Dual lens dark field electron holography and Moiré fringe mapping from dark field scanning transmission electron microscopy are used to map strain distributions at high spatial resolution in Si devices processed with stress memorization techniques (SMT). It provides experimental evidence that strain in the Si channel is generated by dislocations resulting from SMT. The highest value of strain, up to 1.1% (1.9 GPa in stress) occurs at the Si surface along the channel direction: ⟨110⟩. An increase of ∼0.2% strain in the channel is observed after removing the poly-Si gate through the replacement high-k metal gate process.
For the past decade, stressors have been incorporated into the source and drain regions of the silicon semiconductor device to change the lattice constant of the current-carrying region in the channel, thereby altering the band structure of the semiconductor to enhance device performance. In semiconductor industry, it is critical to measure strain distributions at the nanometer scale. In recent years, dual lens dark field electron holography and precession electron diffraction are developed to obtain strain distribution at ~1 nm spatial resolution [1][2][3][4][5][6][7]. We use these two techniques to measure strain distribution of box shaped embedded SiGe devices and we compare our result with Eshelby inclusion simulations [8]. Fig.1 is the strain map obtained by dual lens dark field electron holography. The spatial resolution is about 2 nm with 1 nm fringe spacing. Dark field STEM image shows the box shaped embedded SiGe. The <220> strain map shows compressive strain in the channel region with large lattice constant in the embedded SiGe region. The <004> strain map shows slightly tensile strain in the Si region, with large lattice constant in SiGe region. Fig.2 is the strain map obtained by precession electron diffraction (PED). The probe size is about 2 nm. Fig.2(a) is the strain map along <220> direction and Fig.2(b) is the strain along <004> direction. Fig.2(c) is the shear strain map and Fig.2(d) is the crystalline rotation map. The strain map by PED is very similar to the one obtained by dark field electron holography. The shear strain shows high value at the bottom corner of SiGe and SiGe/Si boundary near the surface. The rotation map shows maximum 0.6 o crystal rotation at the top surface. Fig.3 is the result of Eshelby inclusion simulation. Fig.3(a) is the simulation for the strain along <220> and Fig.3(b) is the simulation for the strain along <004> direction. The simulation results match well with measurement from dual lens dark field electron holography and electron precession diffraction measurement.The precession electron diffraction provides better S/N ratio maps than the one by dual lens dark field electron holography. However, the acquisition time and storage space for PED is ~10 3 and ~10 4 of dark field electron holography, respectively.In conclusion, using dual lens dark field electron holography and precession electron diffraction, we provided strain maps at high spatial resolution and demonstrated that to be valuable methods for semiconductor research and development.
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