Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An apparatus and methods for modifying isolation structure configurations for MOS devices to either induce or reduce tensile and/or compressive stresses on an active area of the MOS devices. The isolation structure configurations according to the present invention include the use of low-modulus and high-modulus, dielectric materials, as well as, tensile stress-inducing and compressive stress-inducing, dielectric materials, and further includes altering the depth of the isolation structure and methods for modifying isolation structure configurations, such as trench depth and isolation materials used, to modify (i.e., to either induce or reduce) tensile and/or compressive stresses on an active area of a semiconductor device.

Abstract: An integrated circuit package which includes an integrated circuit that is connected to a silicon substrate. The silicon substrate may have a via. The package may further include a solder bump that is attached to both the integrated circuit and the silicon subtstrate. The silicon substrate has a coefficient of thermal expansion that matches the coefficient of thermal expansion of the integrated circuit.

Abstract: An integrated circuit including a die having a circuit area and a plurality of guard rings. The circuit area includes active devices, passive devices, and interconnects connected to form an integrated circuit. The plurality of guard rings includes a plurality of stacked guard rings having substantially equal widths and encircling the circuit area. Alternatively, the plurality of guard rings includes metallization level guard rings interleaved with one or more via level guard rings. Each of the one or more via level guard rings includes one or more guard rings encircling the circuit area. Alternatively, the plurality of guard rings includes a plurality of concentric guard rings encircling the circuit area. Each of the plurality of guard rings is fabricated from a metal, such as aluminum, copper, or silver, or an alloy of aluminum, copper, or silver.

Abstract: A microelectronic package including a microelectronic die having an active surface and at least one side. An encapsulation material is disposed adjacent the microelectronic die side(s), wherein the encapsulation material includes at least one surface substantially planar to the microelectronic die active surface. A first dielectric material layer may be disposed on at least a portion of the microelectronic die active surface and the encapsulation material surface. At least one conductive trace is then disposed on the first dielectric material layer. The conductive trace(s) is in electrical contact with the microelectronic die active surface. At least one conductive trace extends vertically adjacent the microelectronic die active surface and vertically adjacent the encapsulation material surface.

Abstract: An integrated circuit package which includes an integrated circuit that is connected to a silicon substrate. The silicon substrate may have a via. The package may further include a solder bump that is attached to both the integrated circuit and the silicon substrate. The silicon substrate has a coefficient of thermal expansion that matches the coefficient of thermal expansion of the integrated circuit.

Abstract: An enhanced heat dissipation device for a chip-on-flex packaged unit includes a flex circuit material attached to a front side of an integrated circuit die. The flex circuit material further attached to a bottom side of a printed circuit board having an opening to expose the flex circuit material. A top heat spreader thermally coupled to the flex circuit material through the opening in the printed circuit to dissipate heat from the front side of the integrated circuit die. The device further includes a bottom heat spreader, that is thermally coupled to back side of the integrated circuit die, to dissipate heat from the back side of the integrated circuit die. This enables the heat dissipation device to dissipate heat from both the front side and back side of the integrated circuit die, and thereby enhancing the heat dissipation for a given unit surface are of the integrated circuit die without increasing the volume of the heat dissipation device.

Abstract: A chip-on-flex package which includes at least one moisture barrier layer to prevent metal corrosion and delamination of flex component layers. An exemplary microelectronic package includes a microelectronic die having an active surface and at least one side, wherein the microelectronic die active surface includes at least one contact. A flex component is attached by a first surface to the microelectronic die active surface. At least one conductive trace is disposed on a second surface of the flex component and extends through the flex component to contact at least one of the contacts. An encapsulation material is adjacent the microelectronic die side and a bottom surface of the flex component. A moisture barrier is disposed on the flex component and the conductive trace(s). A second moisture barrier may be disposed on the encapsulation material. A heat dissipation device may also be incorporated into the chip-on-flex package.