Sample Preparation

Three samples of [60]fullerene (C₆₀) in a CNT were used in this study. C₆₀ molecules encapsulated in a CNT (C₆₀@CNT) (Okada et al., Reference Okada, Kowashi, Schweighauser, Yamanouchi, Harano and Nakamura2017) were chosen as the molecular specimen in this study because the hollow and spherical morphology of C₆₀ is suitable for the quantitative evaluation of TEM image quality by SNR and edge analyses. The first two datasets, labelled as C60@CNT1 and C60@CNT2, were used to evaluate the effect of electron dose on image quality and evaluate the effect of various denoising algorithms in restoring image quality. The third dataset, labelled as C60@CNT3, was used to determine the effectiveness in restoring low signal images captured at ultra-high frame rates.

These C₆₀@CNT samples were prepared as follows: CNT powder was heated in air in an oven gradually from 296 to 793 K for 12 min, kept at 793 K for 1 min, heated from 793 to 823 K for 20 min, and kept at 823 K for 20 min to remove the terminal caps of CNTs oxidatively. For encapsulation of C₆₀ molecules, the opened CNTs (0.2 mg) and C₆₀ powder (0.2 mg) were sealed in a glass tube (Pyrex ϕ6 mm) under a pressure of 2 × 10⁻⁴ Pa and gradually heated from 296 to 573 K over 1 h, then to 673 K over 1 h, and kept at 673 K for 72 h. The resulting C₆₀-containing CNTs were separated mechanically from remaining C₆₀ powder, washed with toluene to remove C₆₀ from the surface, and dried in vacuum. C₆₀@CNT thus obtained was a black solid (0.3 mg). We dispersed the C₆₀@CNT in toluene (0.05 mg/mL) in a vial in a bath sonicator for 1 h to soften it, so that we could secure good contact between the CNTs and the carbon surface of the grid (essential for temperature control). A 10-μL solution of the dispersion was deposited on a copper grid mesh with a lacy carbon (NS-C15, Okenshoji Co., Ltd.) placed on a paper that absorbs excess toluene. The TEM grid was dried in vacuum (60 Pa) to remove solvent for 2 h. To ensure reproducibility, we used the same sample grid of C₆₀@CNTs in a series of experiments.

TEM Imaging

Atomic-resolution TEM observation was carried out on a JEOL JEM-ARM200F TEM equipped with a spherical aberration corrector for imaging, Gatan OneView and K2-IS cameras, and at an acceleration voltage of 80 kV, under 1 × 10⁻⁵ Pa in the specimen chamber. Experiments were carried out on a double-tilt holder (JEOL EM-01030RSTH). To remove volatile impurities from the specimen, the holder was heated at 573 K for 30–60 min without electron irradiation before setting a desired temperature. After the stage temperature settled to the target value, we waited for an additional 30 min to minimize thermal drift.

The C60@CNT1 and C60@CNT2 datasets were imaged using the OneView camera under the varying EDR. The raw images were 2,048 × 2,048 pixels (binning 2 mode) with a 32-bit depth and a pixel edge length of 0.0213 nm at 1,000,000× magnification. For C60@CNT1, ten images were taken at ten different EDRs ranging from 1 × 10⁵ to 130 × 10⁵ electrons/nm²/s for a total of 100 images. For C60@CNT2, ten images were taken at 18 different EDRs ranging from 1 × 10⁵ to 123 × 10⁵ electrons/nm²/s for a total of 180 images. Each image was taken with an exposure time of 0.5 s (2 fps). The C60@CNT3 dataset was recorded by the Gatan K2-IS direct electron detection camera. The raw images were 414 × 1,920 pixels with a pixel edge length of 0.021 nm at 400,000× magnification. Each image was taken with an exposure time of 0.000625 s (1,600 fps). The OneView camera uses a scintillator to convert electrons to photons during the acquisition process, which introduces an intrinsic convolution and blurs the resulting image. The K2-IS uses direct electron detection to produce clearer images.

Image Pre-Processing and SNR Calculation

Before denoising, some preprocessing were performed on the raw images. Images were cropped to the relevant area and rescaled to 8-bit tiff-formatted files from the original 32-bit Digital Micrograph file format. 8-bit images were required by the implementations of some denoising algorithms used here. Rescaling to an 8-bit format resulted in some signal loss, but did not affect the relative amounts of denoising achieved with the different methods nor the calculated SNR values to the significant digits reported here. Some of the images contained illumination differences across the image due to the non-uniform spatial distribution of electron flux from the electron beam. This effect was more pronounced at higher EDRs. These pixel intensity trends in the image were removed, so that they would not affect the results. In order to remove these trends, a second-order 2D polynomial surface was fit to each image's pixel intensity values using a least-squares fitting method (Price-Whelan et al., Reference Price-Whelan, Sipőcz, Günther, Lim, Crawford, Conseil, Shupe, Craig, Dencheva and Ginsburg2018). The polynomial fit was subtracted by its mean value to normalize it to a mean of zero and then the result was added to the original image. Sections of these preprocessed images for C60@CNT1 are shown in Figure 3 under the column labelled “Original”.

Many methods exist for calculating the SNR in images, and although there is no agreed upon standard, methods have been developed for medical imaging (Dietrich et al., Reference Dietrich, Raya, Reeder, Reiser and Schoenberg2007), where the vacuum can be taken as the noise and a region of interest (ROI) is taken as the signal. Here, the region containing the C₆₀ molecules represents the signal. The SNR can be calculated using equation (1), where S _mean and N _mean are the mean pixel intensity in the ROI and vacuum, respectively, and N _RMS is the root mean square of pixel intensities in the vacuum.

(1)$$\matrix{ {{\rm SNR} = \displaystyle{{\vert {S_{{\rm mean}}-N_{{\rm mean}}} \vert } \over {N_{{\rm RMS}}}}\;} \cr }. $$

Since the signal is calculated from an ROI, which may have been corrupted by denoising, this metric is useful for determining relative amounts of noise in an image, but does not necessarily show that the signal has been preserved. Large amounts of denoising can corrupt the signal by significantly reducing edge contrast or changing the apparent shape and size of features even as the SNR is increased.

Signal Preservation Calculation

Since the SNR does not show whether the original signal is preserved, it is also necessary to quantify the signal preservation after applying denoising. An ideal denoising protocol will remove noise while fully preserving the sample's features. In this work, the signal preservation was quantified by analyzing the preservation of molecule morphology and by analyzing the preservation of feature edges.

The morphology preservation of the C₆₀ molecules was quantified with a signal score. For each algorithm, the optimum parameter setting was the setting that produces the highest signal score. The steps to calculate the signal score are illustrated in Figure 2. In this process, a template of the true C₆₀ morphology was placed on each molecule, and the signal score was calculated based on the number of matching pixels between the template and the image. A circle detection algorithm using Hough transforms (Yuen et al., Reference Yuen, Princen, Illingworth and Kittler1990) was used to automatically locate the C₆₀ molecules in each image. C₆₀ fullerene molecules have a diameter of 0.7 nm (Sloan et al., Reference Sloan, Dunin-Borkowski, Hutchison, Coleman, Williams, Claridge, York, Xu, Bailey and Brown2000), and the C60@CNT1 and C60@CNT2 images have pixel edge lengths of 0.0213 nm, and thus the circle detection algorithm was set to find circles with a radius of 17 pixels. Circles detected using this algorithm are shown in Figure 2a. A separate template was automatically generated for each image based on the detected circles. An example of such a template is shown in Figure 2b. Wherever a circle was detected, two concentric circles were placed in the template. The outer circle, which represents the molecule ring, had a radius of 17 pixels and was filled with a pixel value of 0 (shown as black). The inner circle represents the interior of the C₆₀ molecule, had a radius of 7 pixels, and was filled with a pixel value of 1 (white). An inner radius of 7 pixels was chosen as an appropriate size after many manual measurements on the unprocessed high EDR images. All template pixels that lie outside the circles were set to a value of 2 (shown as gray). Separately, each image was binarized using Otsu's method (Otsu, Reference Otsu1979), such that darker pixels were set to a value of 0 and brighter pixels set to a value of 1 as shown in Figure 2c. Finally, the signal score was the number of matching pixel values when comparing the binary image with the template image. Matching pixels are shown in Figure 2d highlighted in orange. The signal score was normalized by dividing by the number of circles detected. The maximum possible score in this case is 889, which is the number of pixels that can fit inside a circle with a radius of 17 pixels. A score of 445 or lower means that there is no signal since completely random noise is likely to match half the pixels. The final signal score was scaled to values between 0 and 1 with zero representing 445 matching pixels.

Fig. 2. Calculation of the signal score using circle detection and mask fitting. (a) An image from C60@CNT1 taken at the highest EDR with the detected circles outlined in red. (b) The mask generated from the circle fits where black, white, and gray pixels have a value of 0, 1, and 2, respectively. (c) A binarized version of the original image after thresholding with Otsu's method. Matching pixels in (b) and (c) are highlighted in orange in (d). The final signal score is the number of orange pixels in (d) divided by the number of circles detected and scaled between 0 and 1.

Edge preservation was determined from the derivative of pixel intensity profiles. A line was placed parallel to the CNT running along the center of the C₆₀ molecules. The pixel intensity profile is the plot of the pixel value along the line. In an image, an edge is the location of a sudden change in contrast, which here represents the edges of the molecules or the CNT. During denoising, these edges can become blurred, such that there is a gradual contrast change instead of a sharp change. If the contrast change at an edge is gradual, then it difficult to precisely locate the edge of a molecule, which greatly reduces the accuracy of size measurements. Edge sharpness was quantified by the magnitude of the derivative of the intensity profile across a molecule edge.

Denoising Algorithms

In total, nine denoising algorithms were applied and evaluated with and without downsampling for a total of 18 tests on each image in each dataset. The tested denoising algorithms were the mean, median, Gaussian, and bilateral (Tomasi & Manduchi, Reference Tomasi and Manduchi1998) filters; the Chambolle (Chambolle, Reference Chambolle2004) and Bregman (Osher et al., Reference Osher, Burger, Goldfarb, Xu and Yin2005) total variation denoising algorithms; nonlocal means denoising (Buades et al., Reference Buades, Coll and Morel2005); Wiener–Hunt deconvolution (Hunt, Reference Hunt1971); and low rank approximation with singular value decomposition (Wold et al., Reference Wold, Esbensen and Geladi1987; Lin et al., Reference Lin, Chen and Ma2010). Image corruption can include noise and blur where noise is the quasi-random change of individual pixel values, and blur is the spreading of a point source of brightness described by the point spread function (PSF) and limits the intrinsic resolution of the microscope. Any denoising algorithm assumes a certain model, often a mathematical equation, which defines the relationship between the captured image, the nature of the corruption, and the ideal image that would have been captured by a perfect microscope system. The algorithm solves for or approximates the solution to the assumed ideal image based on this model.

The mean filter reduces noise by averaging together pixels within a specified neighborhood. The Gaussian filter uses weighted averaging where the weight of neighborhood pixels decreases with increasing distance according to the value of a normalized Gaussian distribution with a specified sigma of radial distance. The median filter replaces each pixel with the median value of pixels within a specified neighborhood, a technique that is less sensitive to extreme value pixels. The bilateral filter uses a weighted averaging method that weights neighborhood pixels based on both their spatial proximity and their intensity similarity. By considering intensity, this method preserves image feature edges such as molecule edges, unlike the mean, Gaussian, and median filters which indiscriminately blur edges. Deconvolution algorithms such as Wiener–Hunt deconvolution seek to reduce blur (Hunt, Reference Hunt1971). These methods, however, require prior knowledge of the PSF and perform poorly on noisy images. Some work has been done to estimate the PSF from microscopy images, but the work is ongoing (Liu et al., Reference Liu, Yousefi, Zhi and Wang2011; Dalitz et al., Reference Dalitz, Pohle-Frohlich and Michalk2015; Roels et al., Reference Roels, Aelterman, De Vylder, Luong, Saeys and Philips2016). Here, a numerical Bayesian approach is applied to iteratively estimate the PSF for the Wiener–Hunt filter (Orieux et al., Reference Orieux, Giovannelli and Rodet2010). Without advances in estimating the PSF and in performing deconvolution on noisy images, this method is not expected to perform well, but is included here for completeness and comparison with past work on EM denoising (Kushwaha et al., Reference Kushwaha, Tanwar, Rathore and Srivastava2012). The non-local means algorithm works well for denoising images with specific repeated textures (Buades et al., Reference Buades, Coll and Morel2005). Instead of averaging together neighboring pixels, pixels are averaged when they are surrounded by similar patches, even if they are in different parts of the image. Low rank approximation with singular value decomposition has also been successful in denoising (Wold et al., Reference Wold, Esbensen and Geladi1987; Lin et al., Reference Lin, Chen and Ma2010). A singular value decomposition can be performed on an image matrix I using I = UΣV^⊤, where U and V are orthogonal matrices, and Σ is a diagonal matrix whose entries are called singular values. A denoised image is reconstructed from a low rank matrix which is found by keeping only the top specified n values of Σ, setting the rest to zero and solving for a new I.

Total variation techniques assume that image noise takes the form of sharp intensity differences (i.e., variation) between neighboring pixels in the image and seeks to remove this variation while producing a denoised image that is otherwise similar to the input image. By limiting the total variation reduction subject to the similarity between the input and output images, contrast due to the signal, such as molecule edges, is preserved. The total variation solution is formulated as a co-minimization problem as shown in the following equation:

(2)$$\matrix{ {u = \mathop {\min }\limits_u \lsqb {D\lpar {u\comma \;g} \rpar + \lambda V\lpar u \rpar } \rsqb } \cr }, $$

where u is the denoised image, g is the noisy image, λ is a weight parameter, D is a difference function, and V is a total variation function. The weight parameter determines the preference for more strongly reducing pixel variation or preserving the original image. The initial total variation formulation (Rudin et al, Reference Rudin, Osher and Fatemi1992) used the L₂ norm as the difference function:

(3)$$\matrix{ {\;D\lpar {u\comma \;g} \rpar = \sum\limits_i^n {\sum\limits_j^m {{\lpar {u_{i\comma j}-g_{i\comma j}} \rpar }^2} } } \cr }, $$

where n and m are the number of pixel rows and columns, respectively, and i and j are the pixel indexes. For the variation function they used:

(4)$$\matrix{ {V\lpar u \rpar = \sum\limits_i^{n-1} {\sum\limits_j^{m-1} {\sqrt {{\vert {u_{i + 1\comma j}-u_{i\comma j}} \vert }^2 + {\vert {u_{i\comma j + 1}-u_{i\comma j}} \vert }^2} } } \;} \cr }. $$

However, this initial formulation is difficult to solve because it is non-differentiable and an infinite-dimensional minimization problem (Duran et al., Reference Duran, Coll and Sbert2013). Several modifications have been proposed with adjustments to D, V, or the minimization method. But in all cases, the essence captured in equation (2) remains, where the total variation in the denoised image is reduced subject to fidelity to the original image. The Chambolle method uses a projection algorithm based on a dual formulation and is solved with gradient decent, while the Bregman method uses an operator splitting method (Duran et al., Reference Duran, Coll and Sbert2013). More details can be found in their respective papers (Chambolle, Reference Chambolle2004; Osher et al., Reference Osher, Burger, Goldfarb, Xu and Yin2005).

Gaussian downsampling can be applied before denoising to resample the image to a proper sampling frequency where, according to the Nyquist–Shannon Sampling Theorem (Jerri, Reference Jerri1977), the pixel edge length should be 2.3–3 times smaller than the point-to-point resolution of the microscope. Prior to resampling the image to a larger pixel size, a Gaussian filter is applied with an appropriate kernel size to eliminate image frequencies higher than the Nyquist cutoff frequency of the resampled image. The effects of downsampling can be seen by comparing the third and fourth image columns in Figure 3. The results may appear to be insignificant upon visual inspection, but this is often an important first step. All denoising algorithms are applied to both the original and downsampled datasets for comparison.

Fig. 3. Cropped images of C60@CNT1 at various EDRs before denoising (original) and after denoising with downsampling and the specified algorithm. Here, Cham specifies the Chambolle total variation denoising algorithm with the weighting parameter λ. The standard deviation of the bilateral kernel size is given by σ.

Open-source code and a standalone application to apply Chambolle denoising to TEM images and video frames are available at https://github.com/JStuckner/smart_preprocess.