Integrated semiconductor devices and method of making the integrated semiconductor are disclosed. The integrated semiconductor device may include a first transistor comprising a first gate and at least one first active region, a second transistor comprising a second gate and at least one second active region, wherein the second transistor is spaced a first distance from the first transistor, a dielectric sidewall spacer formed on a gate sidewall of the first transistor and a gate sidewall of the second transistor, a first dielectric layer formed over the first transistor and the second transistor, wherein a thickness of the first dielectric layer is greater than half the first distance, and a patterned metal layer formed on the first dielectric layer and partially covering the second gate.

Integrated semiconductor devices and method of making the integrated semiconductor are disclosed. The integrated semiconductor device may include a first transistor comprising a first gate and at least one first active region, a second transistor comprising a second gate and at least one second active region, wherein the second transistor is spaced a first distance from the first transistor, a dielectric sidewall spacer formed on a gate sidewall of the first transistor and a gate sidewall of the second transistor, a first dielectric layer formed over the first transistor and the second transistor, wherein a thickness of the first dielectric layer is greater than half the first distance, and a patterned metal layer formed on the first dielectric layer and partially covering the second gate.

An apparatus includes a first drain/source region and a second drain/source region surrounded by an isolation ring formed over a substrate, the isolation ring formed being configured to be floating, and a first diode connected between the substrate and the isolation ring, wherein the first diode is a Schottky diode.

An apparatus includes a first drain/source region and a second drain/source region surrounded by an isolation ring formed over a substrate, the isolation ring formed being configured to be floating, and a first diode connected between the substrate and the isolation ring, wherein the first diode is a Schottky diode.

The present disclosure relates to a semi-conductor structure and method for co-integrating a III-V device with a group IV device on a Si.sub.xGe.sub.1-x(100) substrate. The method includes: (a) providing a Si.sub.xGe.sub.1-x(100) substrate, where x is from 0 to 1; (b) selecting a first region for forming therein a group IV device and a second region for forming therein a III-V device, the first and the second region each comprising a section of the Si.sub.xGe.sub.1-x(100) substrate; (c) forming a trench isolation for at least the III-V device; (d) providing a Si.sub.yGe.sub.1-y(100) surface in the first region, where y is from 0 to 1; (e) at least partially forming the group IV device on the Si.sub.yGe.sub.1-y(100) surface in the first region; (f) forming a trench in the second region which exposes the Si.sub.xGe.sub.1-x(100) substrate, the trench having a depth of at least 200 nm, at least 500 nm, at least 1 μm, usually at least 2 μm, such as 4 μm, with respect to the Si.sub.yGe.sub.1-y(100) surface in the first region; (g) growing a III-V material in the trench using aspect ratio trapping; and (h) forming the III-V device on the III-V material, the III-V device comprising at least one contact region at a height within 100 nm, 50 nm, 20 nm, usually 10 nm, of a contact region of the group IV device.

The present disclosure relates to a semi-conductor structure and method for co-integrating a III-V device with a group IV device on a Si.sub.xGe.sub.1-x(100) substrate. The method includes: (a) providing a Si.sub.xGe.sub.1-x(100) substrate, where x is from 0 to 1; (b) selecting a first region for forming therein a group IV device and a second region for forming therein a III-V device, the first and the second region each comprising a section of the Si.sub.xGe.sub.1-x(100) substrate; (c) forming a trench isolation for at least the III-V device; (d) providing a Si.sub.yGe.sub.1-y(100) surface in the first region, where y is from 0 to 1; (e) at least partially forming the group IV device on the Si.sub.yGe.sub.1-y(100) surface in the first region; (f) forming a trench in the second region which exposes the Si.sub.xGe.sub.1-x(100) substrate, the trench having a depth of at least 200 nm, at least 500 nm, at least 1 μm, usually at least 2 μm, such as 4 μm, with respect to the Si.sub.yGe.sub.1-y(100) surface in the first region; (g) growing a III-V material in the trench using aspect ratio trapping; and (h) forming the III-V device on the III-V material, the III-V device comprising at least one contact region at a height within 100 nm, 50 nm, 20 nm, usually 10 nm, of a contact region of the group IV device.

An electrical fuse (e-fuse) includes a fuse link including a silicided semiconductor layer over a dielectric layer covering a gate conductor. The silicided semiconductor layer is non-planar and extends orthogonally over the gate conductor. A first terminal is electrically coupled to a first end of the fuse link, and a second terminal is electrically coupled to a second end of the fuse link. The fuse link may be formed in the same layer as an intrinsic and/or extrinsic base of a bipolar transistor. The gate conductor may control a current source for programming the e-fuse. The e-fuse reduces the footprint and the required programming energy compared to conventional e-fuses.

An electrical fuse (e-fuse) includes a fuse link including a silicided semiconductor layer over a dielectric layer covering a gate conductor. The silicided semiconductor layer is non-planar and extends orthogonally over the gate conductor. A first terminal is electrically coupled to a first end of the fuse link, and a second terminal is electrically coupled to a second end of the fuse link. The fuse link may be formed in the same layer as an intrinsic and/or extrinsic base of a bipolar transistor. The gate conductor may control a current source for programming the e-fuse. The e-fuse reduces the footprint and the required programming energy compared to conventional e-fuses.

Various embodiments of the present application are directed towards a method to integrate NVM devices with a logic or BCD device. In some embodiments, an isolation structure is formed in a semiconductor substrate. The isolation structure demarcates a memory region of the semiconductor substrate, and further demarcates a peripheral region of the semiconductor substrate. The peripheral region may, for example, correspond to BCD device or a logic device. A doped well is formed in the peripheral region. A dielectric seal layer is formed covering the memory and peripheral regions, and further covering the doped well. The dielectric seal layer is removed from the memory region, but not the peripheral region. A memory cell structure is formed on the memory region using a thermal oxidation process. The dielectric seal layer is removed from the peripheral region, and a peripheral device structure including a gate electrode is formed on the peripheral region.

Various embodiments of the present application are directed towards a method to integrate NVM devices with a logic or BCD device. In some embodiments, an isolation structure is formed in a semiconductor substrate. The isolation structure demarcates a memory region of the semiconductor substrate, and further demarcates a peripheral region of the semiconductor substrate. The peripheral region may, for example, correspond to BCD device or a logic device. A doped well is formed in the peripheral region. A dielectric seal layer is formed covering the memory and peripheral regions, and further covering the doped well. The dielectric seal layer is removed from the memory region, but not the peripheral region. A memory cell structure is formed on the memory region using a thermal oxidation process. The dielectric seal layer is removed from the peripheral region, and a peripheral device structure including a gate electrode is formed on the peripheral region.