A sheet manufacturing apparatus includes a web forming section that accumulates a feedstock containing fibers in a gas to form a second web, an arranging section that arranges a magnetic body on the second web while the second web is transported, and a processing section that processes the second web on which the magnetic body is arranged into a sheet.

A method of manufacturing a security paper is presented. The method comprises: preparing a composition A containing a mixture of softwood and hardwood pulp, and preparing a mixture of a refined pulp and magnetic wires having predetermined magnetic properties; preparing a composition C by blending the mixture B and the composition A; diluting the composition C, and forming a pulp single layer D including the magnetic wires at a predetermined density; removing moisture from the pulp single layer D; forming at least one protective coating layer on at least one side of the paper; and calendering the paper, thereby obtaining a security paper structure with the magnetic wires fully embedded in the pulp single layer.

A method for applying an anti-counterfeit signature on a product, and an anti-counterfeit signature. The method includes selecting a substrate and a type of signature and forming a signature of the selected type on the substrate with atomic layer deposition, ALD, wherein forming the signature includes applying at least one layer having a predetermined property configured to be detected with an analysis method on the substrate by atomic layer deposition, ALD.

A method for applying an anti-counterfeit signature on a product, and an anti-counterfeit signature. The method includes selecting a substrate and a type of signature and forming a signature of the selected type on the substrate with atomic layer deposition, ALD, wherein forming the signature includes applying at least one layer having a predetermined property configured to be detected with an analysis method on the substrate by atomic layer deposition, ALD.

In order to increase the security of value or security documents 100, a multi-luminescent security element 400 is provided which contains at least one first luminescence means 510 and at least one second luminescence means 520. The first luminescence means 510 can be excited under first excitation conditions Sp-1 for the purpose of luminescence, and the second luminescence means 520 can be excited under second excitation conditions Sp-2 for the purpose of luminescence, said second excitation conditions Sp-2 differing from the first excitation conditions Sp-1. The multi-luminescent security element 400 is additionally equipped with at least one absorber means 600 which prevents an excitation of the at least one first luminescence means 510 under the second excitation conditions Sp-2 for the purpose of luminescence.

In order to increase the security of value or security documents 100, a multi-luminescent security element 400 is provided which contains at least one first luminescence means 510 and at least one second luminescence means 520. The first luminescence means 510 can be excited under first excitation conditions Sp-1 for the purpose of luminescence, and the second luminescence means 520 can be excited under second excitation conditions Sp-2 for the purpose of luminescence, said second excitation conditions Sp-2 differing from the first excitation conditions Sp-1. The multi-luminescent security element 400 is additionally equipped with at least one absorber means 600 which prevents an excitation of the at least one first luminescence means 510 under the second excitation conditions Sp-2 for the purpose of luminescence.

Methods for marking cellulosic products, including cellulosic fibers such as lyocell and cellulosic films, including methods for marking such products with a detectable nucleic acid marker to identify and validate the origin or authenticity of the products or items manufactured using such products. Detectably-marked cellulosic products marked with nucleic acid markers for authentication, validation and tracking are also provided.

Methods for marking cellulosic products, including cellulosic fibers such as lyocell and cellulosic films, including methods for marking such products with a detectable nucleic acid marker to identify and validate the origin or authenticity of the products or items manufactured using such products. Detectably-marked cellulosic products marked with nucleic acid markers for authentication, validation and tracking are also provided.

An optical device is formed by hot stamping a demetallized hologram to an optically variable foil or to a coating of optically variable ink. In another embodiment a hologram is hot stamped to a banknote or document printed with a color-shifting ink.

A method of forming a security document, comprises providing a thread comprising at least one region of heat-transformable material, this material having an optical effect which is transformable in response to applied heat. The thread is integrated with a document substrate material during a substrate forming process, so as to produce a security document substrate having at least one windowed region in which the thread is exposed at the substrate surface, and at least one bridge region in which the thread is not exposed. A patterned heat process is then applied, causing a structural modification in the heat-transformable layer of the thread so as to produce an observable optical effect representative of the heat pattern at one or more predetermined positions with respect to one or more of the said windowed region or bridge region. Security documents bearing threads with such optically transformable materials are also disclosed.