A display device with high design flexibility is provided. The display device includes a display element, a touch sensor, and a transistor between two flexible substrates. An external electrode that supplies a signal to the display element and an external electrode that supplies a signal to the touch sensor are connected from the same surface of one of the substrates.

A conductive route structure may be formed comprising a conductive trace and a conductive via, wherein the conductive via directly contacts the conductive trace. In one embodiment, the conductive route structure may be formed by forming a dielectric material layer on the conductive trace. A via opening may be formed through the dielectric material layer to expose a portion of the conductive trace and a blocking layer may be from only on the exposed portion of the conductive trace. A barrier line may be formed on sidewalls of the via opening and the blocking layer may thereafter be removed. A conductive via may then be formed within the via opening, wherein the conductive via directly contacts the conductive trace.

A control method for differentiated etching depth is provided. The method includes: providing a first etching stop pattern layer in a panel having stacked structure; adopting a first etchant to perform a first etching process to the panel such that a location of the panel provided with the first etching stop pattern layer forms a first etching depth, and forms a second etching depth at a location of the panel without providing the first etching stop pattern layer; through controlling an etching time, the second etching depth is deeper than a bottom of the first etching stop pattern layer; and adopting a second etchant to perform a second etching process to the panel in order to etch and remove the first etching stop pattern layer. In a same mask process, through changing the etchant, different depths are etched and formed to reduce the time consuming and decrease the production cost.

The present disclosure describes a method of forming a dielectric layer or a dielectric stack on a photoresist layer while minimizing or avoiding damage to the photoresist. In addition, the dielectric layer or dielectric stack can till high-aspect ratio openings and can be removed with etching. The dielectric layer or dielectric stack can be deposited with a conformal, low-temperature chemical vapor deposition process or a conformal, low-temperature atomic layer deposition process that utilizes a number of precursors and plasmas or reactant gases.

A method of manufacturing a semiconductor package includes forming a first redistribution structure, forming a plurality of conductive pillars on the first redistribution structure, mounting the first semiconductor chip on the first redistribution structure, forming an encapsulant configured to cover an upper surface of the first redistribution structure, the plurality of conductive pillars, and the first semiconductor chip, planarizing the encapsulant, exposing the plurality of conductive pillars by forming an opening in the planarized encapsulant, and forming a second redistribution structure connected to the plurality of conductive pillars on the first semiconductor chip and the encapsulant. Upper surfaces of the plurality of conductive pillars are located at a lower level than the upper surface of the first semiconductor chip, and an upper surface of a connection via included in the second redistribution structure has a width greater than a width of a lower surface of the connection via.

A control method for differentiated etching depth is provided. The method includes: providing a first etching stop pattern layer in a panel having stacked structure; adopting a first etchant to perform a first etching process to the panel such that a location of the panel provided with the first etching stop pattern layer forms a first etching depth, and forms a second etching depth at a location of the panel without providing the first etching stop pattern layer; through controlling an etching time, the second etching depth is deeper than a bottom of the first etching stop pattern layer; and adopting a second etchant to perform a second etching process to the panel in order to etch and remove the first etching stop pattern layer. In a same mask process, through changing the etchant, different depths are etched and formed to reduce the time consuming and decrease the production cost.

The present disclosure describes a method of forming a dielectric layer or a dielectric stack on a photoresist layer while minimizing or avoiding damage to the photoresist. In addition, the dielectric layer or dielectric stack can till high-aspect ratio openings and can be removed with etching. The dielectric layer or dielectric stack can be deposited with a conformal, low-temperature chemical vapor deposition process or a conformal, low-temperature atomic layer deposition process that utilizes a number of precursors and plasmas or reactant gases.

A semiconductor device has a semiconductor die and an encapsulant deposited over the semiconductor die. A first insulating layer is formed over a first surface of the encapsulant and an active surface of the semiconductor die. A second insulating layer is formed over a second surface of the encapsulant opposite the first surface. A conductive layer is formed over the first insulating layer. The conductive layer includes a line-pitch or line-spacing of less than 5 m. The active surface of the semiconductor die is recessed within the encapsulant. A third insulating layer is formed over the semiconductor die including a surface of the third insulating layer coplanar with a surface of the encapsulant. The second insulating layer is formed prior to forming the conductive layer. A trench is formed in the first insulating layer. The conductive layer is formed within the trench.

A semiconductor device has a semiconductor die and an encapsulant deposited over the semiconductor die. A first insulating layer is formed over a first surface of the encapsulant and an active surface of the semiconductor die. A second insulating layer is formed over a second surface of the encapsulant opposite the first surface. A conductive layer is formed over the first insulating layer. The conductive layer includes a line-pitch or line-spacing of less than 5 m. The active surface of the semiconductor die is recessed within the encapsulant. A third insulating layer is formed over the semiconductor die including a surface of the third insulating layer coplanar with a surface of the encapsulant. The second insulating layer is formed prior to forming the conductive layer. A trench is formed in the first insulating layer. The conductive layer is formed within the trench.

A conductive route structure may be formed comprising a conductive trace and a conductive via, wherein the conductive via directly contacts the conductive trace. In one embodiment, the conductive route structure may be formed by forming a dielectric material layer on the conductive trace. A via opening may be formed through the dielectric material layer to expose a portion of the conductive trace and a blocking layer may be from only on the exposed portion of the conductive trace. A barrier line may be formed on sidewalls of the via opening and the blocking layer may thereafter be removed. A conductive via may then be formed within the via opening, wherein the conductive via directly contacts the conductive trace.