DE10321152A1 - Method for processing an electroluminescent element and electroluminescent element processed using this method - Google Patents

Abstract

Method for processing an electroluminescent element (1) with a laser beam to influence the lighting properties of the electroluminescent element, which consists of a composite which has at least the following interconnected layers: DOLLAR A - at least one outer cover (11, 12) on the front, DOLLAR A - At least one electrically conductive, transparent front-side electrode layer (5), DOLLAR A - at least one luminescent layer (2) with inorganic luminophores embedded in a polymer matrix, DOLLAR A - at least one electrically conductive back-side electrode layer (6) and DOLLAR A - at least one back-side outer layer Cover (10). DOLLAR A To influence the lighting properties of the electroluminescent element, it is provided that the laser beam is guided through at least one of the outer covers (10, 11, 12) through at least one of the electrode layers (5, 6) and that its intensity, wavelength and Pulse duration should be chosen so that the at least one outer cover (10, 11, 12) remains undamaged and at least one of the electrodes (5, 6) is locally ablated.

Description

The The invention relates to a method for processing an electroluminescent Elements with a laser beam to influence the lighting properties of the electroluminescent element, which consists of a composite, which has at least the following interconnected layers: at least an outer cover, at least one electrically conductive, transparent electrode layer on the front, at least one luminescent layer with embedded in a polymer matrix inorganic luminophores and at least one electrically conductive rear Electrode layer.

The The invention also relates to an electroluminescent element which consists of a composite that connects at least the following Has layers: at least one outer cover, at least an electrically conductive, transparent electrode layer on the front, at least one luminescent layer with embedded in a polymer matrix inorganic luminophores and at least one electrically conductive rear Electrode layer.

An electroluminescent element of this type is out DE 4310082 A1 known. In the known electroluminescent element, a luminous layer containing zinc sulfide electroluminophores is produced by extrusion in the form of a film. The film extrusion process has the disadvantage that the degree of filling with electroluminescent pigments is limited. In order to obtain a satisfactory luminosity, thick luminescent layers must be used, which in turn require larger operating voltages. It is not known that the electroluminescent element can be processed with a laser in order to influence its lighting properties.

Out WO 93/00695 is a sheet-like electroluminescent lamp known in which, among other things, an electrically conductive layer is isolated from the edge area with a laser beam. It will Electrode material on the exposed surface before completion of the Lamp worn out.

Out WO 99/62668 is a method for producing electroluminescent lamps known in which a laser beam material of a multilayer structure removed, the laser beam being guided in a spiral overlapping manner. A laser beam with different energy is used to remove different layers. The removal of the material layers takes place on the exposed surface before completion of the Lamp.

outgoing From this prior art, the invention is based on the object a method for processing an electroluminescent element and an electroluminescent device processed using such a method To create element, the flexible and individual design options Offer. The electroluminescent element should in particular be inexpensive to manufacture and over have a high luminosity.

Regarding the method, this object is achieved in that a laser beam through the at least one outer cover is passed through to at least one of the electrode layers and that its Intensity, wavelength and pulse duration selected be that the at least one outer cover undestroyed remains and at least one of the electrodes is ablated locally.

By the method according to the invention the possibility created an industrially mass-produced electroluminescent Subsequent element individually design, be it in desired areas, for example in the form of a label, the electroluminescence is switched off will, or that areas the electrodes are decoupled globally from the power supply, possibly with the aim of to provide these areas with separate power supplies enable changing segmented ads.

advantageous Refinements of the method are based on the dependent claims remove.

Especially In this context, however, an embodiment should be emphasized of the method in which an electroluminescent element is processed is at least one of the two electrode layers Thickness of less than 10 μm, preferably less than 3 μm, particularly preferably has between 0.1 and 0.4 μm. It has been here shown that such an electrode layer without impairment of the layer structure on the inside, that is, within the composite from several layers, can be removed locally. Surrender themselves amazingly precise Contours.

According to a particularly advantageous embodiment of the method, the design options of the electroluminescent element are further increased if an electroluminescent element is processed in which the front cover comprises at least one decorative film which has a polymer matrix which is transparent to the laser beam and into which laser initiators are at least partially incorporated which give a gradable gray color when irradiated with a laser beam give. With a method designed in this way, complete images can be designed which are illuminated from the background by the electroluminescent radiation.

excellent Results in contouring the electrodes can be achieved if after a variant an electroluminescent element is processed in the method, in which the luminescent layer is made from a solution by means of casting thin film comprises into the electroluminescent pigments with a diameter smaller 40 μm, preferred smaller than 20 μm, especially preferably less than 15 μm, added are. Thanks to their special homogeneity and surface smoothness, a luminous layer designed in this way is also particularly homogeneous and thin electrodes be created that are excellent for the Laser ablation according to the inventive method are suitable.

Usual thermoplastic polymeric or copolymeric layers or films of, for example Polycarbonate (PC) polyalkylene terephthalates, aromatic polyesters, Polyamide (PA), polyacrylate, polymethacrylate, polymethyl methacrylate (PMMA), Polyurethane (PUR), polyoxymethylene (POM), ABS graft polymers, Polyolefins such as polyethylene (PE) or polypropylene (PP), polystyrene (PS), Polyvinyl chloride (PVC), polyimide (PI), polyetherimide (PEI), polyether and polyether ketones (PEK), individually or as a blend of different Polymers can be used and the like in the optically visible wavelength range transparent plastic layers or films generally and without additives high transparency of NIR activators even in the NIR wavelength range on.

If now essentially below one for NIR radiation transparent layer or layer sequence an NIR absorbing layer such as a thin ITO (indium tin oxide) and / or tin oxide layer and / or a polymeric electrically conductive layer and / or an opaque thin Aluminum layer, so this flat electrically conductive layer through a correspondingly focused laser beam is heated in such a way that a high impedance is brought about, i.e. an electrode contour is produced. A spaced laser track can increase the electrical insulation of two adjacent flat conductive layers be effected.

Because usual printing inks good permeability have in the NIR range, the surface of the electroluminescent Elements can be printed without the laser treatment of the element becomes.

It has proven to be particularly advantageous when the electrical conductive lower electrode layer made of aluminum by means of sputtering or vapor deposition and with layer thicknesses of, for example, up to 3 μm or more, in particular, however, 0.1 to 0.4 μm directly on the dielectric layer or film respectively is applied to a lower auxiliary film or carrier film. Back electrodes manufactured in this way from a thin ablatable layer have good electrical conductivity on and additionally effect a good reflection of the light generated in the EL phosphors in the direction of the upper transparent cover electrode and cause thereby increasing the Light intensity of the EL element.

manufacturing technology this type of contouring the back electrode has the great advantage that this is very late Time in the manufacture of the EL element can be made or must and so the positioning exactly on the graphic design of the Front can be matched.

In a further development of this type of electrode contouring by means of Laser beam was found to be transparent and electric conductive upper electrode layer contoured by laser beam can be, but this must Process before the graphic design of the surface or the light exit side surface the electrically conductive coated EL thin film done or have to Printing inks are used that are transparent at 1,064 nm as an example are or have such a low absorption that the laser beam used for contouring without significant weakening and / or thermal activation of the graphic design respectively the one for it used printing inks is passed through.

According to the invention, an EL element in multiple use or in roll form is now produced in the production form which is preferred in terms of production technology in such a way that the following processes are only carried out in a laser processing step at a late stage or at the end of the production process, with each laser process step also being possible on its own : Laser marking of the graphic design, laser ablation of the transparent upper electrode, laser ablation of the opaque or transparent lower electrode from above and / or from below, laser contouring of an individual EL element from the multiple use, laser separation of an EL element from the multiple use, laser labeling of the Decorative film, in which case the decorative film or decorative layer consists of a transparent polymer matrix for the laser beam used, into the so-called laser initiators in the form of Carbon black or carbon particles, of iriodin particles in the form of flakes, of copper (II) hydroxide phosphate or molybdenum (VI) oxide or of commercially available pigments and / or polymer-soluble dyes and the like, elements which are incorporated when using a laser beam of a suitable wavelength, especially of 1064 nm of a Nd: Yag laser, enable a high-contrast and sharp-contour graphic design.

In a further production-technically preferred embodiment of the manufacturing process the individual layers are designed graphically in roll form and by means of a continuous lamination process using pressure and optionally laminated temperature to a composite. In particular are very thin foils due to the use of a roll process or layers can be processed. Basically, however, with this Process also sheet formats editable, but then the Layer thicknesses of the individual layers for a sheet processing company Process adapted become.

In a further embodiment according to the invention it was found that, for example, using the so-called thin film casting method, polycarbonate or polyvinyl fluoride (PVF) or polyvinylidene fluoride (PVdF) thin films with thicknesses from 10 to 70 μm, preferably 20 to 30 μm with a high degree of filling made of inorganic zinc sulfide electroluminophores can be. In addition, in the polymer matrix contains both converting dyes and pigments and other substances that improve electroluminescence excitation be added.

at Use correspondingly fine-grained zinc sulfide Electroluminophores with a preferably cubic crystal structure can thus very thin EL active Films are made.

there the polymer matrix can be used as a dielectric.

There cast thin films an extremely smooth surface can have very good and thin, flat electrodes be applied by means of vacuum technology. The coating can done on one or both sides and both coatings can be transparent accomplished be or a layer opaque as the lower reflective electrode.

According to the invention now found that after lamination of such an EL-active thin film and an additional one support film and / or adhesive adhesive layer with a release film with a transparent and, if applicable, graphically designed cover foil, the laser contouring the flat Electrodes can be carried out very easily and inexpensively and precisely can and such EL elements can be made particularly thin, one have high dielectric strength and high light emission is achieved with a low AC voltage supply.

According to the invention in such EL active cast thin films fine-grained uncapsulated or microencapsulated zinc sulfide electroluminophores are used become. Instead of or in addition A barrier coating can be used to microencapsulate the EL pigments the cast thin film in the form of transparent or opaque metal-oxidic, metal-nitridic, Metal carbide, metal oxynitride, metal oxyboride layers and combinations of these layers in conjunction with at least one Polymer layer in the form of an acrylate or methacrylate polymer or one Combination of both polymers mentioned on the top and bottom Side of the EL thin film be applied. In this way, the life of the EL element elevated become.

The invention is based on the in the 1 and 2 schematically illustrated preferred embodiments explained in more detail.

In 1 an EL element structure in cross section based on a cast EL thin film is shown schematically by means of lamination.

According to the invention, an EL polymer matrix can now 2 can be used in the form of a thin film from a roll and can in particular be coated on one or both sides by means of a flat electrically conductive electrode 5 . 6 respectively.

A decorative film 11 can now have a graphic design on the bottom 12 can be provided and can use common printing processes for graphic design 12 largely transparent films are used, in particular the screen printing process, as well as offset and flexographic printing and digital printing techniques, using opaque to translucent or translucent colors, as well as special effect colors from metallic to luminescent and long-afterglow pigments in the form of strontium Aluminates and the like. Then an adhesive adhesive layer or an adhesion promoter layer or a hot melt adhesive layer 23 applied.

Furthermore, a base substrate 10 with also a coating 24 provided and can now position these 3 layers to each other and to an EL element 1 get connected. Depending on the requirements, cold lamination under pressure or lamination at elevated temperatures can now be carried out rature and with pressure. In the case of cold lamination, adhesive adhesive coatings with a protective or peel-off film must clearly be used and this protective film must be removed before the joining process.

According to the invention, the adhesive layers can furthermore 23 . 24 can also be provided with a water vapor barrier property, the upper layer preferably 23 transparent and the bottom layer 24 opaque or transparent.

According to the invention, ablation or contouring of the planar electrodes can now be performed using a laser beam 5 . 6 through layers or foils arranged above.

That in the 2 illustrated electroluminescent element 1 has a front outer cover, which consists of two layers, namely the layers 11 and 12 consists. The outer cover layer 12 can contain a graphic design that consists of printing inks that are largely transparent in the NIR range. The inner surface layer 12 can be doped in places with laser initiators in the form of soot particles, carbon particles, iriodin particles in the form of flakes, copper (II) hydroxide phosphate or molybdenum (VI) oxide or commercially available pigments and / or polymer-soluble dyes, the function of which will be described in more detail later is explained.

On the shift 11 follows an electrode layer 5 made of indium tin oxide (ITO). The electrode layer 5 is both electrically conductive and transparent to visible light.

On the electrode layer 5 follows a layer of light 2 , which has a polymer matrix with embedded fine-grain luminophores made of zinc sulfide. The inorganic zinc sulfide luminophores can be microencapsulated with metal oxides and / or metal nitrides and can be protected against moisture in this way. The luminescent layer 2 is a thin film cast from a solution.

To the luminescent layer 2 close two dielectric layers 13 and 14 on.

On the dielectric layer 14 follows a back electrode layer 6 which can consist, for example, of a reflective opaque aluminum layer.

Finally follows the electrode layer 6 a back outer cover 10 ,

In the selected example is the electrode layer 5 directly on the luminescent layer 2 applied by vapor deposition or sputtering. This is possible because of the luminescent layer 2 is a thin film cast from a solution, which is distinguished by a particularly smooth surface, to which very thin flat electrodes can be applied by means of vacuum technology.

The electrode is in the same way 6 on the dielectric layer 14 applied, which in turn with the further dielectric layer 13 and the luminescent layer 2 is connected by lamination.

The semi-finished electroluminescent element is processed as follows:
With a laser 26 becomes the outer top layer 12 processed, with ablation or carbonization, so blackening can be achieved. Different effects can be achieved through a multi-layer graphic design. For example, individual layers can be ablated, i.e. removed by evaporation. Different color effects can be achieved by exposing various layers of color.

With another laser 27 with appropriate selection of the wavelength, intensity and pulse duration, a kind of internal ablation of the transparent front electrode 5 realized. The prerequisite for this is that the cover layers 11 . 12 , including the graphic design attached there, do not significantly absorb the laser beam. If an Nd: YAG laser is emitted at a wavelength of 1064 nm, this requirement can be met well. It is also essential that the laser beam is well focused and has only a small local extent. The electrode layer 5 must be very thin and have a good absorption at the laser wavelength used, which is very well fulfilled when using an Nd: YAG laser at 1064 nm, since indium-tin oxide and tin oxide layers absorb at 1064 nm.

The achievable ablation of the opaque rear electrode 6 by means of another laser source 28 , so from the front, through the layers 12 . 11 . 5 . 13 . 14 through, is only possible if the absorption of the back electrode 6 for the laser beam used is significantly higher than the absorption of the other layers, in particular the electrode layer on the front 5 , Since a thin and reflective aluminum layer is selected as the back electrode, a fine adjustment must be made here. In addition, the luminescent layer must be left out in the processing area, since electroluminescent pigments have too high an absorption capacity for the laser beam for such ablation purposes.

With another laser 29 can also separate the entire element with a correspondingly high laser power 1 be performed. In this way, individual elements can be manufactured from multiple uses. With such a cutting process, complete contours can be cut. The creation of perforations and predetermined breaking points is also possible. The laser wavelength, the pulse rate up to a few 20 kHz and the pulse power as well as the beam shape, i.e. whether there is a Gaussian distribution or a rectangular pulse profile, are very important. Attention must also be paid to cooling with inert gas and to the evacuation of the vaporized substances. In high-performance separation processes, in particular in addition to the Nd: YAG laser mentioned, a CO ₂ laser with generally much higher power can be used very efficiently.

The front cover layer is covered with another laser 30 processed. The graphic design of the decorative film or top cover layer 11 is exemplified by the laser 30 shown schematically. This is the focus of the laser 17 the laser source 30 set so that inside the top cover layer 11 or the decorative film 11 there is sufficient energy density and in this way a tint is achieved in conjunction with laser initiators built into the polymer matrix. Examples of so-called laser initiators are those in the form of carbon black or carbon particles, iriodine particles in the form of flakes, copper (II) hydroxide phosphate or molybdenum (VI) oxide or commercially available pigments and / or polymer-soluble dyes and the like elements which, when using a laser beam of a suitable wavelength, in particular of 1064 nm of an Nd: Yag laser, enable a high-contrast and sharply contoured graphic design. Such a process is best known on the basis of special polycarbonate foils in the identification area, and it can be used to produce very detailed gray wedge tints up to a complete blackening.This process can be used to achieve an individual graphic design on the inside without damaging the surface and can be combined with it excellent visualization can be achieved with an EL illuminated field underneath.

In a further embodiment of the present invention, the back electrode 6 also from the bottom using a laser beam from a laser source 31 can be contoured or ablated and fine points or lines can be created in this way. In this case, the base substrate must clearly 10 and / or the lower cover layer 15 largely non-absorbent for the laser beam used.

Claims (41)

Process for processing an electroluminescent element ( 1 ) with a laser beam to influence the lighting properties of the electroluminescent element, which consists of a composite that has at least the following interconnected layers: - at least one outer cover ( 10 . 11 . 12 ), - at least one electrically conductive, transparent electrode layer on the front ( 5 ), - at least one luminescent layer ( 2 ) with in a polymer matrix ( 3 ) embedded inorganic luminophores ( 4 ), and - at least one electrically conductive rear electrode layer ( 6 ), characterized in that the laser beam through the at least one outer cover ( 10 . 11 . 12 ) through to at least one of the electrode layers ( 5 . 6 ) and that its intensity, wavelength and pulse duration are selected so that the at least one outer cover ( 10 . 11 . 12 ) remains undamaged and at least one of the electrodes ( 5 . 6 ) is ablated locally. A method according to claim 1, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has metal oxides. A method according to claim 1 or 2, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has indium tin oxide. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) has an electrically conductive polymer. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has aluminum. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has carbon. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has silver. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) Has copper. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one of the two electrode layers ( 5 . 6 ) has a thickness of less than 10 μm, preferably less than 3 μm, particularly preferably between 0.1 to 0.4 μm. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which a front cover ( 11 . 12 ) is provided, the at least one decorative film ( 11 ) which has a transparent polymer matrix for the laser beam, into which laser initiators are incorporated at least in places, which give a gradable gray coloration when irradiated with a laser beam. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which at least one cover ( 10 ) is arranged on the back. Method according to one of the preceding claims, characterized in that an electroluminescent element ( 1 ) is processed in which the luminescent layer ( 2 ) comprises a thin film produced from a solution by means of a casting process, in which electroluminescent pigments with an average diameter of less than 40 μm, preferably less than 20 μm, particularly preferably less than 15 μm, are embedded. A method according to claim 12, characterized in that encapsulated electroluminescent pigments are used. A method according to claim 12, characterized in that electroluminescent Pigments are used by at least one water vapor barrier Layer are encapsulated. A method according to claim 12, characterized in that electroluminescent Pigments are used which are characterized by at least one metal nitride and / or metal oxide layer are encapsulated. Method according to one of claims 12 to 15, characterized in that the luminescent layer formed from the thin film ( 2 ) has a thickness of 10 to 70 μm, preferably 20 to 40 μm. Method according to one of claims 12 to 16, characterized in that the luminescent layer formed from the thin film ( 2 ) at least on one side with a conductive material to form at least one of the two electrode layers ( 5 . 6 ) is coated. A method according to claim 17, characterized in that the Coating is carried out using vacuum technology. A method according to claim 17, characterized in that the Coating takes place by means of vapor deposition or sputtering. Electroluminescent element ( 1 ), which is processed with a laser beam to influence its lighting properties and consists of a composite that has at least the following interconnected layers: - at least one outer cover ( 10 . 11 . 12 ), - at least one electrically conductive, transparent electrode layer on the front ( 5 ), - at least one luminescent layer ( 2 ) with in a polymer matrix ( 3 ) embedded inorganic luminophores ( 4 ) and - at least one electrically conductive rear electrode layer ( 6 ), characterized in that the at least one cover ( 10 . 11 . 12 ) is transparent to a laser beam, and at least one of the two electrode layers ( 5 . 6 ) has a material that can be ablated by means of a laser beam. Electroluminescent element ( 1 ) according to claim 20, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has metal oxides. Electroluminescent element ( 1 ) according to claim 20 or 21, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has indium tin oxide. Electroluminescent element ( 1 ) according to one of claims 20 to 22, characterized in that at least one of the two electrode layers ( 5 . 6 ) has an electrically conductive polymer. Electroluminescent element ( 1 ) according to one of claims 20 to 23, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has aluminum. Electroluminescent element ( 1 ) according to one of claims 20 to 24, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has carbon. Electroluminescent element ( 1 ) according to one of claims 20 to 25, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has silver. Electroluminescent element ( 1 ) according to one of claims 20 to 26, characterized in that at least one of the two electrode layers ( 5 . 6 ) Has copper. Electroluminescent element ( 1 ) according to one of claims 20 to 27, characterized in that at least one of the two electrode layers ( 5 . 6 ) has a thickness of less than 10 μm, preferably less than 3 μm, particularly preferably between 0.1 to 0.4 μm. Electroluminescent element ( 1 ) according to one of claims 20 to 28, characterized in that at least one cover ( 11 . 12 ) is arranged on the front, the at least one decorative film ( 11 ) which has a transparent polymer matrix for the laser beam, into which laser initiators are incorporated at least in places, which give a gradable gray coloration when irradiated with a laser beam. Electroluminescent element ( 1 ) according to one of claims 20 to 29, characterized in that at least one cover ( 11 . 12 ) is arranged on the back. Electroluminescent element ( 1 ) according to one of claims 20 to 30, characterized in that the luminous layer ( 2 ) comprises a thin film produced by means of a casting process, in which electroluminescent pigments with a diameter of less than 30 μm, preferably less than 20 μm, particularly preferably less than 15 μm, are embedded. Electroluminescent element ( 1 ) according to claim 31, characterized in that the luminous layer ( 2 ) forming thin film contains unencapsulated electroluminescent pigments. Electroluminescent element ( 1 ) according to claim 31, characterized in that the luminous layer ( 2 ) forming thin film contains electroluminescent pigments which are encapsulated by at least one water vapor barrier layer. Electroluminescent element ( 1 ) according to claim 31, characterized in that the electroluminescent pigments are encapsulated by at least one metal oxide and / or metal nitride layer. Electroluminescent element ( 1 ) according to one of Claims 31 to 34, characterized in that the luminescent layer (formed from the thin film) 2 ) has a thickness of 10 to 70 μm, preferably 20 to 40 μm. Electroluminescent element ( 1 ) according to one of claims 31 to 35, characterized in that the luminescent layer formed from the thin film ( 2 ) at least on one of its two sides with a conductive material for forming at least one of the two electrode layers ( 5 . 6 ) is coated. Electroluminescent element ( 1 ) according to claim 36, characterized in that the electrode layers ( 5 . 6 ) are applied using vacuum technology. Electroluminescent element ( 1 ) according to claim 37, characterized in that the electrode layers ( 5 . 6 ) are evaporated or sputtered. Electroluminescent element ( 1 ) according to claim 36, characterized in that at least one of the two electrode layers ( 5 . 6 ) with a polymer film by means of lamination on the luminous layer ( 2 ) is attached. Electroluminescent element ( 1 ) according to claim 30, characterized in that the rear electrode layer ( 6 ) is opaque and / or reflective or transparent or translucent. Electroluminescent element ( 1 ) according to one of Claims 20 to 40, characterized in that it has at least one water vapor barrier layer with a water vapor permeability rate of less than 0.005 g / m ² / 24h at 38 ° C and 100% relative atmospheric humidity to protect the luminescent layer ( 2 ) is protected against moisture from outside.