An example fluidic device may comprise a fluidic die, a unitary molded structure, and a fluidic fan-out structure—The unitary molded structure may comprise thermo-electric traces and fluidic channels and may be coupled to the fluidic die. A first dimension of the fluidic channels is between ten μm to two hundred μm, or less. The fluidic fan-out structure may also be coupled to the molded structure. The fluidic die, the molded structure, and the fluidic fan-out structure may be arranged such that a first fluidic channel of the fluidic channels is in fluid communication with an aperture of the fluidic die at a first extremity and to a fluidic fan-out fluid channel through hole of the fluidic fan-out structure at a second extremity.

A wafer structure is disclosed and includes a chip substrate and at least one inkjet chip. The chip substrate is a silicon substrate which is fabricated by a semiconductor process on a wafer of at least 12 inches. The at least one inkjet chip is directly formed on the chip substrate by the semiconductor process, and the wafer is diced into the at least one inkjet chip, to be implemented for inkjet printing.

A microfluidic die may include a microfluidic passage and a protective layer provided adjacent to internal surfaces of the microfluidic passage. The protective layer may include a protective nano-crystalline material and a protective amorphous matrix encapsulating the protective nano-crystalline material.

Examples include a fluid ejection die embedded in a molded panel. The fluid ejection die comprises a substrate, and the substrate includes an army of nozzles extending therethrough. The substrate has a first surface in which nozzle orifices are formed and a second surface, opposite the first surface, in which nozzle inlet openings are formed. The fluid ejection die is embedded in the molded panel such that the first surface of the substrate is approximately planar with a top surface of the molded panel. The molded panel has a fluid channel formed therethrough in fluid communication with the nozzle inlet openings of the array of nozzles.

A micro-valve includes an orifice plate including an orifice. The micro-valve further includes an actuating beam having a first end and a second end. The actuating beam also includes a base layer and a layer of piezoelectric material disposed on the base layer, a bottom electrode layer, and a top electrode layer. At an electrical connection portion of the actuating beam, the layer of piezoelectric material includes a first via, and a portion of the top electrode layer disposed within the first via, and a portion of the bottom electrode disposed beneath the first via. The actuating beam includes a base portion extending from the electrical connection portion and a cantilevered portion extending from the base portion. The cantilevered portion is movable in response to application of a differential electrical signal between the bottom electrode layer and the top electrode layer to one of open or close the micro-valve.

An example fluidic device may comprise a fluidic die and a support element coupled to the fluidic die. A fluid channel may be arranged within the support element and may define a fluid path through the support element and a fluid aperture of the fluidic die. A conductive element may be arranged in the fluid path and separated from the fluidic die. A conductive lead may provide an electrical coupling between a ground of the fluidic die and the conductive element.

A method for producing a substrate that includes a protective layer made from a metal oxide protecting silicon against corrosion and an organic resin layer on a substrate surface of a silicon substrate includes the following steps in this order: step A of forming the protective layer on the substrate surface; step B of removing the protective layer from the substrate surface in a region Z1 that is a part of the region in which the protective layer has been formed; and step C of providing an organic resin layer on the substrate surface in a region Z2 including the region Z1.

The microfluidic device has a plurality of ejector elements. Each ejector element includes a first region, accommodating a first fluid flow channel and an actuator chamber; a second region, accommodating a fluid containment chamber; and a third region, accommodating a second fluid flow channel. The fluid containment chamber is fluidically coupled to the first and to the second fluid flow channels. The second region is formed from a membrane layer, from a membrane definition layer, mechanically coupled to the membrane layer and having a membrane definition opening, and a fluid chamber defining body, mechanically coupled to the membrane definition layer and having a chamber defining opening, with a width greater than the width of the membrane definition opening. The width of the membrane is thus defined by the width of the chamber defining opening.

Examples of molded substrates are described herein. In some examples, a molded substrate may support integrated circuitry. In some examples, the molded substrate and the integrated circuitry are included in a circuitry package for a replaceable print component. In some examples, the molded substrate is relatively flat. In some examples, molding remnants may be on the molded substrate.

At times, devices, such as semiconductor devices, may be attached to molded structures. The molded structure may have through holes or channels through which fluids and gasses (among other things) may travel, A number of processes exist for creating molded structures with through holes or channels. For instance, build up processes, such as lithography on dry film, may be used to create molded structures with through holes or channels. Substrate bonding and/or welding may also be used to yield molded structures with through holes or channels.