2.2.1. Magnetorheological finishing

Magnetorheological finishing (MRF) [Fig. 3(a)] is a polishing technique involving holding the mirror close to a rotating element (such as a wheel or belt) inside a magnetic field (Kordonski & Jacobs, 1996; Harris, 2011). A slurry flows between the mirror and the rotating element, containing a mix of magnetic particles and abrasive particles, and the action of the slurry against the mirror causes removal of material. The fluid pressure may be changed in real time by adjusting the magnetic field strength, which increases or decreases the viscosity of the slurry due to the presence of the magnetic particles. Thus, the removal rate may be adjusted at different points on the mirror's surface, enabling deterministic correction. For precise deterministic polishing, the removal must be precisely known. Therefore, the impact of the fluid parameters – composition, consistency, temperature, pressure, and so on – must be carefully calibrated to ensure well controlled removal and precise error correction.

2.2.2. Fluid jet polishing/elastic emission machining

Fluid jet polishing (FJP) and elastic emission machining (EEM) [Fig. 3(b)] are two closely related techniques, which use a high-pressure jet of fluid or polishing slurry that is rastered across the mirror to deterministically remove material (Yamauchi et al., 2002a,b; Li et al., 2011; Buss et al., 2022). In addition to deterministic removal at the centre of the jet, a layer of fluid spreads in a wider area over the surface, which may contribute additional smoothing of the microscale surface features. Therefore, the technique maintains or may improve the microroughness of the surface along with correcting the figure error. Although the terms FJP and EEM are occasionally used interchangeably, generally EEM involves a chemical method of removal (Yamauchi et al., 2002a; Mori et al., 2003), whereas FJP typically involves physical removal by the action of abrasive particles (Faehnle & Brug, 1999; Booij et al., 2001).

FJP and EEM both allow high-precision correction of figure errors. The tool head size is typically on the order of 0.2–1 mm, allowing figure errors on a similar spatial wavelength to this to be corrected. The technique may be applied to a range of surfaces, and the parameters of the fluid jet, including pressure, nozzle size and the composition of the slurry, may be chosen depending on the requirements of the mirror. For this reason it is a very powerful and versatile technique. However, as with MRF, the impact of factors such as temperature, pressure and slurry composition (including species and particle size) must be exactly calibrated and controlled, both to ensure precise removal, and to minimize the impact on surface roughness of the jet (Fang et al., 2006; Peng et al., 2013; Li et al., 2010). Additionally, due to the low removal rates, which vary depending on the hardness of the material from ∼10 nm s⁻¹ to well under 1 nm s⁻¹ (Faehnle & Brug, 1999; Yamauchi et al., 2002a; Li et al., 2011), the total figuring time for EEM/FJP may be long, up to tens of hours or more. Hence, there is a particular challenge involved in ensuring the parameters are sufficiently stable to maintain accurate removal during the figuring.

2.2.3. Differential deposition

Differential deposition [Fig. 3(d)] is an additive technique, which corrects errors by selectively depositing a thin film of material onto the mirror. The thickness of the layer is controlled by varying the motion of the sputtering source relative to the mirror (Alcock & Cockerton, 2010; Morawe et al., 2019; Kim et al., 2021, 2023; Bras et al., 2023). A mask may be used to control the profile deposited on the mirror's surface, which can vary in size from a few millimetres to tens of millimetres, enabling correction of both long- and medium-wavelength features. This technique is well suited to X-ray mirrors, and is applied as one or more corrective layers before deposition of the reflection coating typically used for beamline mirrors. As an additive technique, differential deposition is particularly well suited for correction of recessed or `negative' features on a mirror's surface, which are more challenging to correct with techniques that remove material. Careful consideration of the deposited material or material(s) is required to ensure the roughness of the substrate is not increased by deposition of the corrective layer (Morawe et al., 2019; Kim et al., 2023). In addition, the technique is generally restricted to 1D correction, which is effective for improving tangential height and slope errors for glancing-angle X-ray mirrors (such as focusing Kirkpatrick–Baez mirrors) but may be limited for 2D figuring.

2.2.4. Ion beam figuring

Ion beam figuring [Fig. 3(c)] is a deterministic figuring technique which uses a neutralized ion beam to sputter material from the mirror. The size of the beam profile generally varies from below one millimetre to a few tens of millimetres, enabling both coarse and fine error correction. The beam typically has a very low removal rate, on the order of a few nanometres per second, allowing sub-nanometre figure errors to be obtained after correction. Some polycrystalline materials suffer surface roughness degradation after sputtering (Egert et al., 1992); however, it is suitable for many materials commonly used for X-ray mirrors, such as Si, SiC, Zerodur and ULE glasses (Soufli et al., 2012).

A crucial advantage of IBF is that there are no edge effects or fall-off seen at the edges of a mirror (Yang et al., 2017), unlike for other methods such as MRF, as well as the majority of mechanical polishing techniques. Therefore, IBF is particularly suited to correct mirrors where the clear aperture is very close to the physical edges of the surface, and also strongly curved mirrors. Unlike MRF and FJP, a polishing slurry is not used, removing the requirement of post-processing cleaning and drying of the mirror.

Ion beam sputtering may also be used to improve surface micro-roughness when the beam is employed at an oblique angle (typically around 40°), in a process known as (direct) ion beam smoothing (IBS) (Frost et al., 2004, 2009; Ziegler et al., 2010; Arnold et al., 2010). A related technique, known as ion beam planarization (IBP), involves an additional spin-coated layer which is chosen to have the same removal rate as the mirror underneath at a particular sputtering angle (Frost et al., 2004; Arnold et al., 2010; Li et al., 2017). Both IBS and IBP have been shown to be promising for reducing the micro-roughness of surfaces, down to around 2 Å r.m.s. under optimal conditions. However, for Si X-ray mirrors, existing mechanical-chemical polishing techniques can already provide a surface with extremely low roughness (sub-Å r.m.s.). Hence, in this work, we will focus on IBF at normal or near-normal incidence for figure error correction.

3.2.1. Ion source

The parameters of the ion source dictate the removal capabilities of the IBF system. Temporal stability and linearity of the removal are crucial for precise figuring, and therefore the ion source must also be highly stable.

A Kaufmann (gridded) ion source is typically used, with the grids generally made of pyrolitic graphite due to improved thermal stability. Argon is the most common choice of gas, although other heavier inert gases such as neon (Chkhalo et al., 2017) or xenon (Chkhalo et al., 2014) are also used, which may improve the resulting surface roughness for some materials. When inert gases are used, the sputtering process is purely physical, which helps to ensure linearity of the removal rate.

In RIBE, a variant of IBF, reactive gases such as oxygen are used for sputtering, causing the formation of chemical products during the etching process (Bauer et al., 2017). RIBE has the advantage of higher removal rate in certain cases (Idir et al., 2013), and can be more applicable to certain materials, such as aluminium alloys. However, the chemical reactions caused at the surface involve a much more complicated removal process compared with IBF using inert gases. Hence, a significant challenge for RIBE is the precise calibration and stability of the removal rate.

Bombardment of a mirror surface by high-energy ions can cause surface damage and pitting, which increases the micro-roughness and degrades the quality of the mirror (Makeev et al., 2002). Therefore, the beam energy must be carefully chosen to ensure gentle removal and minimize surface damage. The optimal energy depends on the species and mass of the ions used, as well as the material of the mirror being figured. For Ar ions, the typical beam energy for IBF is between 400 and 1000 eV, with a resulting removal rate of ∼1 nm s⁻¹ for Si mirrors.

The ion beam may be focused or collimated depending on the beam optics, with both having individual advantages and disadvantages. Focused ion beams allow for a higher current density, and therefore a higher removal rate. In comparison, a collimated ion beam typically produces a larger beam profile, which may be more appropriate for coarse correction, but with a lower peak current density. If an additional aperture is used to filter the beam, the resulting shape will vary from a Gaussian profile at large distances to a top-hat shape close to the aperture. The angle of incidence of the ion beam on the mirror must also be considered, particularly for strongly curved mirrors (Liao et al., 2014a,b). This can be controlled using a five- or six-axis motion system to ensure the beam incidence remains normal to the mirror throughout figuring. Alternatively, it can be post-compensated by considering a dynamic removal function at different points on the surface (Gu et al., 2023) (see Section 4.3 for further discussion).

3.2.2. Motion configuration

During IBF correction, one of either the mirror or the ion source may move, while the other component is fixed (Fig. 5). A third approach is to fix both the source and the mirror, and use a movable mask/aperture to control the removal (Peverini et al., 2010; Preda et al., 2013), but this technique has not been widely adopted.

Figure 5 Sketch of the two possible motion setups, where either the source (left) or the mirror (right) is mounted on a motion stage, and the other component is fixed in place during figuring.

Moving the ion source has the advantage of reducing the overall size of the IBF plant. In configurations where the mirror position is fixed, the vacuum chamber only needs to be as long as the size of the largest mirror to be figured; whereas, if the mirror moves, the vacuum chamber must be twice as long as the size of the largest mirror to accommodate its length as it moves from one side of the source to the other. The volume of the chamber has important implications for how long it takes to be pumped to vacuum, as well as practical considerations around the overall size of the IBF plant. On the other hand, fixing the ion source position and moving the sample allows for much more flexible use of on-board metrology during the process, as discussed in Section 3.2.3.

The required motion of the ion beam to correct a given surface is initially calculated as a dwell time map, consisting of short increments of time at discrete positions on the surface. However, trying to implement this in a literal way would require discontinuous motion with infinite velocity between the dwell positions. Instead, the position–time scheme is typically adapted to a position–velocity–time (PVT) scheme, allowing the velocity of the motor to be smoothly modulated (Wang et al., 2020a). Additional care may be needed to ensure the acceleration is also smooth, and that the maximum acceleration and velocity during motion do not exceed the limits of the motion stage (Wang et al., 2023c).

The number of axes of motion required depends on whether 1D or 2D figuring is being performed. 1D figuring involves only one axis of motion relative to the ion beam, and allows the correction of mirror surfaces over a narrow aperture of a few millimetres wide. This is suitable for figuring of grazing-incidence mirrors, such as Kirkpatrick–Baez (KB) focusing mirrors (Zhou et al., 2016a) using a very simple setup. Conversely, 2D figuring involves scanning the beam in two dimensions, enabling greatly improved flexibility but at the cost of increased complexity. 2D figuring plants require at least two axes of motion, and typically use between three and six axes (including manipulation of source-sample distance, and rotation of the sample with respect to the beam), as well as requiring significantly more complex calculations to implement (see Section 4.3 for more discussion).

3.2.3. On-board metrology

One novel advantage of IBF is its compatibility with on-board metrology, as demonstrated by the in-house IBF facility at the Diamond Light Source (Hand et al., 2019) (Fig. 6). Various optical measurement devices may be installed in an IBF plant, aiding in either sample targeting and alignment, or allowing measurement of the height or slope profile of the mirror under figuring. A straightforward example of a targeting aid is a camera, which may be used to find the position of the edges or fiducial marks on a mirror. Other options to measure the position and orientation of the mirror may include an on-board autocollimator for angular calibration. In the Diamond Light Source IBF, an autocollimator was used for calibration of the angular motion stage, and to characterize rotation errors caused by the translation stage during commissioning (Hand et al., 2019).

Figure 6 A photograph of the IBF plant at the Diamond Light Source, which is equipped with a fixed ion source, a CCD camera for mirror alignment and targeting, and a SAM instrument for measuring the curvature of the mirror. Figure reproduced with permission from Mahji et al. (2024).

For measurement of the height or slope profile of a mirror within the IBF chamber, a wide range of optical metrology instruments are suitable for on-board installation. For instance, the Diamond Light Source in-house IBF facility is equipped with a speckle angular measurement device (SAM), enabling measurement of the curvature of a mirror using stitching speckle deflectometry (Sutter et al., 2011; Wang et al., 2021a; Mahji et al., 2024). On-board measurements have the advantage of being carried out in vacuum, helping to reduce air fluctuations from pressure and temperature. They also allow rapid measurement of a mirror, compared with ex situ measurements (which require venting the IBF vacuum chamber to atmosphere, removing the sample to perform the measurements, and then subsequently pumping the chamber down to vacuum again, which is a highly time-consuming process).

Fundamentally, the precision of on-board metrology instruments is limited, due to environmental effects such as vibrations, and also clamping (see Section 4.2) and heating/cooling (see Section 4.1.4). To converge to the required sub-100 nrad accuracy, ex situ metrology must be used to give the required measurement precision. However, on-board metrology can be used for initial coarse corrections of a mirror, when the slope errors may be on the scale of hundreds of nanoradians or even several microradians. Additionally, it may be used to extract beam removal function (BRF) parameters and removal rate of the ion beam from an etched crater (see Section 4.1.2). Both of these applications can speed up the IBF process significantly, compared with relying exclusively on ex situ metrology.

4.1.1. Coordinate alignment and targeting

The IBF process relies on alignment between (at least) two coordinate systems: the IBF coordinate system, describing the position of the ion beam relative to the mirror; and the metrology coordinate system, containing the measured height or slope information about the mirror. Accurately correcting errors on a millimetre-scale spatial wavelength requires position and alignment tolerances of 100 µm or less, and any larger misalignment dramatically reduces the accuracy of the figuring process (Wang et al., 2023b).

A common approach to coordinate alignment is to use a `fiducial mark', typically a small cross, made on the surface of a mirror. Coordinate systems may then be aligned relative to the centre of this feature. For example, in an IBF setup equipped with an onboard camera, the camera can be used to find the sample position by locating the fiducial mark. An instrument that measures the height profile of the mirror, such as a stitching interferometer, will also be able to resolve the mark, allowing alignment between the two coordinate systems. For metrology instruments that measure slope or curvature, a suitable fiducial mark can instead be obtained by etching a crater or a furrow on the mirror using an ion beam. The measured location of these etched marks can be directly compared with the ion beam targeting coordinates, provided the mirror is returned to the exact same position in the IBF chamber after ex situ measurement (Zhou et al., 2016b; Hand et al., 2019). A combination of cross and crater fiducial marks may be used to allow comparison between various metrology instruments.

4.1.2. Accurate determination of beam removal function

To ensure a high accuracy of material removal during IBF, the removal rate and the shape and size of the ion beam should be determined to a high accuracy. This is usually done by etching a crater on a mirror, and then fitting the resulting measured height profile to a two-dimensional analytical function B(x, y), the BRF. As the removal process is generally highly linear, the material removal per unit time can be obtained by dividing the amplitude of the measured crater by the number of seconds it was etched for.

Fig. 7 shows a graphite aperture plate used to select a smaller region of the ion beam for etching, and the resulting BRF obtained for each aperture. For smaller apertures or when a focused source is used, the BRF will typically be Gaussian in shape; for larger apertures in front of a collimated source, the BRF will instead tend to take a `top-hat' shape described by a higher-order super-Gaussian function. The BRF will be influenced by the distance between the mirror surface and the ion source/aperture plate, and also by the angle of incidence [which is particularly relevant for curved mirrors (Liao et al., 2014a)]; the material and structural composition of the mirror; and the history of the mirror, due to oxide formation and depth, total removal depth, and other effects. Where possible, a BRF obtained from a crater etched directly on the mirror under figuring will give the most accurate determination of removal for that mirror surface. However, BRFs may be obtained by etching on `sacrificial' test mirrors with reasonable accuracy, especially for the initial stages of coarse figuring.

Figure 7 Left: an aperture plate used in the IBF plant at Diamond Light Source, with 1 mm, 5 mm and 10 mm diameter circular apertures that may be used to selectively mask the ion source during figuring. Right: the removal profiles obtained from each aperture, derived from fitting to measured data with either a Gaussian or super-Gaussian function.

4.1.3. Choosing optimal tool shape and size

Use of an aperture plate (Fig. 7) to selectively mask out part of the ion beam allows the beam size and shape used during figuring to be carefully controlled. Typical sizes range from 10 mm or more in diameter to as small as 0.5 mm for focused sources. The appropriate tool size and shape chosen depends on the nature of the errors which are to be corrected. In general, beam size represents a trade-off between reducing total dwell time (associated with larger beam sizes) and minimizing residuals (associated with smaller beam sizes) (Allen & Keim, 1989). Fig. 8 shows an example of the impact of beam size for correcting a measured mirror surface.

Figure 8 The impact of beam size for correction of an analytical input surface (top), comprising a low-frequency parabolic component with a period of ∼100 mm and a medium-frequency sinusoidal component with a period of ∼3 mm. The 10 mm and 5 mm beams are effective at correcting the low-frequency errors with a short total dwell time. However, they cannot correct the medium-frequency errors, which remain visible in the residual surface post-figuring. The 1 mm beam effectively corrects both the low-frequency and the medium-frequency errors, yielding a residual surface with greatly improved r.m.s. and PV errors. However, the required dwell time is much longer than for the larger beam sizes.

In approximate terms, a Gaussian beam with a diameter d can effectively correct errors with a spatial period ≥2d (Zhou et al., 2008; Arnold et al., 2010). When the beam size is too large to effectively correct the errors present on the surface, the overall residuals will be higher, and the convergence of the figuring will worsen. However, when the beam size is small compared with the low-frequency errors present on a surface, the dwell time needed for figuring may be increased to tens or even hundreds of hours. Such long dwell times are not generally feasible and will cause errors due to source instability, sample heating and expansion, etc., leading to poor convergence (Wang et al., 2022). As such, figuring is usually performed in multiple iterations, starting with coarse correction using a larger beam and progressing to finer corrections using smaller beams until the desired figure accuracy is achieved. This ensures the dwell time for each iteration is kept acceptably low, but at the cost of increasing total processing time, due to the need to measure the surface profile after each iteration.

4.1.4. Mirror heating and thermal expansion

One potential issue associated with long dwell times during figuring is heating of the mirror. The ion beam imparts heat to the mirror as it passes over the surface, and this heating is larger when a focused source is used, the source–sample distance is low, and there is poor thermal conductive contact between the mirror and the holder/chamber to allow cooling. Depending on conditions, the temperature of the mirror may increase by tens or even hundreds of degrees Celsius during figuring. A test performed at the IBF plant at Diamond Light Source showed that, during an hour-long correction using a 5 mm beam from a collimated ion source, the temperature of a Si mirror increased by over 80°C, before rapidly cooling after the figuring was completed and the ion source switched off (Fig. 9).

Figure 9 (a) Photograph of the Si mirror used for the temperature test. A temperature sensor was installed at the top of the mirror (labelled). (b) Graph of temperature over time when a raster path was etched on the sample with the ion beam, with a total etching time of 1 h and 5 min. The sample temperature increased dramatically during etching by over 80°C, followed by a rapid fall after etching completed.

This heating effect may cause significant expansion and/or change in curvature of the mirror under figuring. For example, given an increase of 100°C, a Si mirror 300 mm in length will expand by 78 µm, which is non-negligible considering the tolerances required for IBF. Depending on the clamping of the mirror, this thermal expansion may cause the curvature of the mirror to change, sometimes dramatically, which can also impact the figuring process. Additionally, other components in the chamber, such as the sample holder, may be made of materials such as Al or stainless steel with significantly higher thermal expansion coefficients. Expansion of these components due to high temperatures can cause further strain, deformation or potential misalignment of the mirror. Finally, high temperatures can also change the linearity of the sputtering process, reducing the accuracy of figuring.

For IBF, the heating of the mirror during figuring should therefore be minimized. This may involve reducing the total dwell time wherever possible; performing figuring in multiple short cycles and allowing the mirror to cool in between cycles (Wang et al., 2023a,b); or adjusting the design of the sample holder and mount to allow for improved passive cooling (e.g. using thermal braids).

4.2.1. High precision and repeatability requirements

Key to the ability of an IBF process to obtain sub-nanometre height errors and sub-100 nrad slope errors is a metrology system capable of accurately measuring such errors. For successful correction of figure errors, it is imperative to accurately measure the surface profile before and after figuring. The repeatability of metrology must be at least as good as the lowest errors sought, and preferably better. Much of the development of the IBF process has moved hand-in-hand with the development of metrology systems to reliably measure smaller features on optical surfaces with greater precision. As the tolerances and uncertainties of an IBF system must be minimized to produce mirrors with such low figure errors, so too must the metrology instruments be carefully calibrated and sources of random and systematic measurement errors be eliminated.

Each metrology instrument will typically measure either the height, slope or curvature of the test surface. Conversion between any such measurements can be achieved using numerical calculus. Algorithms should be chosen to ensure numerical errors are minimized compared with the measured data. However, care must be taken; integrating a slope measurement to obtain a height profile can significantly magnify any noise or errors, whereas differentiating a height measurement to obtain slope involves careful consideration of the window used to calculate slope and the filters (if any) applied to the data before calculation. In general, a thoughtful approach is needed when comparing measurements from different instruments.

X-ray mirrors typically involve an active area much longer than it is wide. As such, stitching methods are common when measuring the height or slope profile. This involves taking a large number of overlapping sub-aperture measurements of the surface, using a device such as an interferometer (Yamauchi et al., 2003), that are then combined or `stitched' to form a view of the entire surface. However, stitching sub-apertures is nontrivial, and solving the optimization problem to combine individual apertures takes a large amount of processing power.

Options for measuring the slope profile include instruments such as the long trace profiler (Rommeveaux et al., 2008; Takacs et al., 1987) and the nanometre optical component measuring machine (Siewert et al., 2008), both of which were designed to measure the tangential slope of glancing-angle mirrors like those often used in X-ray beamlines (with sagittal slope information obtained in only a narrow area). Both approaches yield 1D slope profiles, but 2D slope information may be obtained using a raster scan over the mirror surface.

In addition to the ex situ metrology described above, in situ at-wavelength metrology can also be used to assess the height and slope errors of an X-ray mirror. Such at-wavelength metrology is extremely powerful for assessing the performance of a mirror in its working conditions with high precision (Berujon et al., 2014; Wang et al., 2014, 2015b; Yamauchi et al., 2011), with sensitivity of a few nanoradians achievable (Wang et al., 2015a,b). An IBF plant installed on an X-ray beamline, such as that presented by Preda et al. (2013), could further integrate the process with in situ measurement and diagnostics. This would allow even more rapid convergence of the IBF process to highly accurate results.

As well as the millimetre-scale figure errors, it is also important to monitor the micrometre-scale features of a mirror. Excessive micro-roughness of mirror surfaces, generally >0.3 nm r.m.s. for X-ray mirrors, causes scattering and loss in intensity of the reflected X-ray beam. Therefore, it is essential to ensure that the micro-roughness of the mirrors is not increased during the figuring process. Techniques for characterizing micro-roughness include micro-interferometry; tactile stylus contact measurement; scanning probe techniques, such as atomic force microscopy (AFM); and X-ray reflectometry (XRR). Notably, techniques like micro-interferometry and AFM only measure a small region of the sample. Therefore, it is important to ensure that representative parts of the surface are chosen, and it is good practice to measure at several different positions.

4.2.2. Clamping stresses and sample position alignment

A key aspect of accurate metrology is minimizing the mechanical stress and gravitational `sag' deformation when a mirror is measured. Depending on the thickness of the mirror, deformation caused by improper clamping could be tens or even hundreds of nanometres, as demonstrated in Fig. 10. Therefore, wherever possible, a mirror should be measured under as little force as possible, and ideally free-standing. This allows the stresses on the mirror to be kept as consistent as possible during each measurement.

Figure 10 (a) A photograph of a trapezoidal mirror, clamped in preparation for figuring with IBF. (b) Height profile showing the deformation of the mirror in this clamping configuration, obtained as the difference between the measured height profile when clamped, and the measured height profile when free-standing. A large deformation is seen of more than 100 nm, which is most severe at the thinner end of the mirror, indicating the force applied by clamping significantly impacts the height profile of the mirror.

This requirement to minimize force on the mirror during metrology poses a challenge for the IBF process in terms of the sample positioning. Correction of a mirror often progresses over many iterations, and after each correction the mirror must be measured to assess the effect of the previous iteration and provide input for the next correction iteration. When using ex situ metrology, this means removing the mirror from the IBF plant for measurement, and then replacing it for the next correction. However, to ensure accurate targeting, the mirror must be reproducibly placed back into the IBF system, and any offset in position or rotation must be precisely measured and accounted for.

These two requirements pose conflicting demands on sample handling and mounting. For example, a solution for the IBF mounting is to load the mirror within a mount or holder that can be removed and replaced in the IBF chamber using mechanical stops. However, such an arrangement imposes clamping stresses on the mirror itself that can have an adverse effect on the metrology, particularly measurements of the slope (Siewert et al., 2012). Even if the mirror is held or clamped under the same conditions, the heating during ion beam figuring and subsequent cooling will cause the sample to expand in the mount, which may have a significant impact on the stress and deformation. This is also one drawback of on-board metrology; the stresses on the mirror in its mounting configuration within the IBF chamber cannot be mitigated, and must therefore be accounted for some other way (in data processing or by careful setup of the measurement), or otherwise considered in the fundamental uncertainties of the metrology.

As discussed, the ideal approach from a metrology perspective is to measure the mirror as close to free-standing as possible. In vertical configurations, where the mirror is lying flat with the active surface pointing upwards, the sag under gravity can be accounted for by modelling the weight and flexibility of the mirror, depending on its dimensions and material composition. However, care must be taken to ensure the mirror is replaced in the exact same configuration in the IBF chamber. This is another area where the use of fiducial marks and an on-board targeting system (such as a camera) can be extremely useful for accurate positioning.

4.2.3. Data processing and frequency filtering

Data processing is not a trivial task, and every transformation applied to data, no matter how small, will impact the results. As discussed, preprocessing steps such as stitching of interferometric measurements must be undertaken with care, and there are often parameters that must be set (such as the tolerance of each stitch, and the minimum overlap between sub-apertures) which affect the final output. When calculating slope data from height data, factors such as the region over which the slope is calculated, and the filter (if any) applied to the data before calculation, can have a significant impact on the final result. As discussed, it is vital to consider these factors when attempting to compare data from two different sources or instruments, where the spatial resolution and instrument transfer function (Groot, 2021) may differ.

A consideration for processing of IBF data is the filtering of noise and certain surface features. A common example is the spikes caused in interferometric measurements by dust particles on a mirror's surface (Fig. 11). These spikes can be removed by data processing, such as with a spike clip or a slope/height filter. However, this process may risk removal of other, `real' surface features, if the filtering is poorly applied. Another example is the removal of high-frequency features on a mirror surface. As described, the IBF process can only effectively correct errors with the same spatial period as the beam size used. For coarse corrections, it may be more efficient to remove the higher-frequency features that cannot effectively be removed with a given beam size, as this enables more efficient figuring with a lower dwell time and minimal unnecessary removal (Guan et al., 2022). But this similarly runs the risk of filtering out `real' surface features, if the filtering is not performed in an intelligent or appropriate way.

Figure 11 Example of data processing to remove noise, such as spikes caused by particles of dust. Left: measured 3D height profile of a sample, which shows several spikes caused by dust particles or other contaminants. Right: the same surface after applying a slope filter with a threshold of 11 µrad to remove the spikes from the surface.

Ultimately, the result of a measurement is a result of the conditions under which it was taken and the steps that were carried out during processing. It is important that any transformation steps applied are not only well posed but carefully documented and presented alongside the data, to ensure proper comparison and interpretations of the results.

4.3.1. Choice of algorithms to calculate dwell time

The principle of deterministic figuring is that, given a removal function B(x, y) and a tool dwell time distribution t(x, y), the resulting removal Z is obtained through a convolution

Therefore, when Z is the measured height error of a surface that is to be corrected, and B(x, y) is known from characterization of the BRF, the required t(x, y) to correct the height errors can be obtained via inverting the equation and solving the resulting deconvolution between Z and B.

In practice, solving this deconvolution is non-trivial. Generally, an algorithm is used to optimize the approach and, if necessary, set additional parameters. Most algorithms use either a matrix-based approach, utilizing least-squares minimization to solve the deconvolution (Paige & Saunders, 1982; Carnal et al., 1992; Wang et al., 2019), or an inverse Fourier transform method (Wilson & McNeil, 1987). Matrix-based algorithms offer improved flexibility, such as the option to consider arbitrary dwell points (Wang et al., 2021c), which can be used to minimize tool marks from the IBF process; implementation of dynamic or spatially varying beam effects (Liao et al., 2014a,b); or simultaneous consideration of multiple figuring tools at once during calculation (such as different sizes of ion beam) (Ke et al., 2022). However, they are generally computationally expensive, requiring longer calculation times than Fourier transform-based methods. As such, matrix-based methods are generally favoured for 1D figuring (Wang et al., 2019; Mahji et al., 2024). In comparison, Fourier transform-based methods, such as the recently developed RIFTA (Wang et al., 2020b, 2023b), are computationally efficient and able to find effective dwell time solutions in very short calculation times. However, they are generally less flexible than matrix-based methods.

When solving a dwell time deconvolution, the measured data over the clear aperture (CA) (i.e. working area of the mirror) should be extended by at least the radius of the tool size to ensure that the CA is worked evenly during figuring. This extended area, known as the dwell grid (DG), may be populated with data generated by various surface extension methods, such as Gaussian, nearest-neighbour or smooth triangular interpolations (Yang et al., 2017), or by a polynomial fitting to the measured data that is then extended over the DG (Wang et al., 2021b). Continuity at the edge of the CA is important to minimize residuals; however, the height of the extrapolated profile outside of the CA should be made low to reduce the total dwell time. Therefore, the optimal surface extension for a given CA typically depends on the nature of the measured surface, the prominence of high- and low-frequency features, and the behaviour of the surface at the boundaries of the CA.

4.3.2. Convergence of both height and slope error

Most figuring methods consider the height error of the mirror under correction. However, slope error is an equally important metric to consider, especially for many X-ray mirrors. Although improving height error will generally also improve slope error, an optimized height profile may yield a sub-optimal slope profile. Given the extremely low slope errors required for X-ray mirrors, it can be challenging to converge to these errors by considering height error alone.

An alternating height/slope optimization method has been shown to efficiently reduce both height and slope errors over 2D surfaces (Wang et al., 2023a). This method works by iteratively optimizing first the height error, then the slope error in x and y, until a solution is found that minimizes both the height and slope errors to the desired accuracy. The 2D slope errors in x and y of the surface can be obtained from the height profile by simple calculus. Likewise, for a BRF represented by a Gaussian or super-Gaussian function in terms of height removal, the x and y slope removal profile can be obtained by differentiation. This method was found to be highly effective in correction of slope errors. Using this approach, an elliptical mirror was figured with 0.36 nm r.m.s. height error and 150 nrad slope error over a 150 mm × 20 mm CA (Wang et al., 2023b).