A method for treating a substrate having millimeter and/or micrometer and/or nanometer structures. The method includes applying at least one protective material to the structures, wherein the at least one protective material can be dissolved in a solvent, and the structures are produced by an imprinting process.

A motor base assembly for a storage drive assembly includes a basewall and a plurality of sidewalls extending from the basewall to define an interior of the motor base assembly. The motor base assembly also includes a stiffener support portion disposed within the interior of the motor base assembly. The stiffener support portion includes a stiffener guide slot and a hole adjacent to the stiffener guide slot. The stiffener guide slot is configured to hold a first plate section of a second stiffener region of a flexible printed circuit and the hole is configured to guide a first stiffener region of the flexible printed circuit.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

Embodiments herein relate to creating a high-aspect ratio opening in a package. Embodiments may include applying a first laminate layer on a side of a substrate, applying a seed layer to at least part of the laminate layer, building up one or more copper pads on the seed layer, etching the seed layer to expose a portion of the first laminate layer, applying a second laminate layer to fill in around the sides of one or more copper pads, and removing part of the buildup copper pads. Other embodiments may be described and/or claimed.

A method of manufacturing conductive patterns includes the steps of a) printing and curing UV curable inkjet to define a cured inkjet ink pattern on a metal sheet bonded to a non-conductive substrate; b) etching the metal sheet not covered by the cured ink pattern to expose the non-conductive substrate; and c) applying an alkaline solution to dissolve the cured inkjet ink pattern within 5 minutes.

A flexible printed circuit for a storage drive assembly is provided. The flexible printed circuit includes a stiffener layer having a first stiffener region, and a second stiffener region separated from the first stiffener region by a hinge region, a first insulation layer disposed on the stiffener layer, a conductive electrode layer disposed on the first insulation layer; and a second insulation layer disposed on the conductive electrode layer, wherein the hinge region is formed from the first insulation layer, the conductive electrode layer and the second insulation layer.

The disclosure provides a polyimide-containing layer suitable for being etched by an alkaline solution and a method for etching a polyimide-containing layer. The polyimide-containing layer suitable for being etched by an alkaline solution includes 20-50 parts by weight of a silica dioxide, and 50-80 parts by weight of a polyimide.

A flexible printed circuit for a storage drive assembly is provided. The flexible printed circuit includes a stiffener layer having a first stiffener region, and a second stiffener region separated from the first stiffener region by a hinge region, a first insulation layer disposed on the stiffener layer, a conductive electrode layer disposed on the first insulation layer; and a second insulation layer disposed on the conductive electrode layer, wherein the hinge region is formed from the first insulation layer, the conductive electrode layer and the second insulation layer.

A method of manufacturing a flexible electronic circuit is provided. The method may include forming a positive photoresist mold on a flexible polymer substrate having a plurality of metal traces. The method may also include applying a conformal material coating over the positive photoresist mold, the flexible polymer substrate, and the metal traces. The method may further include removing an excess of the conformal material coating by running a blade over the positive photoresist mold. The method may also include removing the positive photoresist mold to reveal a cavity defined by the conformal material coating. The method may further include dispensing an anisotropic conductive paste into the cavity and inserting a chip into the cavity and bonding the chip to the metal traces.

Systems, apparatuses, and/or methods to manufacture and/or implement a sensor film, a composite electrode, and/or a computing device such as a flexible device. The sensor film may include a random network of metal lines and graphene interconnecting the metal lines. The composite electrode may be formed from the sensor film. In addition, the composite electrode may include a first portion including a metal layer in a graphene layer, wherein the metal layer is randomly located in the graphene layer, and a second portion excluding the metal layer and including the graphene layer. The sensor film may be patterned to include any composite electrode configuration, such as an antenna electrode configuration, a touch electrode configuration, and so on. Thus, the flexible device may include a flexible touch screen.