DE3617502A1 - Transparent, electrically conductive multilayer films - Google Patents

Abstract

Transparent, electrically conductive multilayer films made up of A) a film of electrically conductive polyacetylene with a layer thickness of 1 to 15 mu m, B) a transparent, electrically non-conductive stretchable support material with a layer thickness of 10 to 1000 mu m.

Description

The invention relates to transparent, electrically conductive multilayer films, built up from

• A) a film made of electrically conductive poly (acetylene) with a thickness from 1 to 15 µm and
• B) a transparent, electrically non-conductive, stretchable carrier material with a thickness of 1 to 1000 microns, preferably 10 to 100 µm.

The invention further relates to a method for producing such Multilayer films.

It is known from the work of Shirakawa that the polymerization of Mechanical acetylene on Ziegler catalysts under certain conditions provides solid films made of poly (acetylene) (see Journal of Polymer Science, Polymer Chemistry Edition 12 (1974), 11 to 20 and DE-A 31 20 441).

From EP-A 88 301 a method for the production is mechanically stronger Poly (acetylene) films described in sufficient layer thickness, in which a certain catalyst used in a solution of certain viscosity becomes. This catalyst solution is used to make polyacetylene films used on solid substrates.

Both the poly (acetylene) films described by Shirakawa and the However, films described in EP-A 88 301 are not transparent, such as this is desirable for some applications.

The object of the present invention was therefore to provide transparent, electrically conductive multilayer films based on electrical to provide conductive poly (acetylene).

According to the invention, this object is achieved by the initially defined transparent, electrically conductive multilayer films.

Essential for the transparency of the multilayer films according to the invention is that the film made of electrically conductive poly (acetylene) Layer thickness in the range from 1 to 15 μm, preferably in the range from 1 to 10 and in particular from 2 to 8 microns. Slides with larger ones Thicknesses of more than 15 µm no longer show good transparency after doping.

On the other hand, films made of poly (acetylene) have such low Layer thicknesses are too low inherent stability, so that they are suitable  Carrier materials must be produced. To be transparent, Obtaining electrically conductive multilayer film is the backing material a transparent, electrically non-conductive and preferably stretchable carrier material with a thickness of 1 to 1000, preferably of Use 1 to 500 and in particular from 10 to 100 microns.

In principle, all transparent, electrically non-conductive are suitable Backing materials, preferably only PVC, polyethylene, Called polyisobutene, polypropylene or polybutadiene. Manufacturing process such carrier materials are known and corresponding Films are commercially available.

The inventive method for producing transparent, electrical Conductive multilayer films are characterized in that a solution of a transition metal catalyst under an inert gas atmosphere applies a transparent, electrically non-conductive carrier material, then with acetylene on the surface of the carrier material into one Polymerized film with a thickness of 2 to 15 microns, by washing the Catalyst removed and then the polyacetylene with a dopant doped in the usual way, where appropriate before or after washing the catalyst of the polyacetylene film together with the Carrier material is stretched.

It can often be advantageous to wash the polyacetylene films after washing them out swell the catalyst in a suitable solvent. The only solvents mentioned here are toluene and benzene.

Suitable catalysts for the polymerization of acetylene are in the DE-A 29 12 572 and in the work of Shirakawa and EP-A 88 301 listed, so that further details are unnecessary here. Particularly preferred catalysts from aluminum alkyls and alkyl titanates, for. B. Triethyl aluminum and titanium tetrabutylate. The mixing ratio (molar ratio) of triethyl aluminum and titanium tetrabutylate is generally in the range from 0.5: 1 to 1: 0.5, preferably in the range from 1: 1.

The polymerization temperature is generally in the range between -15 and + 150 ° C, preferably in the range of 10 to 80 ° C.

To achieve good mechanical properties of the polyacetylene films it advantageous to adjust the viscosity of the catalyst solution in a given Keep area as described in EP-A 88 301.  

The catalyst solution is applied to the transparent, electrically non-conductive Carrier material applied such that a continuous film arises. The amount of the catalyst added can be determined in certain Limits control the layer thickness of the polymer films obtained.

After applying the solution of the transition metal catalyst under an inert gas atmosphere Acetylene, preferably gaseous, is added and on polymerized the surface of the transparent support material.

The layer thickness of the resulting poly (acetylene) film can be read through appropriate control of the polymerization time in the required range hold from 1 to 15 µm. Generally are for the production of Films with these polymerisation times of 1 to 20, in particular from 2 to 10 minutes is sufficient.

The acetylene used for the polymerization is preferably special pure and has a purity of more than 99%. Possibly can be contaminated by upstream cleaning steps be pre-cleaned.

After the polymerization can be carried out by washing, for. B. with toluene or Methanol containing hydrogen chloride is the catalyst from the polyacetylene film be washed out. The multilayer films are usually used for this 1 to 6 hours in toluene and / or 8 to 24 hours in Washed methanol containing hydrogen chloride. After subsequent The multilayer films can be dried under inert gas, if appropriate under vacuum doped with dopants in a manner known per se in order to achieve sufficient electrical conductivity.

The dopants and methods for doping polyacetylene are on known and described in the literature, so that here is closer There is no need for information. In this context, in particular, the EP-A 36 118 pointed out.

Particularly preferred dopants are iodine and arsenic pentafluoride usually the best electrical conductivities are achieved. Basically, however, all are listed in EP-A 36 118 Suitable dopants.

The electrical conductivity of the multilayer films after doping lies generally in the range of 100 to 1500, especially in the range from 200 to 1200 S / cm and is of course of the dopant and the doping conditions dependent. It is essential in any case that the doping  is carried out in the absence of oxygen and moisture, since these have a negative influence on the electrical conductivity of the polyacetylene to have. Even after the doping, it is advantageous to use the polyacetylene films to be stored in the absence of moisture and oxygen, to get better long-term stability of the conductivity.

It is also essential for achieving good conductivity that the polyacetylene produced essentially no longer contains any proportions of sp ³ -hybridized carbon atoms, since larger portions of sp ³ -hybridized carbon atoms bring about a reduction in the electrical conductivity. The poly (acetylene) films obtained by the process of EP-A 88 301 meet these conditions; the content as sp ³ -hybridized carbon atoms is generally less than 0.5 mol%, based on the total content of carbon atoms in the polyacetylene film.

To achieve even higher electrical conductivities than 1500 S / cm, the multilayer films according to the invention can be stretched, ie stretched in one direction. The electrical conductivity rises steadily with increasing stretching rate. The ratio is the stretching rate s

understood, where L _{0 represents} the starting length of the polyacetylene film and L the length of the polyacetylene film after the stretching has been carried out.

The achievable stretching rate depends on the one hand on the polyacetylene films and their mechanical properties, on the other hand from the used transparent carrier material. In general, stretching rates are possible achieve up to 600%, preferably in the range of 100 to 550%. With stretching rates in the range of approx. 300%, electrical Achieve conductivities in the range from 3500 to more than 5000 S / cm, d. H. compared to the starting materials will improve the Conductivity achieved by a factor of 3.

Parallel to the increase in conductivity in the stretching or orientation direction is a drop in electrical conductivity perpendicular to Direction of stretch or orientation can be determined, d. H. there is one Anisotropy of electrical conductivity. The anisotropy factor, d. H. the ratio of the electrical conductivity in the orientation direction electrical conductivity perpendicular to the orientation direction, is generally in the range from 3 to 20, preferably from 5  to 15. As a rule of thumb, the conductivity must be in the direction of orientation is about an order of magnitude higher than perpendicular to Orientation.

The stretching to increase the electrical conductivity can be immediate following the polymerization of acetylene on the support material, d. H. if the catalyst is still in the film or after washing out of the catalyst. The results are in both Cases comparable.

Because of their transparency and the simultaneous electrical The transparent inventive transparency can be electrically conductive Use conductive multilayer foils in areas that are made of foils electrically conductive polymers because of lack of transparency so far were locked. For example, here are polarizers, light filters, Switches, reflectors, coatings for visible parts such as windows and called optical devices.

The multilayer films according to the invention are also suitable, such as the usual foils made of electrically conductive polymers for the production of sensors, detectors and as shielding materials as well as transparent antistatic equipment.

example 1

A carrier film made of polyethylene (10 microns thick) was with a catalyst solution from 0.24 mol of triethyl aluminum and 0.12 mol of titanium tetrabutylate and 50 ml of silicone oil (AV 1000®) with a thickness of 10 µm.

This system was gassed with acetylene for 2.5 minutes and the resulting one Polyacetylene film stretched with the carrier film while still wet with catalyst.

A stretching rate of 300% was achieved. The mixture was then washed with HCl / methanol and, after drying (30 minutes at 0.1 torr and 30 ° C.), doped with saturated iodine / CCl ₄ solution, then the mixture was dried again at 20 ° C. and 0.1 torr.

The specific electrical conductivity was 4500 S / cm.  

Example 2

The procedure was as in Example 1, the resulting polyacetylene film was washed, however, then swollen in toluene for 12 hours and then dried to 550% with the carrier film, then the Film as described above, dried, doped and measured.

The specific electrical conductivity was in this case 5600 S / cm.

Example 3

The procedure was as in Example 2, except that it was only a polyisobutylene film with a thickness of 20 µm was used instead of a polyethylene film.

The stretching rate was 480% and the specific electrical conductivity 4900 S / cm.

All work was carried out under argon, the doping was carried out excluding light.

The dried polyacetylene films on their carrier film are transparent and translucent red. The transparent and conductive foils glued between glass plates. After 1 month of storage in the light and laboratory atmosphere (at 25 ° C) there was no change in the Conductivity or transparency observed.

Claims (5)

1. Transparent, electrically conductive multilayer films, built up from

• A) a film of electrically conductive polyacetylene with a layer thickness of 1 to 15 µm,
• B) a transparent, electrically non-conductive stretchable carrier material with a layer thickness of 1 to 1000 microns.

2. Transparent, electrically conductive multilayer films according to claim 1, characterized in that the transparent carrier material B) a film made of polyethylene, polypropylene or polybutadiene is. 3. Process for producing transparent, electrically conductive Multi-layer films, characterized in that under an inert gas atmosphere a solution of a transition metal catalyst on applies transparent, electrically non-conductive carrier material, then acetylene on the surface of the transparent, electrical non-conductive carrier material to a poly (acetylene) film polymerized with a thickness in the range of 2 to 15 microns, optionally stretches the polyacetylene film together with the carrier material and then doped the poly (acetylene) with a dopant. 4. Process for the production of transparent, electrically conductive Multi-layer films according to claim 3, characterized in that the Stretching immediately after the polymerization of acetylene he follows. 5. Process for the production of transparent, electrically conductive Multi-layer films, characterized in that stretching after washing out of the catalyst.