500 nm. Table 10 represents the results of the
freestanding films. TABLE-US-00009 TABLE 10 Freestanding
POLYIMIDE-1 % T @ Resistivity in Sample Description 500 nm Ohms/Sq.
POLYIMIDE-1 with 0.1% 77.3 3.0E+8 SWnT at 4 um POLYIMIDE-1 with
0.1% 75.2 1.9E+7 SWnT at 12 um Virgin POLYIMIDE-1 at 4 um 83.7
>10.sup.13 Virgin POLYIMIDE-1 at 12 um 89.2 >10.sup.13
[0110] Summary of Optical Test Results.
[0111] The optical testing of these ESD films in the test matrix
demonstrates excellent transmission with low loss. Even more
exciting are the results of thin film and bi-layer experiments
where optical properties were the focus and result in near
colorless (>95% T) films and coatings. With successful
demonstration of optically clear, low resistivity films, the next
step was to confirm that these films have the same or better
mechanical properties as those not enhance with nanotubes.
[0112] Mechanical Properties of Tensile, Modulus, Elongation.
[0113] The use of these films inmost application requires good
mechanical properties. In this section, it is demonstrated that the
presence of nanotube to impart the ESD characteristic does not
adversely affect the mechanical properties of these polymer films.
To that end, each type of film with and with out nanotube present
was tested for tensile strength, tensile modulus, and elongation at
break. The results of these tests are in Table 11 and graphed in
FIG. 10.
[0114] Coefficient of Thermal Expansion (CTE).
[0115] SWNTs' ability to impart ESD characteristics does not
adversely affect the coefficient of thermal expansion (CTE)
properties of polymer films. To that end, each type of film with
and with out nanotube present was tested. The CTE tests were
conducted using Universal Testing Machine from SRS. The testing was
conducted on 6 samples of film: Virgin POLYIMIDE-1, POLYIMIDE-1
with SWNT, Virgin POLYIMIDE-2, POLYIMIDE-2 with SWNT, Virgin TPO,
and TPO with SWNT.
[0116] Each sample was first mounted onto a strip of 5 mil Kapton
since the samples alone were slightly too short to be placed on the
fixtures properly. Once the sample was fixed to the machine, the
strain gage clamps were placed onto the film using a standard 4''
gage length. The film was then loaded with approximately 15 grams,
which would provide a suitable stress to initiate elongation during
heating but not permanent deformation.
[0117] The POLYIMIDE-1 and POLYIMIDE-2 samples behaved as expected
throughout the temperature range. The TPO samples behaved
irregularly as compared to the polyimide. Initially, the samples
appeared to shrink when heat was first applied then would grow
normally as the temperature increased. The behavior seemed typical
for the TPO VIR trial 1 on the ramp upward once the film
normalized. Interestingly, the TPO material followed a different
profile on the temperature ramp down and actually decreased in size
before growing back to its original size. Another interesting
behavior is that the TPO material seemed to change size if left to
soak at 177 C (350.degree. F.) for any length of time. The virgin
TPO shrank when soaked at 177.degree. C. while the TPO with SWNTs
grew when soaked at 177.degree. C. Since the behavior was the same
for both trials, it was determined that neither operator error nor
instrument error was at fault. All CTE measurements fell within 10%
of known values and are presented in Table 11 and in FIG. 11.
TABLE-US-00010 TABLE 11 The CTE values for each material Material
CTE (ramp up) CTE (ramp down) POLYIMIDE-1 53.27 ppm/C. 57.18 ppm/C.
POLYIMIDE-1 with SWnT 56.87 ppm/C. 55.58 ppm/C. POLYIMIDE-2 63.38
ppm/C. 64.45 ppm/C. POLYIMIDE-2 with SWnT 56.00 ppm/C. 56.43 ppm/C.
TPO (trial1) 55.42 ppm/C. 57.04 ppm/C. TPO with SWnT (trial1) 53.81
ppm/C. 56.13 ppm/C. TPO (trial2) 50.70 ppm/C. 57.60 ppm/C. TPO with
SWnT (trial2) 60.86 ppm/C. 55.78 ppm/C.
[0118] Summary of CTE Testing
[0119] As with the tensile properties, the CTE properties of these
films were generally unchanged by the addition of nanotubes. This
will permit the use of these other polymers enhanced by the
addition of nanotubes for coating and multilayer applications were
CTE matching is important for bonding and temperature cycling.
[0120] Results Obtained from exploratory Films and Coatings.
[0121] In this section are provided those results obtained from
films and coating made from the same three resins, however, in
these samples film thickness and nanotube concentration were not
held fix. Samples were generated to demonstrate the ease at which
very high clarity, high conductivity coatings and films can be
produced using Nano ESD technology. In brief, the following samples
were prepared and presented in the subsequent subsections of the
proposal:
[0122] High clarity 1-2 micron thick coatings on glass with high
loading levels of (0.2 and 0.3%) nanotubes.
[0123] Bilayer films, where very thin, high nanotube loading level
is layered on standard thickness films.
[0124] Special polymer wrapped SWNT layered on 1 mil films.
[0125] High Clarity ESD Films
[0126] It is possible to obtain a highly absorbing film by
increasing the nanotube concentration. A 1.5% loading level of
multiwalled nanotubes in polymer matrix is black and dull in
appearance. In contrast, an 8-micron thick polymer coating loaded
with 0.2% SWNTs is still conductive yet nearly colorless as
depicted in FIG. 12. This coating was formed by casting a solution
of POLYIMIDE-1 with 0.3% SWNTs @ 1.5 .mu.m final thickness. It has
a resistivity of 10.sup.8 Ohms sq with transparency 96% T with haze
of 0.6%.
[0127] This excellent coating demonstrates that by manipulating the
concentration and coating thickness excellent optical and
electrical properties can be obtained in the same film. For
comparison, the same sample was tested in our UV-Vis spectrometer
at 500 nm. The glass complicates the results since the ESD layer
acts as an antireflective coating to the glass and alters the
reflective components contribution to the transmission result.
Nevertheless, this coating demonstrates the potential for very high
clarity ESD coatings. TABLE-US-00011 TABLE 12 Transmission at 500
nm for thin 0.3% POLYIMIDE-1 coating on glass Sample % T @ 500 nm
w/ Resistivity in Description glass subtracted Ohms/Sq. Ultrathin
monolayer of 83.8 3E+8 POLYIMIDE-1 with 0.3% SWnT 0.5 mil cast
Blank piece of glass 88.8 >10.sup.13
[0128] To reduce optical absorbance in nanocomposite conductive
films the coating can be formed from a thin monolayer of high
concentration nanotubes. Several other techniques have also been
demonstrated to achieve the same high optical transparency while
maintaining high electrical conductivity in the film. Two of the
most successful rely on the same concept just shown, they are: 1)
the use of bi-layers and 2) ultra thin polymer wrapped
nanotubes.
[0129] Bi-Layer and Special Ultra Thin ESD Films.
[0130] A natural extension of the thin coating method for high
optical clarity coatings, is to form a bi-layer free standing film
by cast the thin 1 .mu.m layer first on glass and then over coating
with the thicker, 25 um layer of virgin resin. The resulting film
has a conductive surface without conductivity through the
thickness. We made films from the TPO resin to demonstrate the
concept. The specifications for this film are provided in Table
13.
[0131] Nanotube concentration was increased to almost 50% in the
conductive layer. This was done by modifying the nanotubes with a
coating of polyvinylpyrrolidone (PVP). This is also referred to as
wrapping the nanotubes with a helical layer of polymer. To
accomplish this, SWNTs were suspended in sodium dodecy sulfate and
PVP. This solution was then incubated at 50.degree. C. for 12 hours
and then flocculated with IPA. The solution is centrifuged and
washed in water three times and then suspended in water. The
resulting nanotubes are water soluble and easily sprayed or cast
onto any surface. This solution was spray coated onto virgin films
to create a fine coating (<1 um thick) that has ESD properties
and is very clear and colorless.
[0132] The resulting coating can be coated with a thin binder while
still remaining conductive or coated with a thicker layer to make
free standing films. Using this technique, coatings with a
resistivity down to 100 Ohms were generated.
[0133] Although only a few exemplary embodiments of the present
invention have been described in detail in this disclosure, those
skilled in the art who review this disclosure will readily
appreciate that many modifications are possible in the exemplary
embodiments (such as variations in sizes, structures, shapes and
proportions of the various elements, values of parameters, or use
of materials) without materially departing from the novel teachings
and advantages of the invention. Accordingly, all such
modifications are intended to be included within the scope of the
invention as defined in the appended claims.
[0134] Other substitutions, modifications, changes and omissions
may be made in the design, operating conditions and arrangement of
the preferred embodiments without departing from the spirit of the
invention as expressed in the appended claims.
[0135] Additional advantages, features and modifications will
readily occur to those skilled in the art. Therefore, the invention
in its broader aspects is not limited to the specific details, and
representative devices, shown and described herein. Accordingly,
various modifications may be made without departing from the spirit
or scope of the general inventive concept as defined by the
appended claims and their equivalents.
[0136] All references cited herein, including all U.S. and foreign
patents and patent applications, all priority documents, all
publications, and all citations to government and other information
sources, are specifically and entirely hereby incorporated herein
by reference. It is intended that the specification and examples be
considered exemplary only, with the true scope and spirit of the
invention indicated by the following claims.
[0137] As used herein and in the following claims, articles such as
"the", "a" and "an" can connote the singular or plural.
* * * * *