A method of forming a multi-layered printed circuit board (PCB) may include, with a printing device, delivering a flexible medium to at least one fluid jet printhead. Printing an electrically conductive fluid on the flexible medium may be performed with at least one fluid jet printhead, to form a first conductive layer on the flexible medium. With the at least one fluid jet printhead, an electrically insulating fluid may be printed on the first conductive layer to form at least one insulating layer on the first conductive layer. With the at least one fluid jet printhead, the electrically conductive fluid may be printed on the at least one insulating layer to form a second conductive layer.

A system (100) and a method for marking a product (10) utilize an encoding that specifies the presence or absence of each of a plurality of luminescent materials, at least one of which exhibits a predetermined decay behavior. The decay behavior of a plurality of different materials is detected, and based thereon the presence or absence of the luminescent materials is inferred. A corresponding encoding specifies whether or not the respective materials are present. In this way, different encodings can be associated in advance with different properties of the product (10). The luminescent materials that specify the associated encoding can be applied to the product (10) as a mark (20) in accordance with a determined property of the product (10).

A method for producing a silver coating on a glass pane, wherein the silver coating includes at least one busbar and/or at least one solder contact surface, wherein the method includes printing the silver coating onto the glass pane by screen printing with a printing pattern having printing and non-printing regions and baking the printed silver coating, wherein the printing region of the printing pattern for the busbar and/or the printing region of the printing pattern for the solder contact surface is provided at least partially with a dot matrix or a line matrix.

An inkjet method for producing a solder mask in the manufacture of a Printed Circuit uses a solder mask inkjet ink containing at least one photo-initiator, at least one free radical polymerizable compound and at least one allyl sulfone compound as adhesion promoter. A high quality solder mask withstanding the high thermal stress during the soldering process while maintaining excellent physical properties is produced.

A system and method for printing and drying flavors and fragrances is provided. The system and method include a source of flavor or fragrance, a print assembly adapted to print the flavor or fragrance, a movable product conveyor that directly receives the printed flavor or fragrance and a drying component. As the movable product conveyor passes through or adjacent to the drying component, the printed flavor or fragrance is dried thereby providing a free-flowing flavor or fragrance product.

Systems and methods are presented for a swallowable pH sensor made entirely of edible and digestible materials. A substrate is provided and an electrical circuit pattern is printed on a top surface of the substrate. The electrical circuit pattern includes a plurality of interdigitated electrodes and an antenna portion. The substrate is rolled into a cylindrical form such that the interdigitated electrodes are positioned on an outermost layer of the rolled substrate. The rolling of the substrate also causes the antenna portion of the electrical circuit pattern to form into a coil shape.

Adhesive compositions that can be applied to substrates using inkjet printheads and cured to a hardened, tack-free state and readily rendered tacky on application of heat and pressure to accurately transfer foil to the substrates including one or more free-radical curing monomers, an oligomer/resin composition component including one or more oligomers and one or more inert thermoplastic resins that are soluble in the monomers, and, where required, one or more free radical photoinitiators.

A method of producing a solderable aluminum contact comprises formulating an ink, applying the ink to an aluminum substrate to form an ink layer on a surface of the aluminum substrate, and melting the ink layer. The ink includes a solderable element that is conductive. The melting of the ink layer forms an alloy on the surface of the aluminum substrate including the solderable element.

Methods and systems of fabrication of high resolution, high-throughput electrochemical sensing circuits on a substrate. High resolution electrochemical sensing circuits are printed by an effective additive technique to the substrate. Optionally, post-print annealing converts electrochemically inactive printed graphene into one that is electrochemically active. The printing can be by aerosol jet printing, but is not necessarily limited thereto. An example is inkjet printing and then the post-print annealing. Ink formulation would be adjusted for effectiveness with inkjet printing. Optionally biorecognition agents can be covalently bonded to the printed graphene for the purpose of electrochemical biosensing. High throughput fabrication of high-resolution graphene circuits (feature sizes in the tens of microns <50 m) for electrochemical biosensing is possible by chemical functionalization of the graphene surface with a biological agent.

A system (100) and a method for marking a product (10) utilize an encoding that specifies the presence or absence of each of a plurality of luminescent materials, at least one of which exhibits a predetermined decay behavior. The decay behavior of a plurality of different materials is detected, and based thereon the presence or absence of the luminescent materials is inferred. A corresponding encoding specifies whether or not the respective materials are present. In this way, different encodings can be associated in advance with different properties of the product (10). The luminescent materials that specify the associated encoding can be applied to the product (10) as a mark (20) in accordance with a determined property of the product (10).