A method for improving the SiGe bipolar yield as well as fabricating a SiGe heterojunction bipolar transistor is provided. The inventive method includes ion-implanting carbon, C, into at one of the following regions of the device: the collector region, the sub-collector region, the extrinsic base regions, and the collector-base junction region. In a preferred embodiment each of the aforesaid regions include C implants.

A bipolar transistor includes a collector that is selected from the group SiC and SiC polytypes (4H, 6H, 15R, 3C . . . ), a base that is selected from the group Si, Ge and SiGe, at least a first emitter that is selected from the group Si, SiGe, SiC, amorphous-Si, amorphous-SiC and diamond-like carbon, and at least a second emitter that is selected from the group Si, SiGe, SiC, amorphous-Si, amorphous-SiC and diamond-like carbon. Direct-wafer-bonding is used to assemble the bipolar transistor. In an embodiment the bandgap of the collector, the bandgap of the at least a first emitter and the bandgap of the at least a second emitter are larger than the bandgap of the base.

A silicon germanium heterojunction bipolar transistor device and method comprises a semiconductor region, and a diffusion region in the semiconductor region, wherein the diffusion region is boron-doped, wherein the semiconductor region comprises a carbon dopant therein to minimize boron diffusion, and wherein a combination of an amount of the dopant, an amount of the boron, and a size of the semiconductor region are such that the diffusion region has a sheet resistance of less than approximately 4 Kohms/cm.sup.2. Also, the diffusion region is boron-doped at a concentration of 1.times.10.sup.20/cm.sup.3 to 1.times.10.sup.21/cm.sup.3. Additionally, the semiconductor region comprises 5 25% germanium and 0 3% carbon. By adding carbon to the semiconductor region, the device achieves an electrostatic discharge robustness, which further causes a tighter distribution of a power-to-failure of the device, and increases a critical thickness and reduces the thermal strain of the semiconductor region.

A silicon germanium heterojunction bipolar transistor device and method comprises a semiconductor region, and a diffusion region in the semiconductor region, wherein the diffusion region is boron-doped, wherein the semiconductor region comprises a carbon dopant therein to minimize boron diffusion, and wherein a combination of an amount of the dopant, an amount of the boron, and a size of the semiconductor region are such that the diffusion region has a sheet resistance of less than approximately 4 Kohms/cm.sup.2. Also, the diffusion region is boron-doped at a concentration of 1.times.10.sup.20/cm.sup.3 to 1.times.10.sup.21/cm.sup.3. Additionally, the semiconductor region comprises 5 25% germanium and 0 3% carbon. By adding carbon to the semiconductor region, the device achieves an electrostatic discharge robustness, which further causes a tighter distribution of a power-to-failure of the device, and increases a critical thickness and reduces the thermal strain of the semiconductor region.

A method and resulting high electron mobility transistor comprised of a substrate and a relaxed silicon-germanium layer formed over the substrate. A dopant layer is formed within the relaxed silicon-germanium layer. The dopant layer contains carbon and/or boron and has a full-width half-maximum (FWHM) thickness value of less than approximately 70 nanometers. A strained silicon layer is formed over the relaxed silicon-germanium layer and is configured to act as quantum well device.