2.1. Physical setup at the 1-ID-E endstation

The FF-HEDM setup is illustrated in Figure 1. The monochromated high-energy X-ray beam is produced from a combination of a superconducting undulator source (Ivanyushenkov et al., 2017) and a bent double Laue high-energy monochromator (Shastri et al., 2002) located approximately 70 m upstream of the endstation. The energy bandwidth of the monochromated beam is approximately 1 × 10⁻³. The size of the beam impinging on the sample's volume of interest (VOI) is defined by a series of slits, sometimes in combination with focusing optics (Said & Shastri, 2010; Shastri et al., 2020).¹ Between the final slits and the sample, an ion chamber exists to measure the incident beam flux; its reading is denoted as IC0 hereon. The stage stack illustrated in Figure 1 is assembled to align the rotation stage to the incident beam and the sample to the rotation axis. Table 1 summarizes the available motions, their functions, and motion performance.² The motion resolution and repeatability of the hardware used in this work exceed the intentional motions executed. The distance from the top of the rotation stage to the beam is approximately 300 mm and the distance from the top of the optical table to the beam is approximately 700 mm. The optical table is equipped with an inclinometer capable of measuring rotations about x_L and z_L³ to monitor the angular perturbation of the table. The area detector is placed approximately 1000 mm from the sample on a separate, stable optical table. The area detector used in this work is an amorphous Si detector with a nominal pixel pitch of 200 µm × 200 µm and detection area of 409.6 mm × 409.6 mm (Lee et al., 2007, 2008). The direct beam is blocked by a beam stop placed in front of the area detector. It consists of a tungsten block with an embedded pin diode often used to acquire transmission information and placed approximately 5 cm in front of the area detector along z_L. The temperature fluctuation in the endstation is approximately ±0.2°C when the endstation remains closed for an extended period of time similar in length as the duration of the measurements conducted for this work.

Figure 1 A schematic of the APS 1-ID-E setup for HEDM.

2.2. MIDAS framework for FF-HEDM

There are several software packages available for the analysis of FF-HEDM data (Gotz et al., 2003; Bernier et al., 2011; Schmidt, 2014; Sharma, 2020). In this work, we employ the MIDAS software suite for data analysis. Figure 2 illustrates the relevant coordinate systems used in MIDAS. Here, a high-level summary of the framework is described. A more detailed description of the framework is presented by Sharma et al. (2012a,b; Sharma, 2021). In Figure 2, the subscripts L, D, S, and C correspond to the laboratory frame, the detector frame, the sample frame, and the crystal frame, respectively. The z_L direction is the beam propagation direction. Rotation of the sample occurs about and it is denoted as ω. For FF-HEDM⁴ it is desirable to have parallel to y_L⁵; the angle between y_L and , denoted as Ω, is defined as the wedge angle. Finally, x_L is the cross product between y_L and z_L. The origin of x_L-y_L–z_L is denoted as O_L. In practice, the vertical blades of the slits are aligned to the x_L–z_L plane; similarly, when sawtooth refractive lenses are employed (Said & Shastri, 2010; Shastri et al., 2020), the vertically focused planar beam is aligned to the x_L–z_L plane.

Figure 2 The MIDAS analysis framework and relevant coordinate systems. A polycrystalline sample is rotated about and the rotation is denoted as ω. The angle between yL and is denoted as Ω.

Often, the detector frame does not coincide with the laboratory frame by a simple translation. The goal of detector calibration is to determine the relationship between the two frames and, hence, the location of any point on the area detector with respect to the laboratory frame. Several standards are used for calibration. The nominal distance from O_L to the detector⁶, location of the direct beam on the detector, detector tilt with respect to x_L and y_L, and the distortion of the detector are determined using the diffraction patterns from CeO₂ (Kaiser & Watters, 2007) or LaB₆ (Freiman & Trahey, 2000). The distortion of the detector is described using a model that combines the approaches presented by Lee et al. (2008) and Borbély et al. (2014a,b). These parameters are fine-tuned and the tilt of the detector with respect to z_L is determined using a ruby (Freiman, 2001) or gold single crystal (Shade et al., 2016) whose lattice parameter and geometry are well known.

The VOI is rotated about continuously over a 360° range while area detector patterns are collected at fixed ω intervals. An area detector pattern contains the diffraction spots from the crystallographic planes in the VOI that satisfy the diffraction condition over the ω interval. These diffraction spots and corresponding scattering vectors (q) combined with the nominal crystallographic symmetry and lattice parameters for the material of interest in the VOI are used to determine the center of mass (COM) of the illuminated coherent lattice⁷ with respect to O_L; the relationship between the crystal frame and the laboratory frame, commonly referred to as crystallographic orientation, and the elastic strain tensor of each crystal with respect to the prescribed reference state are also determined.

For the amorphous Si detector used in this work, the readout is occurring cyclically row-by-row from the center line of the detector toward the edges in 126 ms with a 124 µs dead-time per each pixel (Lee et al., 2008). Therefore, the dead-time is often negligible relative to the integration time (>150 ms) used in the present study and is not anticipated to influence the measured intensities. However, this also means that the pixels that are closer to and the pixels farther away from the center line of the detector in a frame have slightly different ω positions. Therefore, a correction for this systematic temporal artifact is to be applied during data processing. Such correction is taken into account in MIDAS by considering the appropriate integration interval for each pixel row when calculating the center of mass position of individual diffraction peaks (Sharma, 2021).

It is noteworthy that the relationship between the sample and laboratory frames⁸ is not introduced to this framework explicitly; the relationship between the laboratory and sample frames needs to be established through other means such as radiography, tomography, and/or attaching particles to the VOI that are insensitive to the applied stimulus (Shade et al., 2016) so that rigid-body rotation and translation of the VOI can be tracked during an in situ experiment or ex situ measurements in between which the sample is processed.

6.1. Repeated measurements (DS-A-SS)

For DS-A-SS, ten FF-HEDM scans were performed while the sample was rotated in the positive direction (from −180° to +180°) and another ten scans in the negative rotation direction (Table 2) spanning over several hours. Here, we only show the results from the positive rotation scans for brevity; the findings from the negative rotation scans are consistent and repeatable as those from the positive rotation scans. Table 6 shows the number of grains found (N_grain) from the repeated scans. It also shows the %-change in the number of diffraction spots detected (Δ_SPOT) and %-change in the IC0 value (Δ_IC0) with respect to the first scan. In the first scan, the total number of diffraction spots found was 89515 and the IC0 value was 233.9 kHz. Average N_grain is 214 with a standard deviation of 2, maximum of 216 and minimum of 210. During these repeated measurements, Δ_SPOT and Δ_IC0 showed minimal changes. Furthermore, Δ_SPOT and Δ_IC0 did not indicate a strong correlation with the number of found grains.

The grains found in each scan are matched with respect to the grains found from scan 1 using the matching method summarized in §5 without the volume filter. The mean, median, and standard deviation of the change in COM along x_L, y_L, z_L, and orientation of the matched grains are computed over the ten scans. Table 7 lists these calculated values. This table shows that the instrument is in general stable and repeatable as indicated by the mean and the median values. However, a large standard deviation indicates that there may be some outlier grains that may be improperly paired.

Table 8 summarizes the number of grains matched for each scan with different grain radius filter levels. The number of grains matched decreases with smaller radius filter. Using 2% radius tolerance, the number of grains from scan 1 that are successfully matched is on average 207 grains out of 214 grains found in scan 1. Table 8 also show that using a bigger radius tolerance allows more grains from two scans to be matched.

Using the matched grain pairs that satisfy the 5% grain radius tolerance, the values presented in Table 7 are recomputed (Table 9). In this case, the difference in COM along x_L, y_L, and z_L are all on the order of 1 µm with significantly smaller standard deviation than those shown in Table 7. The difference in crystallographic orientation is 0.01° with a small standard deviation. This is because the false positive grain pairs are removed by the grain radius tolerance. The missing grains plotted in orientation space or in physical space did not show any significant trends in those spaces. Figure 3 shows the histograms of change in COM Y without and with the volume filter for one of the scans in the repeatability dataset. Figure 4 shows the histograms of misorientation without and with the volume filter for one of the scans in the repeatability dataset. Both figures show that large outliers are removed through the volume filter.

Figure 3 Histograms of COM Y difference between matched grains without (left) and with (right) the volume filter for a repeatability scan. In the left-hand figure, the Y-axis is truncated from 120 to show the values at higher Y values.

Figure 4 Histograms of misorientation angle between matched grains without (left) and with (right) the volume filter for a repeatability scan. In the left-hand figure, the Y-axis is truncated from 170 to show the values at higher misorientation angles.

The radius of the missing grains was in general less than 50 µm while the mean and the standard deviation of the grain radius in the VOI were 61 µm and 13 µm, respectively. This indicates that the missing grains are some of the smaller ones in the VOI. This is further illustrated in Fig. 5. In this figure, the left-hand scatter plot compares the radii of the matched grains obtained at the reference scan (scan 0) and the Nth scan with the volume filter turned off, and the right-hand scatter plot shows similar data with the volume filter turned on. In both scatter plots, the dotted red line shows the case where the radii of the matched grains are identical. The left-hand figure shows that the grains with significantly different sizes can still be declared as matching when the volume filter is not used; the dots that appear away from the dotted red line illustrate this point.

Figure 5 Scatter plots comparing the radii of the matched grains obtained at scan 0 and the Nth scan. The left-hand plot is without the volume filter and the right-hand plot is with the volume filter used in the grain matching process. The red line is added to show the ideal case where the radii of the matched grains are identical.

In the subsequent sections with intentional motions, the grain matching procedure with 5% grain size filter was used, resulting in removing false positive matches and a similar reduction in standard deviation illustrated in Tables 7 and 9.

Figure 6 shows the difference in elastic strain tensors between the tracked grains between the first scan and the third scan (chosen arbitrarily; the other scans also show a similar distribution). This figure shows that for the tracked grains the component-wise difference in strain is negligible on average. However, the difference can be as large as 2 × 10⁻⁴. Table 10 shows the difference in elastic strain tensor over the entire DS-A-SS. Consistent with Fig. 6, the average differences are smaller than 1 × 10⁻⁴ but the standard deviation can be as large, 1 × 10⁻⁴. Reducing this distribution will be critical as we push to employ FF-HEDM to investigate rare-event-driven material behavior such as fatigue and crack initiation.

Figure 6 A histogram plot of the change in elastic strain tensors between the tracked grains in DS-A-SS between the first scan and the third scan.

6.2. Intentional translations (DS-B-SS)

For DS-B-SS, the VOI was translated intentionally from O_L using samX and samZ translations before acquiring FF-HEDM data. Here, only the results from intentional samX motion are presented for brevity; the results from intentional samZ motion and compound samX–samZ motion were similar. Table 11 summarizes the result. The number of grains found in the reference configuration is 379. In general, when the magnitude of intentional motion is less than 50 µm, most of the grains can be mapped back to the grains found in the reference state; for example, with 5 µm intentional translation, 378 out of 379 grains from the reference state are detected. The missing grains are in general small and their orientations and COMs did not show any systematic trends. With larger intentional motions, the number of the grains found and matched to the reference configuration decreases. At 500 µm intentional motion, only 253 grains out of 379 grains found in the reference configuration can be found. The missing grains are located primarily in the periphery of the VOI where the grains are not always illuminated by the incident X-rays.

The median change in COM along x_L listed in Table 11 is a convolution of the rigid-body motion introduced by the the intentional motion, unintentional motion, and the instrument sensitivity. If the known rigid-body translation component is removed from the median change in COM along x_L, the resulting difference is comparable with the repeatability values associated with DS-A-SS (Table 9) particularly when the magnitude of the intentional motion is small. This implies that the instrument is capable of detecting translation as small as 5 µm, reliably. However, the intentional translation may also be introducing a slight rigid-body rotation as the median misorientation values are slightly larger than those in Table 9. These results indicate that the FF-HEDM instrument is sensitive to approximately 5 µm translation.

Figures 7 and 8 show the differences in strain as the VOI is intentionally translated by 5 µm and 500 µm, respectively. Similar to the DS-A-SS case, the average component-wise strain difference is close to zero but the difference can be as large as 2 × 10⁻⁴. For larger intentional translation (Fig. 8), the standard deviation of the difference distribution is slightly larger. But overall, the strain difference is similar to that observed in DS-A-SS. This implies that smaller rigid-body translations do not affect the strain significantly and the MIDAS framework is accounting for the rigid-body translation appropriately.

Figure 7 A histogram plot of the difference in elastic strain tensors between the tracked grains in DS-B-SS between the first scan and the scan after 5 µm intentional motion. Strain units in 10−4.

Figure 8 A histogram plot of the difference in elastic strain tensors between the tracked grains in DS-A-SS between the first scan and the scan after 500 µm intentional motion. Strain units in 10−4.

6.3. Intentional rotations

The angular sensitivity of the instrument is characterized by intentionally rotating the sample by a known value. As described in §3, these intentional rotations can also induce unintentional motions. The unintentional motion is not compensated in DS-C-SS (§6.3.1). It is compensated in DS-C-Au (§6.3.2).

6.3.1. Stainless steel sample (DS-C-SS) without compensating for the unintentional motion

For DS-C-SS, the VOI was tipped intentionally using ξ. The VOI was not realigned to O_L after each ξ motion to investigate the effect of un­intentional motion. At the end of the data acquisition, the VOI was returned to its reference configuration (ξ = 0°) to confirm that the motion was repeatable.

The number of grains found in the reference configuration was 379. Table 12 summarizes the result. For intentional ξ motion, the changes in x_L and z_L are negligible while the change in y_L increases in magnitude with increasing ξ. This indicates that the pivot point of the ξ motion and O_L do not coincide and an unintentional rigid-body translation is included. The number of grains matched to the grains in the reference configuration also decreases with increasing ξ. Nevertheless, the median misorientation angle for the matched grains agrees with the input ξ motion well.

Table 12 A summary of detected motions when the VOI is rotated using ξ without compensating for unintentional motion The last row shows the statistics after returning the VOI to its original configuration. Motion using ξ (°) Median misorientation (°) Median change in COM along xL (µm) Median change in COM along zL (µm) Median change in COM along yL (µm) Number of grains matched 0.05 0.07 0 1 −6 365 0.10 0.11 0 1 −10 361 0.25 0.26 −1 0 −24 343 0.50 0.50 1 −1 −49 269 1.00 1.00 1 −2 −95 205 0.00* 0.04 1 0 0 370

The median misorientation listed in Table 11 is a convolution of the rigid-body motion introduced by the intentional motion, unintentional motion, and instrument sensitivity. If the known rigid-body rotation component is removed from the median misorientation, the resulting difference is comparable with the repeatability values presented in Table 9 even at relatively large intentional rotations. However, as described above, the intentional motion is introducing an unintentional translation in y_L. As anticipated, the unintentional translation in y_L increases with the magnitude of the intentional motion.

Figure 9 shows the differences in strain as the VOI is intentionally rotated by 0.25°. Similar to the DS-A-SS case, the average component-wise strain difference is close to zero but the difference can be as large as 2 × 10⁻⁴. Overall, the strain difference is similar to that observed in DS-A-SS.

Figure 9 A histogram plot of the difference in elastic strain tensors between the tracked grains in DS-A-SS between the first scan and the scan after 0.25° intentional motion. Strain units in 10−4.

6.4. Intentional wedge angle (DS-D-SS)

For DS-D-SS, a set of FF-HEDM scans was conducted with non-zero Ω. This motion was realized using the three vertical motions of the optical table (Figure 1). The tilt values were acquired by the tilt sensors on the table. The three vertical motions were adjusted such that remains nominally on the y_L–z_L plane. For each Ω motion, the VOI was positioned to O_L before conducting the FF-HEDM scan. During analysis of these datasets using MIDAS, Ω was initially set to zero and Ω was independently refined using MIDAS as a blind test. The values of Ω determined from MIDAS agreed with the actual readings from the inclinometer attached to the optical table (Figure 1). These refined values for Ω were then used to analyze the data.

Table 14 summarizes the result. As with datasets B-SS and C-SS, the number of grains found in the reference configuration was 379 and the grain radius filter was 5%. With larger magnitudes of Ω, the number of matched grains decreases. This is again due to the original VOI not being illuminated continuously during the FF-HEDM scan when Ω is non-zero. For the grains that are successfully matched, the deviation in COM and orientation are minimal indicating that the MIDAS framework appropriately accounts for a non-zero Ω.

When a non-zero Ω is introduced to the physical setup but not accounted for in the MIDAS data analysis, grain COM, orientation, and elastic strain tensor were all influenced significantly. In particular, Fig. 10 shows the component-wise elastic strain tensor distribution when Ω = 0.25° and this is not accounted for in the MIDAS analysis. The normal strain components deviate significantly from those measured when Ω = 0° or when Ω is accounted for. On the other hand, the shear components seem to be less affected by Ω. It is noteworthy that similar observations have been presented (Poshadel et al., 2012) where some strain components are more susceptible to error than the others depending on the experimental geometry. In this case, the dominant effect of Ω is the change in sample-to-detector distance which is directly related to the normal components of strain. This highlights that appropriately accounting for Ω in the analysis is important.

Figure 10 A histogram plot of the difference in elastic strain tensors between the tracked grains in DS-D-SS between the first scan and Ω = 0.25° without account for Ω in the MIDAS analysis. Strain units in 10−4.

7.1. Instrument performance

Based on the results presented in §6, the FF-HEDM instrument's repeatability in translation, rotation, and strain are approximately 5 µm, 0.02°, and 2 × 10⁻⁴, respectively, when an appropriate grain matching method is used. Without an appropriate matching method, these numbers – particularly the mean and the standard deviation associated with these values – increase significantly as indicated by Tables 7 and 9. The instrument sensitivity, based on the intentional motion results (Tables 11, 12, and 13), is approximately 5 µm and 0.05° for translation and rotation, respectively. For larger grains that can take full advantage of the detector dynamic range, these values can be better.

It is worthwhile to note that the materials used in this work represent an ideal case. Both samples (stainless steel and Au cube) are fabricated from a well scattering material with well known crystal structure. They are both free of large plastic deformation. These characteristics mean that the diffraction spots do not have large angular spread and can suitably be fit with a simple peak profile function. In a real sample, subject to various types of in situ stimuli, the material state of constituent crystals will evolve, often increasing the defect density. This means that the diffraction spots will, in general, have large angular spread and cannot be fit well with a simple peak profile function. Since the repeatability and the sensitivity figures presented here depend on the quality of diffraction spots and how well they are fit, it is probably reasonable to anticipate that the performance figures reported here are closer to the ultimate performance attainable with the current FF-HEDM instrument. There are several avenues to improve these performance metrics. For instance, reducing the detector pixel size, ω step size used for scanning, and bandwidth of the monochromatic X-rays (Shastri, 2004) can all lead to gains in sensitivity. Currently, these approaches are often limited by available beam time or the temporal resolution required in an experiment. But significant gains in detector technology and storage ring upgrades can bring these approaches closer to reality.

As highlighted throughout this work, the stability of the physical setup and the accuracy in the representation of the setup in the analysis framework are paramount to acquiring a reliable microstructural map. As highlighted in §6.3.1 where the unintentional motion of the VOI was not compensated (DS-C-SS) physically or in §6.4 where the physical setup differed from the analysis framework (DS-D-SS), these discrepancies and instabilities can have significant consequences to the microstructural map. In DS-C-SS, many grains found in the reference configuration were lost or had large motions. In DS-D-SS, many grains seemingly had significant hydrostatic strain compared with the reference configuration. Overall, maintaining the stability of the physical setup at the level of 1 µm and 0.01° during an FF-HEDM measurement is desirable. At the APS, with the robust measurement hardware and reliable software framework to analyze the FF-HEDM data, we were able to successfully index approximately 20000 grains in a 1 mm × 1 mm × 0.1 mm VOI with 0.8 completeness. There were approximately 1.1 million diffraction spots indexed and refined by MIDAS running on an APS high-performance computing cluster. Figures 11 and 12 show a COM map from a VOI in a nickel-based superalloy measured using the FF-HEDM instrument and corresponding grain size distribution histogram, respectively.¹⁸ Newer developments such as employing artificial intelligence in peak search (Liu et al., 2020), addressing overlapped diffraction spots, and collaborations with larger high-performance computing facilities like the Argonne Leadership Computing Facility (Wozniak et al., 2015; Wolf, 2014) will push this limit further and allow us to provide grain-resolved information in polycrystalline materials with a higher degree of structural complexity than ones HEDM can investigate today. This stability requirement will be even more stringent as the technique is pushed to investigate more complex material systems.

Figure 11 An example of a grain COM map acquired using the FF-HEDM instrument. The number of grains found is approximately 20000. The position of the dots denotes the grain COM in space and the color of the dots denotes the grain radius.

Figure 12 The grain size distribution based on the FF-HEDM map in Fig. 11.

7.2. Inconsistency between the datasets

While the FF-HEDM instrument performs reasonably well during a measurement session, there are also inconsistencies between the datasets acquired at different times that highlight the limitations of FF-HEDM and warrants further investigation. The number of grains found in DS-A-SS is significantly smaller than those found in DS-B-SS, DS-C-SS, and DS-D-SS even though the identical sample was illuminated in all four datasets. The number of grains found in DS-A-SS was approximately 200 while the number of grains found in DS-B-SS, DS-C-SS, and DS-D-SS was approximately 380. However, the beam size used for DS-A-SS was twice as large as that used for DS-B-SS, DS-C-SS, and DS-D-SS. Given the beam size, the number of grains found in these datasets should show an opposite trend. However, if we considered the size of the illuminated volume and the number of grains found to compute the average grain radii (assuming the grains are spherical) in DS-A-SS and the other SS datasets, the grain radius is approximately 60 µm and 40 µm for DS-A-SS and the other SS datasets, respectively. A grain radius range of 40–60 µm is reasonable for this material based on metallography.

The discrepancy in the number of grains found between different datasets is most likely because of the reflections used in the analysis (Table 3). In the case of DS-A-SS and associated MIDAS analysis, many reflections with vastly different scattering power were used while a smaller number of reflections with higher scattering power were used in other datasets. Satisfying the completeness value of 0.8 in DS-A-SS, therefore, is probably more challenging than the other datasets. This implies that the exposure settings for data acquisition and the choice of reflections used in the analysis can influence the resulting microstructure map.

In the case of DS-A-SS, it is noteworthy that there are a significant number of diffraction spots that are not assigned or indexed to grains. The average N_grain in DS-A-SS is 214 and the anticipated number of diffraction spots for a grain is 244 (Table 3); this means that 52216 diffraction spots and 41773 diffraction spots need to be detected with a completeness of 1 and 0.8, respectively. When these are compared with the actual number of diffraction spots detected, approximately 50% of the detected diffraction spots are not assigned to grains. Figure 13 shows a histogram of the assigned (and indexed to grains) and unassigned diffraction spots in a DS-A-SS scan. This figure indicates that the intensity of the unassigned diffraction spots is typically lower compared with that for the assigned diffraction spots. Dissecting Fig. 13 further into different {hkl}s, we can see that the majority of the inner and generally more intense diffraction spots are unassigned (Fig. 14) while the majority of the outer and generally less intense spots are assigned to grains (Fig. 15). A combination of high completeness and inclusion of higher-order diffraction spots in the MIDAS analysis are contributing factors to a large number of detected diffraction spots being unassigned to grains. This implies that a grain detection limit associated with the grain size distribution in the VOI exists and highlights that an FF-HEDM experiment and associated data analysis need to be designed and conducted carefully, particularly when the goal for acquiring a 3D grain-resolved microstructural map is to investigate rare-event driven phenomena in materials. An independent measurement like optical or electron microscopy to confirm the FF-HEDM results (at least statistically) is encouraged, particularly when investigating a new or unknown material.

Figure 13 A histogram of the number of diffraction spots that are assigned or unassigned to grains in a DS-A-SS scan.

Figure 14 A histogram of the number of diffraction spots that are assigned or unassigned to grains in a DS-A-SS scan for the {220} ring.

Figure 15 A histogram of the number of diffraction spots that are assigned or unassigned to grains in a DS-A-SS scan for the {422} ring.

As described in §4, the analysis parameters for each dataset presented in this work were carefully determined to yield stable and reproducible results at the time the measurements were conducted. The number of grains found in DS-A-SS can be increased to more than 500 grains if the number of reflections used in the analysis decreased, completeness threshold decreased, or peak detection threshold altered. However, adjusting these analysis parameters to ensure that all SS datasets have a consistent number of grains matching the illuminated volume size will be misleading. More importantly, we are currently working with the 3D EBSD community to understand the effects of MIDAS analysis parameters on the resulting microstructure better and we hope to report on this in the near future.

7.3. Matching grains

In situ grain-resolved X-ray microscopy, including the FF-HEDM technique described here, has been lauded as a novel non-destructive characterization technique capable of investigating the small changes that occur at the grain length scale while applying macroscopic stimuli. This implies that matching of grains measured at different macroscopic stimuli levels needs to be robust and reliable. As we investigate more complex material systems with smaller grain sizes, grain matching will be more challenging. There are several methods in MIDAS and associated tools to enhance the reliability and robustness of grain matching and they are listed here:

(i) The diffraction data acquired with applied macroscopic stimulus can be analyzed with the grains found at the reference state as the initial guess to instantiate the indexing process. In this case, MIDAS will only look for grains that existed in the reference state. Whether the grains found in the reference state are indexed again needs to be verified. Additionally, the number of spots that are unclaimed also needs to be monitored.

(ii) If the list of grains found in the reference state is not used to instantiate the indexing process, various grain matching methods can be used. In this work, the grains were matched by considering the entire misorientation and distance tables computed between two sets of grains measured in between an intentional motion. Additional grain matching filters such as grain size can also be use for grain matching.

Another important aspect of grain matching and operating on the microstructure maps is accounting for the sample frame. In this work, the relationship between the sample frame and the laboratory frame was not monitored diligently because the sample frame is not highly relevant. However, when a `real' sample with a very specific frame is measured, the relationship between the sample frame and the laboratory frame needs to be tracked. After all, reporting the orientation relationship between the crystal and the laboratory frame is not the goal of HEDM; the goal is to report the orientation relationship between the crystal and the sample frame. Therefore, appropriate fiducial markers and methodologies to extract the relationship between the sample and laboratory frames is crucial for HEDM measurements. At the APS 1-ID-E, complementary tomography measurements are routinely conducted to assist in monitoring the relationship between the sample and the laboratory frames. Furthermore, various types of fiducial markers (Shade et al., 2016) can be attached near the VOI so that a sample can be removed from the beamline to evolve its state before measuring it again with HEDM for processes that are not suitable or unavailable for in situ experiments.