A method can be used to generate a fluid droplet pattern for an imprint lithography process using a fluid dispense system having fluid dispense ports. The method can include determining a fluid droplet pattern for dispensing a formable material onto a substrate, during a first pass, dispensing the formable material along a stitch line to form a first part of the fluid droplet pattern for an imprint field, where the stitch line runs from a first corner to a second corner of the imprint field. The method can also include offsetting the substrate and the fluid dispense ports relative to each other after dispensing the formable material during the first pass, and during a second pass, dispensing the formable material along the stitch line onto the substrate to form a second part of the fluid droplet pattern for the imprint field. An apparatus can be configured to carry out the method.

The present invention relates to a method of bonding substrates and a substrate for displays manufactured by the same. In an embodiment, the method comprises (a) printing a first photocurable adhesive ink on the lower substrate to form a pattern; (b) photocuring the pattern to form a spacer on the lower substrate; (c) printing a second photocurable adhesive ink on the lower substrate, which includes the spacer, to form an adhesive layer; (d) irradiating the adhesive layer with light; and (e) laminating the upper substrate to the lower substrate via the adhesive layer, wherein the upper and lower substrates are transparent or opaque, and wherein the upper and lower substrates comprise the same or different materials.

A method can be used to generate a fluid droplet pattern for an imprint lithography process using a fluid dispense system having fluid dispense ports. The method can include determining a fluid droplet pattern for dispensing a formable material onto a substrate, during a first pass, dispensing the formable material along a stitch line to form a first part of the fluid droplet pattern for an imprint field, where the stitch line runs from a first corner to a second corner of the imprint field. The method can also include offsetting the substrate and the fluid dispense ports relative to each other after dispensing the formable material during the first pass, and during a second pass, dispensing the formable material along the stitch line onto the substrate to form a second part of the fluid droplet pattern for the imprint field. An apparatus can be configured to carry out the method.

A method for locally adjusting the glossiness of a printed image includes printing an image onto a recording medium in multiple swaths and locally adjusting the ink volume for each swath. A printer for printing an image onto a recording medium includes a control unit configured to perform the method.

A sensor can be manufactured by printing a working electrode onto a substrate using aerosol jet printing. Sensing chemistry (e.g., enzyme-based ink that including detection chemistry) also can be printed onto the working electrode using aerosol jet printing. A reference electrode also can be printed on the substrate at a position spaced along the substrate from the working electrode. In certain examples, the substrate can be positioned within a lumen of a skin piercing member of a sensor module.

A method of manufacturing a sensing decal (400), a sensing decal and a method of providing a sensing decal to a device (702), in which the method of manufacture includes providing a flexible release layer (401) having a substantially non-uniform surface (405) and printing a conductive ink layer (402) onto the non-uniform surface. An adhesive layer (403) is printed onto the conductive ink layer to produce the sensing decal. The decal can then be applied to a surface (701) of a device and the flexible release layer is removed.

The disclosure relates to systems and methods for photonic sintering of conductive ink compositions with metal nanoparticles. Specifically, the disclosure relates to methods and systems for sintering ink compositions with metal nanoparticles using an illumination source comprising an array of pulsed light emitting diodes (LEDs).

The present invention relates to a body fluid analyzing apparatus and a body fluid analyzing method using the same. This body fluid analyzing apparatus includes: an ejecting unit configured to eject a body fluid; a main body unit configured to support an ejecting unit; and a printing member on which the body fluid ejected through the ejecting unit is printed, wherein the body fluid is printed on a surface of the printing member while the printing member moves in one direction relative to the ejecting unit.

Described herein are methods for printing conductive ink on a substrate. In one embodiment, the method for printing a conductive ink on a substrate, comprises (a) printing, using a printer, one or more layers of a non-conductive material on a surface of the substrate such that one or more channels are formed to produce a template on the surface of the substrate; and (b) printing one or more layers of the conductive ink within the one or more channels In another embodiment, substrates produced by the methods described herein are provided. In another embodiment, systems for implementing the procedures described herein are provided.

A method for applying a patterned structure on a surface, comprising providing a donor substrate (1) comprising donor material (1a) between a light source (3) and a receiving surface (5), providing by means of the light source (3) a light pulse (3a) directed to the donor substrate (1), the light pulse (3a) being configured to cause the donor material (1a) to be transferred from the donor substrate (1) onto the receiving surface (5), wherein the donor substrate (1) comprises a pattern (2) of donor material (1a) on discrete portions (2a) of the donor substrate (1). The pattern (2) on the donor substrate (1) is transferred so as to form a pattern (4) of donor material (1a) on the receiving surface (5).