A sheet assembly can be cut into one or more cards. The sheet assembly includes an upper sheet configured to receive a first printing of first indicia for the one or more cards, a polymer core coupled with the upper sheet, and a lower sheet configured to receive a second printing of second indicia for the one or more cards. The lower sheet is coupled with the polymer core with the polymer core disposed between the upper sheet and the lower sheet. The upper sheet, polymer core, and/or the lower sheet is or are formed from a polymer binder with inorganic particles dispersed in the polymer binder. The inorganic particles can have a first density of the inorganic particles that is less than four times a second density of the polymer binder and/or a mass-median-diameter (D.sub.50) of the inorganic particles can be larger than ten microns in size.

The invention relates to an improved method for the partial coloring, in particular for the color laser engraving, of plastic parts, in particular thermoplastic plastic parts, more particularly thermoplastic plastic parts that have a multi-layered structure, to the resulting partially colored, preferably color laser engraved, plastic parts, in particular thermoplastic plastic parts, and to a device for the partial coloring of plastic parts.

The invention relates to an improved method for the partial coloring, in particular for the color laser engraving, of plastic parts, in particular thermoplastic plastic parts, more particularly thermoplastic plastic parts that have a multi-layered structure, to the resulting partially colored, preferably color laser engraved, plastic parts, in particular thermoplastic plastic parts, and to a device for the partial coloring of plastic parts.

Provided are a resin composition which can provide a resin sheet having excellent light shielding properties with titanium oxide sufficiently dispersed, as well as a resin sheet, a multilayered article and a card produced therefrom. The resin composition includes a polycarbonate resin in an amount of 30 to 95 parts by mass, and titanium oxide in an amount of 5 to 40 parts by mass, wherein the titanium oxide has an average primary particle size of 0.22 to 0.26 .Math.m based on measurement of an image observed by a scanning electron microscope (SEM), and wherein the titanium oxide has an Si content of 1.0 to 1.8 % by mass and an Al content of 1.6 to 2.2 % by mass based on measurement by X-ray fluorescence (XRF) analysis after firing at 700° C. for 2 hours.

There is described a method of manufacturing a security article, said method comprising the steps of: introducing into an offset printing device a transparent film comprising a non-fibrous substrate layer of regenerated cellulose; disposing an opacification layer on at least a portion of at least one surface of said film by a first offset printing step; and disposing printed information on at least a portion of said opacification layer by a second offset printing step.

There is described a method of manufacturing a security article, said method comprising the steps of: introducing into an offset printing device a transparent film comprising a non-fibrous substrate layer of regenerated cellulose; disposing an opacification layer on at least a portion of at least one surface of said film by a first offset printing step; and disposing printed information on at least a portion of said opacification layer by a second offset printing step.

A laminated transaction card may comprise post-consumer polyethylene with a thickness of at least 30% of a thickness of the laminated transaction card. A first polymer- based layer comprising polyvinyl chloride is coupled to a first surface of the core layer by a first adhesive layer. A second polymer-based layer comprising polyvinyl chloride is coupled to a second surface of the core layer by a second adhesive layer. The first adhesive layer and the second adhesive layer comprise an adhesive formulated to bond the post-consumer polyethylene and the polymer-based layers.

Systems, methods and apparatus are provided for light-based authentication of a payment card. The payment card may include a randomized mix of materials. The materials may include transparent or translucent materials. A light source may shine light on a surface of the payment card. Light passing through the card may generate a light pattern that is unique to the payment card. The light pattern may be captured and compared to a reference light pattern to authenticate the payment card. In some embodiments, photodetectors may detect light patterns generated through interactions with the card materials.

Systems, methods and apparatus are provided for light-based authentication of a payment card. The payment card may include a randomized mix of materials. The materials may include transparent or translucent materials. A light source may shine light on a surface of the payment card. Light passing through the card may generate a light pattern that is unique to the payment card. The light pattern may be captured and compared to a reference light pattern to authenticate the payment card. In some embodiments, photodetectors may detect light patterns generated through interactions with the card materials.

In a general aspect, orientation information is used to generate a unique code. In some aspects, orientation information is extracted from an object. The object includes multiple elements, and the orientation information indicates the relative spatial orientations of the respective elements. The orientation information can be extracted, for instance, by a scanner system that detects the elements. A unique code is generated for the object based on the orientation information. In some examples, the elements are diamond particles that each have one or more color centers, and the orientation information is extracted by detecting the color centers.