Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a first plurality of conductive interconnect layers arranged within a first inter-level dielectric (ILD) structure disposed on a first surface of a first substrate. A second plurality of conductive interconnect layers are arranged within a second ILD structure disposed on a first surface of a second substrate. The second substrate is separated from the first substrate by the first ILD structure. The first plurality of conductive interconnect layers and the second plurality of conductive interconnect layers define an inductor having one or more turns.

Abstract: A method for manufacturing three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is formed and bonded to a first IC die by a first bonding structure. A third IC die is formed and bonded to the second IC die by a second bonding structure. The second bonding structure is formed between back sides of the second IC die and the third IC die opposite to corresponding interconnect structures and comprises a first TSV (through substrate via) disposed through a second substrate of the second IC die and a second TSV disposed through a third substrate of the third IC die. In some further embodiments, the second bonding structure is formed by forming conductive features with oppositely titled sidewalls disposed between the first TSV and the second TSV.

Abstract: A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die by a first bonding structure. The first bonding structure contacts a first interconnect structure of the first IC die and a second interconnection structure of the second IC die, and has a first portion and a second portion hybrid bonded together. A third IC die is bonded to the second IC die by a third bonding structure. The third bonding structure comprises a second TSV (through substrate via) disposed through the second substrate of the second IC die and includes varies bonding structures according to varies embodiments of the invention.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: A three-dimensional (3D) integrated circuit (IC) is provided. In some embodiments, a second IC die is bonded to a first IC die by a first bonding structure. The first bonding structure contacts a first interconnect structure of the first IC die and a second interconnection structure of the second IC die, and has a first portion and a second portion hybrid bonded together. A third IC die is bonded to the second IC die by a third bonding structure. The third bonding structure comprises a second TSV (through substrate via) disposed through the second substrate of the second IC die and includes varies bonding structures according to varies embodiments of the invention.

Abstract: The present disclosure, in some embodiments, relates to an integrated chip. The integrated chip includes a first plurality of conductive interconnect layers arranged within a first inter-level dielectric (ILD) structure disposed on a first surface of a first substrate. A second plurality of conductive interconnect layers are arranged within a second ILD structure disposed on a first surface of a second substrate. The second substrate is separated from the first substrate by the first ILD structure. The first plurality of conductive interconnect layers and the second plurality of conductive interconnect layers define an inductor having one or more turns.

Abstract: The present disclosure, in some embodiments, relates to a method of forming an integrated chip. The method may be performed by forming a first conductive wire within a first dielectric structure formed on a first surface of a first substrate. A through-substrate-via (TSV) is formed to extend though the first substrate. A second conductive wire is formed within a second dielectric structure formed on a second surface of the first substrate opposing the first surface. The TSV electrically couples the first conductive wire and the second conductive wire. The first conductive wire, the second conductive wire, and the TSV define an inductor that wraps around an axis.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: The present disclosure, in some embodiments, relates to an integrated circuit having an inductor with one or more turns arranged along vertical planes that intersect an underlying substrate. In some embodiments, the integrated circuit includes a plurality of conductive routing layers having conductive wires and conductive vias disposed within one or more dielectric structures abutting a first substrate. The plurality of conductive routing layers define an inductor having one or more turns respectively including a vertically extending segment arranged along a plane that intersects the first substrate. The vertically extending segment has a plurality of the conductive wires and the conductive vias.

Abstract: The present invention relates to antiviral agents and methods of their use in suppression of viruses and in the treatment of a disease or condition associated with viral infection. The antiviral agent includes a nucleotide derivative is a morpholino oligomer complementary to mammalian relative of DnaJ (MRJ) gene.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: The present disclosure, in some embodiments, relates to an integrated circuit having an inductor with one or more turns arranged along vertical planes that intersect an underlying substrate. In some embodiments, the integrated circuit includes a plurality of conductive routing layers having conductive wires and conductive vias disposed within one or more dielectric structures abutting a first substrate. The plurality of conductive routing layers define an inductor having one or more turns respectively including a vertically extending segment arranged along a plane that intersects the first substrate. The vertically extending segment has a plurality of the conductive wires and the conductive vias.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: A plurality of gate stacks is formed over a substrate. The gate stacks are surrounded by a dielectric structure. A plurality of contact-line-blocking patterns is formed over the dielectric structure. The contact-line-blocking patterns are formed using three or more lithography masks. A plurality of trenches is formed in the dielectric structure. The contact-line-blocking patterns serve as protective masks for the dielectric structure to prevent trenches from being formed in portions of the dielectric structure underneath the contact-line-blocking patterns. The trenches are filled with a conductive material to form a plurality of contact lines of the SRAM device.

Abstract: A static random access memory (SRAM) cell includes a first gate and a second gate each extending in a first direction. A first gap separates the first gate from the second gate in the first direction. The SRAM cell includes a Vcc contact extending in the first direction. A second gap separates the Vcc contact and the first gate in a second direction perpendicular to the first direction. No segment of the Vcc contact overlaps with the first gap in the first direction. The SRAM cell includes a Vss contact extending in the first direction. A third gap separates the Vss contact from the first gate in the second direction. A segment of the Vss contact is disposed to the first gap. The Vss contact is smaller than the Vcc contact in the second direction.

Abstract: A static random access memory (SRAM) cell includes a first gate and a second gate each extending in a first direction. A first gap separates the first gate from the second gate in the first direction. The SRAM cell includes a Vcc contact extending in the first direction. A second gap separates the Vcc contact and the first gate in a second direction perpendicular to the first direction. No segment of the Vcc contact overlaps with the first gap in the first direction. The SRAM cell includes a Vss contact extending in the first direction. A third gap separates the Vss contact from the first gate in the second direction. A segment of the Vss contact is disposed to the first gap. The Vss contact is smaller than the Vcc contact in the second direction.

Abstract: A fan includes a motor, an impeller and a heat-dissipating structure. The motor includes a stator magnet assembly, a frame, a first circuit board, and a cover. The frame supports the stator magnet assembly. The frame and the stator magnet assembly define a first accommodating space, and the first circuit board is disposed in the first accommodating space. The cover covers the first circuit board. The motor drives the impeller and the impeller includes a hub and a plurality of first blades. The hub has at least a heat-dissipating hole. The first blades are disposed around the hub, and the heat-dissipating structure is disposed at the outer side of the hub. The heat-dissipating structure has a baffle and at least a second blade extended from the baffle and located corresponding to the heat-dissipating hole.

Abstract: A fan includes an impeller and a frame. The frame is used for accommodating the impeller. The frame includes a plurality of static blade groups. Each of the static blade groups has a plurality of static blades. Moreover, at least one first static blade of a first static blade group and at least one first static blade of a second static blade group are symmetric with respect to a central axis of the frame.