Growth and characterization of undoped and in situ doped Si1−xGex on patterned oxide Si substrates by very low pressure chemical vapor deposition at 700 and 625 °C

Abstract

Results of strained layer Si_1−xGe_x heteroepitaxy on patterned oxide silicon substrates using a very low pressure chemical vapor deposition reactor are presented. Patterned oxide wafers were in situ cleaned at 700 °C using an Ar/H₂ plasma. Undoped Si_1−xGe_x strained layers at 625 and 700 °C along with in situ doped p and n‐type Si_1−xGe_x strained layers at 625 °C were deposited using SiH₄, GeH₄, B₂H₆, and AsH₃ with H₂ as a carrier gas. Alternating layers of Si_1−xGe_x and Si were formed by switching the inlet gases. Scanning electron microscope showed a smooth surface morphology for Si_1−xGe_x strained layers deposited with GeH₄/SiH₄ gas ratios 1−xGe_x and Si layers with dislocation densities below the detection limit of 10⁵ cm⁻². Defect etching confirmed the low defect density at the surface. For epitaxial windows smaller than 50×50 μm, no defects were observed. Germanium solid mole fraction, boron and arsenic chemical dopant concentrations, and interfacial carbon and oxygen contamination were measured by secondary ion mass spectrometry. Undoped, B₂H₆, and AsH₃ in situ doped Si_1−xGe_x strain layers with germanium content up to 23% were demonstrated. The Ge incorporation was controlled by the GeH₄/SiH₄ gas ratio and the Si_1−xGe_x growth rate decreased with increasing Ge solid mole fraction. The addition of B₂H₆ did not affect the Si_1−xGe_x growth rate and modulation of the boron chemical incorporation was possible by controlling the B₂H₆ gas concentration. On the other hand, AsH₃ severely degraded the Si_1−xGe_x growth rate and varying the AsH₃ gas concentration did not change the arsenic chemical incorporation. Lastly, selective AsH₃ doped Si_1−xGe_x heteroepi