Theory of Electron Holography

The electron passing through a specimen contains amplitude information as well as phase information. Regular transmission electron microscopy can only measure the amplitude information. However, electron holography can be used to measure both amplitude and phase information of the electron wave function passing through the sample. The electron holography is achieved by interfering two electron beams through a biprism: one electron beam passing through the region of interest and other electron beam passing through reference region, as shown in Figure 1 and Figure 2 for bright-field electron holography and dark-field electron holography, respectively.

Figure 1 Electron hologram formation using a single lens in a dual-lens imaging system. The interference pattern with fringe spacing, σ _i, and fringe width, W _i, is formed by two virtual sources, S ₁ and S ₂. (a) Low-magnification single-lens holography where only the second lens is turned on. (b) High-magnification single-lens holography, where only the first lens is turned on.

Figure 2 (a) Off-axis dark-field electron holography. A diffracted beam is selected by a moving objective aperture to the diffracted beam location. (b) On-axis dark-field electron holography. A diffracted beam is selected by tilting the illumination to bring the diffracted beam to the optical axis.

In electron holography, three parameters are critical: fringe overlap for FOV, fringe spacing for spatial resolution, and fringe contrast for signal-to noise ratio. The fringe spacing, σ _i, and fringe overlap, W _i, at the image plane is determined by the biprism voltage and have a limited range because of the requirement of fringe contrast value, μ, for data processing [Reference Wang4–Reference Wang12]. Their relationship to the object (or specimen), σ _o and W _o, can be written as:

(1) $$\sigma _{o} ={{\sigma _{i} } \over {M_{o} }}$$

and

(2) $$W_{o} ={{W_{i} } \over {M_{o} }},$$

where M _o is the magnification of the imaging lens(es). The equation shows that magnificaton is a dominant factor for the variation of fringe spacing and fringe overlap relative to the object.

Bright-Field Electron Holography for Junction Profiling

The intensity of the wave function for bright-field electron holography after the biprism can be written as:

(3) $$I=A_{0}^{2} {\plus}A^{2} (\vec {r}){\plus}2\mu A(\vec {r})A_{0} \,\cos [2\pi q_{c} r{\plus}\varphi (\vec {r}){\plus}\theta ]$$

where q _c = 1/σ _o, which denotes the frequency of the interference fringes, μ is the fringe contrast, and θ is the constant phase shift. The phase map, which is related to the mean inner potential, and the amplitude map, which is related to the specimen thickness and material scattering factor, can be extracted through a fast Fourier transformation (FFT) of the hologram and an inverse FFT of an appropriately sized side band [Reference Mccartney13, Reference Rau14].

Dark-Field Electron Holography for Strain Mapping

The dark-field holography method was first developed by Hytch et al [Reference Hytch1]. A detailed method of strain mapping by electron holography was described by Beche et al. [Reference Beche15]. A theoretical description of dark-field holography in relationship with strain measurement can be found in Hytch et al.'s 1998 paper [Reference Hytch, Snoeck and Kilaas16] and Rouviere and Sarigiannnidou's 2005 paper [Reference Rouviere and Sariggiannidou17]. The principle of dark-field holography is to use a biprism to overlap a strained region of the device with an unstrained region in Si, as shown in Figure 2a (off-axis dark-field holography) or in Figure 2b (on-axis dark-field holography). The intensity of a dark-field hologram can be written as following:

(4) $$I=A_{{obj}}^{2} {\plus}A_{{ref}}^{2} {\plus}2\mu A_{{obj}} A_{{ref}} \cos [2\pi q_{c} r{\plus}2\pi (\vec {g}_{{ref}} {\minus}\vec {g}_{{obj}} ){\bullet}\vec {r}{\plus}\varphi _{{ref}} {\minus}\varphi _{{obj}} ]$$

where $\vec {g}_{{ref}} $ and $\vec {g}_{{obj}} $ are g vectors from the region of the interest (object) and the reference, respectively. The phase of the hologram is:

(5) $$\varphi =2\pi (\vec {g}_{{ref}} {\minus}\vec {g}_{{obj}} ){\bullet}\vec {r}{\plus}\varphi _{{ref}} {\minus}\varphi _{{obj}} $$

The lattice constant change to the first order can be approximated as:

(6) $${\varepsilon}_{{ii}} ={{d_{{obj}}^{{(i)}} {\minus}d_{{ref}}^{{(i)}} } \over {d_{{ref}}^{{(i)}} }}\,\approx\,{{g_{{ref}}^{{(i)}} {\minus}g_{{obj}}^{{(i)}} } \over {g_{{ref}}^{{(i)}} }}\,\approx\,{1 \over {2\pi g_{{ref}}^{{(i)}} }}{{\partial \varphi ^{{(i)}} } \over {\partial r_{i} }}$$

where i = x, y, g = 1/d, and d is the lattice spacing. By selecting a specific diffracted beam with an objective aperture to obtain a dark-field hologram, the difference in lattice spacing between strained and unstrained Si can be measured.

Dual-Lens Electron Holography

Prior to the dual-lens operation, electron holography had limited application because of its fixed FOV and fringe spacing relative to the sample, with a microscope operated in a single-objective lens mode. This is because in a single-lens mode, the magnification is usually fixed and Equations (1) and (2) show that the magnification is the dominant factor to determine the fringe spacing and fringe width relative to the sample.

Figure 1a shows the low-magnification operation mode with second objective lens excited, whereas Figure 1b shows high-magnification operation mode with the first objective lens excited. The fringe spacing of low-magnification mode (Figure 1a) is too large for the current generation of devices, whereas the FOV of high-magnification mode (Figure 1b) is too small for semiconductor devices. These two single-lens operations cannot cover the range of the current generation devices. Because of this problem, we developed the dual-lens electron holography method to obtain wide fringe spacing and FOV to cover the device dimensions of several generations [Reference Wang4–Reference Wang6]. However, the application of dual-lens method is not limited to only semiconductor device characterization.

Figure 3 illustrates the electron optical ray diagram of a dual-lens system. The voltage (or current) of the first objective lens (OL) is set so that the position of the object is behind the first focal point f _1OL but before the lens, thereby forming a virtual image of the object. The second objective lens (OM) is used to project a real image of the OL’s virtual image onto the intermediate image plane beyond the biprism. As shown in Figure 3, when the focal point of the OL gets closer to the sample, the virtual image moves further away from the sample and is magnified. In order to refocus the virtual image onto the same image plane, the focal length of the OM is increased (by decreasing the OM strength) to compensate for the movement of the virtual image position. Thereby, the magnification of the sample at the image plane, M _o, can be adjusted by varying the focal length of the first objective lens (OL) to give a virtual image of variable size, which is refocused to the intermediate image plane by the second objective lens (OM).

Figure 3 Optical ray diagram of dual-lens operation. A magnified virtual image of OL (first objective lens) is shown as a dashed image and a real image is projected by OM (second objective lens) onto the imaging plane. As the focal point gets closer to the object by increasing the OL strength, a virtual image is magnified and moves away from OL. To refocus the virtual image back to the imaging plane, the strength of the second lens is reduced to increase the focal length of the second lens, as shown in the movement of f _1OM by the nearby arrow.

Figure 4 summarizes experimental results for fringe width and fringe spacing relative to the objective lens excitation on microscope A. The graphical results show that the range of values for FOV and fringe spacing necessary for semiconductor characterization are achieved. The fringe spacing decreases from 6 nm to 0.5 nm; while the FOV changes from 800 nm to 100 nm, when the first objective lens current increases with a constant biprism voltage. The second objective lens is adjusted to refocus the image back to the same imaging plane as shown in Figure 3. With the constant biprism voltage, the contrast varies slightly through the operational ranges [Reference Wang4].

Figure 4 Fringe spacing σ _obj (circle) and fringe width W _obj (square) as a function of objective lens excitation in the unit of voltage applied to the lens with a constant biprism voltage of 20 V for microscope A.

We obtained similar curves on other instruments with dual-lens configurations. Figure 5 shows the fringe spacing and fringe overlap decrease with increasing objective lens excitation for instrument B (Figure 5a) and instrument C (Figure 5b) [Reference Wang6]. The rate of fringe spacing decreases with the objective current on instrument B and C being slightly different from the one obtained on instrument A, but the trends are similar.

Figure 5 (a) Fringe spacing and fringe width relative to the object as a function of objective lens excitation current in the unit of percentage from the full excitation of the lens on instrument B with the biprism voltage of 100 V. (b) Fringe spacing and fringe width relative to the object versus objective lens excitation current in the unit of percentage from the full excitation of the lens on instrument C with the biprism voltage of 120 V.

In all, the data show that the dual-lens mode leads to a large operational space for electron holography without sacrificing fringe contrast, which determines the signal-to-noise ratio in the amplitude and phase (potential) maps derived from the electron holograms.

Junction Profiling by Dual-Lens Electron Holography

Contour potential maps for the two devices are shown in Figure 6. Figure 6a is for the device with 220 nm gate length and Figure 6b is a device with 70 nm gate length. The intensity of the maps near the sides of the gates (side wall spacers and CoSi₂) changes sign abruptly due to phase wrapping. As shown in this example, both σ _o and W _o can be scaled by simply varying the OL excitation without losing fringe contrast. This allows the characterization of different size devices with similar signal sensitivity. In these two cases, device scale changes about 3×, and the electron holography imaging scale also changes 3× to show the flexibility of dual-lens operation.

Figure 6 Mean inner potential maps of pFET devices. (a) With 220 nm gate width and (b) with 70 nm gate width.

In high-performance CMOS logic devices, low-dose ion implants are placed between the channel and the low-resistance (high-dose) source/drain regions. In Figure 6b, the upper curved portion of the P-N junction on either side of the device channel represents the result of such a low-dose implant, which is clearly visible because of the high spatial resolution in the hologram from which the potential map was reconstructed.

Figure 7 P-diffusion to N-well profile for the Si diffusion region. At the edge of the Si near SiO₂ wall, the junction is slightly tilted toward CoSi₂. (a) TEM image, (b) process condition 1, (c) process condition 2. Where high leakage to the substrate was observed in process condition 2, the junction is more curved upward near the edge of the diffusion Si region.

Figure 8 nFET shallow extension junction profile. (a) TEM image of the shallow junction, (b) junction map that shows CoSi₂ is too close to the junction at the intersection of the extension implant and the source/drain implant. (c) Drawing of shallow junction of Figure (8b).

Strain Mapping by Dual-Lens Dark-Field Electron Holography

Strain mapping along the <220> direction in Si provides channel strain information important to the semiconductor industry. For pFET, compressive strain improves device mobility; whereas for nFET, tensile strain improves device performance. In the following, we provide two examples to show how to use dual-lens electron holography to measure strain along the <220> direction at high spatial resolution.

Figure 9 shows <220> strain measured right after SiGe growth with a box shape. Figure 9a is the TEM image, 9b is the strain map, and 9c is the vertical profile of the strain distribution in the channel and in the source drain region. The compressive strain increases to a maximum at the Si surface in the channel (to -0.65%). Figure 10d shows the line scan for the strain parallel to the channel direction. At the SiGe and Si boundary, the lattice constant along the <220> direction is discontinuous in Figure 9d, whereas at the bottom of the SiGe box, the lattice constant along the 220 direction is continuous between Si and SiGe, but the derivation of the lattice constant is not as shown by the line scan 2 in Figure 9c.

Figure 9 Strain maps of box SiGe after SiGe epitaxial growth. (a) TEM image, (b) <220> strain maps where blue color indicates lattice compression, and red color indicates lattice expansion. (c) Vertical profiles of <220> strain at positions 1 and 2 in the channel and in the source/drain region. (d) Line scan 3 and line scan 4 shown in Figure 9b.

Figure 10 Strain measurement on sigma-shaped SiGe structure. (a) TEM image, (b) <220> strain maps where blue color indicates lattice compression, and red color is lattice expansion. (c) Vertical profile of strain distribution.

Figure 10a is the TEM image of the sigma profile SiGe device. Figure 10b shows the the strain map along the <220> direction, and Figure 11c shows the vertical profile of the strain map. The compressive strain for this device at the Si surface is about -1.7%. Compared with the box-shaped SiGe shown in Figure 9, the absolute strain is higher (more negative), and the compressive region is more concentrated in the channel region with the sigma SiGe process than with the box SiGe process. This is consistent with the electrical data, which shows that the device with sigma profile SiGe has better performance characteristics than the device with the rectangular-shaped SiGe process. The dual-lens electron holography allows measurement of the strain distribution in a very small region with detailed strain distribution.

Figure 11 Strain map on a device processed by the stress memorization process. Red/yellow color shows lattice expansion, and blue indicates lattice compression. High strain near a dislocation is observed. Right top profile is the strain near the dislocation core; right bottom profile is the vertical strain distribution of the <220> direction. Vertical scale of the right figures is strain.

Figure 11a is the <220> strain map of a device processed through strain memorization techniques. From the map, we noticed the highest strain at the Si surface is about 1.1%. In addition to that, the strain near the dislocation region is about 2%. The strain radiates toward the channel region from both sides of the gate. Figure 11b is the profile of strain near the dislocation core, which shows high compressive strain under the dislocation core to about -15%- to -20% and tensile strain above dislocation core of 15% to 20%. Figure 11c is the vertical strain profile in the middle of the device shown in Figure 12a. Based on this picture, we concluded that the strain is memorized in the dislocation generated during the strain memorization process step. In addition to that, we noticed that additional tensile strain of 0.2% is generated after the poly-Si gate is removed, as required by the replacement gate process [Reference Wang22], consistent with the dislocation model for stress memorization technique [Reference Weber20].