Image calculations

Let us first define pixel size at the sample, d _pix , as the size of the square at the sample that is stepped across the sample to form the digital image. What is perceived as a sharp image is one where non-noise-related abrupt changes in intensity can be visually detected by the human eye. If the probe size, d _p , is larger than the pixel size, then as the beam is advanced from pixel to pixel, oversampling will occur and contrast between adjacent pixels will be reduced because of partial resampling. Furthermore, if the excitation volume is larger than the probe size, then the maximum magnification for a sharp image will be reduced. Microscopists generally turn to Schottky or cold field emission (FEG) sources to obtain sharp images at more than 150,000×. Again, depending on the sample type, a variety of factors must be optimized to achieve the highest level of performance, and these conditions may be different from sample to sample. Often the highest possible resolution achievable for one sample may not be possible for a different sample.

Observed SEM images are stored as a matrix of numbers related to the measured signal intensity, I _o (i,j), at points with coordinates i,j detected sequentially as the probe is scanned point to point on the sample. In the situation where excitation volume and surface morphology effects are small, the problem can be visualized as shown in Figure 1. If d _p ≤d _pix , ideally, the signal measured, I _o (i,j) would only be that from the pixel on which the beam is located. However, if d _p >d _pix , then the signal measured will be the sum of the signals generated from all the pixels sampled. Therefore:

(1) $$I_{o} \left( {i,j} \right){\equals}\mathop{\sum}\limits_{k{\minus}s}^{k{\plus}s} {\mathop{\sum}\limits_{l{\minus}s}^{l{\plus}s} {I_{t} \left( {i{\minus}k,j{\minus}l} \right)psf\left( {k,l} \right)} } $$

where the dimension of the beam in pixels is d _p =2s+1 , and s is the number of pixels in the beam on either side of the central pixel (assuming it is chosen to be large enough to give s>0 although the beam need not be symmetric). The actual distribution of electrons in the probe is described by the PSF, psf(k,l) in Equation (1). It is a measure of how the probe current, i _p , is distributed in space and is generally expressed such that the integrated value of the function is unity. The term I _t (i,j) is the true intensity that would be emitted from a given pixel if d _p ≤d _pix that is s=0, when the signal only comes from the specific pixel addressed. Equation (1) indicates that while the beam resides at position (i,j) only a single measurement I _o (i,j) is made, there are more unknowns (I _t (i,j)) than knowns, and the true image cannot be calculated. Assume, for example, as shown in Figure 1, the beam occupies a matrix of 3 × 3 pixels (s=1). In that case there would be a single measurement and nine values of I _t (i,j) to determine including the one on which the beam is centered. As the beam is stepped a single pixel to the right (increasing i), another measurement is made, with three new pixels (unknowns) added and three pixels dropped. Now there are two measurements and twelve unknowns. In normal image collection the beam is also stepped in the j direction, and the ratio of unknowns to knowns approaches one for small PSFs and large images at which point the set of equations generated could be uniquely solved. However, in practice the number of measurements will never equal the number of unknowns, but as the number of pixels in an image gets larger, some form of pixel padding around the periphery of the image makes a reasonable approximation for the values of I _t (i,j) possible.

Figure 1 A 5 × 5 matrix of object pixels. The beam is placed at the center pixel with coordinates i, j (blue box). The probe, assumed here to be circular, has a diameter dp of 3 pixels across (s = 1) and covers an area of 9 pixels, each of which is a separate signal source. Measurements can only be made in the innermost 9 pixels because if the beam is placed along the sides or in the corners it will extend beyond the 5 × 5 matrix. Thus, in this case there can be 9 measurements but with 25 unknowns!

Equation (2) can also be described as the convolution of the PSF with I _t (i,j), but for a proper determination of I _t (i,j) the noise, η(i,j), must be added:

(2) $$I_{o} \left( {i,j} \right){\equals}I_{t} \left( {i,j} \right)\,\otimes\,\;psf\left( {i,j} \right){\plus}\eta \left( {i,j} \right)$$

It is common practice to rewrite image matrices in what is known as column vector format and Equation (2) becomes:

(3) $$I_{o} {\equals}AI_{t} {\plus}\eta $$

where I _o , I _t and η are column vectors representing the observed image, true image, and noise, respectively, and A is a block circulant matrix that can be developed from the point PSF. In the absence of noise it would be relatively straightforward to calculate I _t from I _o if A is known or to calculate A (and therefore the PSF) if I _t and I _o are known. However, when noise is considered, the problem is significantly more complicated. While the approach needed may not be familiar to many scanning electron microscopists, equations similar to Equation (3) may be found in many books and articles on the general topic of image processing [Reference Gonzalez2–Reference Castleman4]. What is important to recognize is that the determination of I _t is a very challenging problem even if I _o is carefully measured and the PSF is known. The reason is related to the uncertainty in η resulting in what is termed an “ill posed” inverse problem that requires some form of functional minimization as well as some form of practical constraint, often referred to a regularization term. This leads to a re-statement of Equation (3) in various forms such as:

(4) $${\rm min}_{{It}} \left\{ {\parallelI_{o} {\minus}AI_{t} \parallel^{2} {\minus}\lambda \parallelDI_{t} \parallel} \right\}$$

The two terms within the absolute brackets refer to a least squares minimization of the difference between the observed image and the estimated best fit image and a smoothing term to account for the noise, respectively. The parameter λ is the regularization parameter and D is a derivative matrix. Although the solution of Equation (4) for a large image is computationally complex, it can be readily handled by a multicore workstation equipped with optional graphics processing units (GPUs), if needed. It should be pointed out that while the problem can be approached by the solution of a series of linear equations in real space, there also exist Fourier space methods such as the Weiner deconvolution method and nonlinear approaches such as Richardson-Lucy [Reference Gonzalez2–Reference Castleman4], as well as other forms.

How it works

The outline in Figure 2 is the procedure implemented in the Nanojehm Aura Workstation. It can be applied to any microscope including those with thermionic, Schottky, or FEG sources. The images collected can be 8-bit or 16-bit TIFF or PNG format to minimize any loss of information. It is also important to examine an image histogram to ensure that no clipping occurs on either end of the image grayscale and that the gamma setting on the detector electronics is set equal to one, which makes the detector output signal linear with respect to its input.

Figure 2 Flow diagram showing the determination of the PSF and the image restoration process.

Step 1. Reference standard image

Take an image of a calibration standard at a preset step size (in nm per pixel) and at the selected beam voltage. The standard consists of spherical gold or other particles dispersed on a very thin carbon film on a TEM grid as shown in Figure 3. The particles used are nearly spherical and selected from a reasonably tight distribution, but subject to some variation as a result of their synthesis. Their specific size, shape, and distribution were determined by transmission electron microscopy. The image size of the reference image should be selected such that dozens of particles are included in the field. The particles in the reference image are then used to form a single composite stacked particle after the elimination of any overlapping or out-of-specification particles. The stacked image has a number of advantages relative to a single particle image: (1) It represents an average of many particles that may have slight differences in size and shape even after meeting certain criteria set by the software to avoid overlapping or otherwise unacceptable particles. (2) More particles means better counting statistics. And (3) the beam never has to dwell for a long time on any one particle, which could lead to problems width drift or contamination. The stacked particle image is then compared to that of a theoretically calculated image of a particle of the same size to determine the PSF. Nanojehm provides a standard block with different separate particle size standards. For example, 19 nm particles are used for determining PSFs at higher magnifications, while 52 nm are used for determining the PSF where lower magnifications are used as in the case of larger-beam thermionic instruments.

Figure 3 (a) BSE image showing a distribution of 19 nm gold particles in a calibration standard at 20 keV with LaB₆ source. (b) Stacked particle composite image. (c) Theoretically calculated BSE image.

Step 2. Images of the sample

Take one or more images of either different samples or different regions of the same sample under identical microscope conditions as those used for collecting the reference standard image. Microscope conditions refers to settings that might perturb the PSF determined in the previous step such as astigmatism adjustment, working distance changes (> 2 mm), and kV changes.

Step 3

Load images into the Nanojehm’s Aura workstation.

Step 4. Point spread function determination

A high-resolution image of a reference particle is theoretically calculated, which can then be directly compared to the measured stacked single particle image (Figure 3). These two images can then be used to compute the PSF by a variant of Equation 3. It should be remembered that a PSF refers to the distribution of electrons in space and therefore can be used to restore either BSE or SE images. Figure 4 shows an example of a PSF determined from the particle image shown in Figure 3.

Figure 4 The PSF determined from the images in Figures 3b and 3c. Data are shown as (a) a surface plot and (b) a contour plot.

Step 5. Resolution improvement

Once the PSF is determined, it can be used to restore images through the use of Equation 4. Figure 5a is an image of a commonly used gold on carbon standard (Pela 617) obtained at 20 kV. The image was taken at a high magnification with an LaB₆ source instrument using 1 nm per pixel. Since the beam diameter was considerably larger that the pixel size larger than the pixel size (Figure 1), imaging conditions imaging conditions were in the oversampling mode (d _p >d _pix ) making this image a good candidate for restoration by Equation (4) with the results shown in Figure 5b. While the image does appear clearer, a less subjective indicator of improved resolution is the line profile of an abrupt discontinuity in the structure at a gold-carbon-gold boundary. Here the steeper slope of the line scan in the restored image (Figure 5c) is an indicator of higher resolution.

Figure 5 (a) The observed image and (b) restored image of a gold-on-carbon standard. SE images taken at 20 kV. Image width = 1.00 µm. (c) Line profile across a gold-carbon-gold boundary (red line on the observed image). Note significant noise reduction and higher slope in restored image profile indicative of higher resolution.