3.1.

Sample Preparation

This paper consists of two studies: the surface roughness and the nonuniformity. The thin films presented were produced at the DC magnetron sputtering facility at DTU Space.²⁰ We deposited the thin films onto double-side polished Si substrates, referred to as witness samples, with a crystal orientation (100) and dimensions of $70\mathrm{mm}\times 10\mathrm{m}\times 0.775\mathrm{mm}$ ($L\times W\times H$). Three samples were used to evaluate the Pt surface roughness when introducing Cr as an adhesive layer: one Pt single layer and two Cr/Pt bilayers, as listed in Table 1. Due to the parabolic mirror’s large size and the sample size limitation on our x-ray reflectometry equipment, it was not possible to measure the thin film coating nonuniformity on the parabolic mirror. A reference coating was therefore performed after the mirror coating with the same deposition parameters, which included 5 witness samples divided across 456 mm, as listed in Table 1. All witness sample substrates were plasma cleaned prior to the thin film deposition, with a power of 100 W for 40 min in an oxygen (${\mathrm{O}}_2$)/nitrogen (${\mathrm{N}}_2$) atmosphere using a Tepla Plasma Asher. The parabolic mirror was polished at INAF-OAB⁹ before arrival at DTU Space, and a visual inspection showed no defects or surface particles. Before the parabolic mirrors thin film deposition, the surface was cleaned using a ${\mathrm{N}}_2$ gun to remove dust and other particulates from the substrate surface.

Table 1

Samples and associated coating designs in each study.The expected thicknesses in the nonuniformity study were calculated using Eq. (4).

During the thin film deposition, we applied a power density of $1.55\mathrm{W}/{\mathrm{cm}}^2$ to the Pt target and $2.33\mathrm{W}/{\mathrm{cm}}^2$ to the Cr target. We preconditioned the Pt and Cr targets for 5 min to remove impurities from the target surface and performed all coatings in an argon atmosphere with a pressure of 3.0 mTorr. The BEaTriX parabolic mirror is placed in the center of a custom-built mirror mounting plate, shown in Fig. 10, and the 5 reference samples’ relative locations across the 456 mm are illustrated in Fig. 5. The aimed thicknesses of each sample is listed in Table 1. The reference samples were mounted on a 50-mm-tall plate to achieve the same TSD as for the parabolic mirror and rotated around the magnetron during the coating process using calibrated ring rotation speeds. The parabolic mirror was coated with a center TSD of 94 mm and mirror edge TSD of 159 mm, using a collimating honeycomb mesh¹⁵ in front of the target.

Fig. 5

Reference sample location, samples ds0077 to ds0081.

3.2.

X-ray Reflectometry Characterization

X-ray reflectometry measurements at 1.487 keV were performed with the low-energy x-ray reflectometer (LEXR²¹) at DTU Space and 8.048 keV measurements using the Rigaku SmartLab X-Ray Diffractometer at DTU Nanolab. Energy scans were measured at the four-crystal monochromator beamline of the Physikalisch-Technische Bundesanstalt laboratory at the BESSY II synchrotron radiation facility,²² though these results will be shown in later work.

Specular ($\theta -2\theta$) and nonspecular ($\theta$) measurements were conducted using the 1.487 keV reflectometer. For both measurements, the reflectometer was operated with a $0.5\times 1.0{\mathrm{mm}}^2$ ($W\times H$) beam shaping slit. The sample to source distance was 1485 mm, and the sample to detector distance was 504 mm. For the specular measurements, a $4.0\times 5.0{\mathrm{mm}}^2$ ($W\times H$) slit was used to filter out undesired scattering before the resulting beam intensity was recorded. For the nonspecular measurements, the detector stage was fixed at $2\theta$ while scanning the sample in the interval $\theta =[\mathrm{0,2}\theta ]$ with a $1.0\times 5.0{\mathrm{mm}}^2$ ($W\times H$) detector slit. The 8.048 keV reflectometer at DTU Nanolab has a sample to detector distance of 351.4 mm and uses a $0.12\times 2.0{\mathrm{mm}}^2$ ($W\times H$) detector slit to shape the beam reaching the sample, and the width of the slit after sample reflection was 1.87 mm. The measured reflectometry data were fitted using a Python-based software that utilizes the Fresnel equations in combination with a differential evolution algorithm, as described in Gellert et al.²³ The optical constants for each material is computed using the atomic scattering factors from the Center for X-Ray Optics.²⁴ An angular instrumental resolution of 0.007 deg is specified for the 8.048 and 1.487 keV system. All model structures were composed of a Si substrate with a native ${\mathrm{SiO}}_2$ surface. The ${\mathrm{SiO}}_2$ thickness was fixed at 2.0 nm (the typical value for native grown oxide²⁰), and the roughness was coupled to that of the Si substrate. For the 1.487 keV models, we introduced an overlayer of hydrocarbons ($\mathrm{C}─\mathrm{H}─\mathrm{O}$) with a density fixed to $1.0\mathrm{g}/{\mathrm{cm}}^3$, which accounts for any $\mathrm{C}─\mathrm{H}─\mathrm{O}$ compound and other surface contaminants visible at 1.487 keV, as presented by Massahi et al.²⁵ The roughness of the $\mathrm{C}─\mathrm{H}─\mathrm{O}$ overlayer is coupled to the underlying Pt roughness because this parameter cannot be constrained from the fit.

4.1.

Surface Roughness

We show the effect of using Cr as an intermediate layer by conducting specular and nonspecular x-ray reflectometry measurements using the 1.487 keV reflectometer (LEXR) at DTU Space on the three samples listed in Table 1. We performed nonspecular measurements at 0.3 deg, 0.9 deg, and 2.5 deg. The nonspecular scan at 0.3 deg is compared with the technical report from INAF-OAB,²⁶ 0.9 deg due to being the facility’s operating angle, and 2.5 deg due to being near the critical angle for Pt at 1.487 keV. All measurements are included in Fig. 6.

Fig. 6

Measured 1.487 keV specular and nonspecular reflectivity at 0.3 deg, 0.9 deg, and 2.5 deg of samples ds0008, ds0021, and ds0027.

The 1.487 keV specular measurements including their best-fit models are shown in Fig. 7, and the best-fit parameters are given in Table 2. The widths of the fringes are well modeled, which is related to a good thickness estimate. We observe a very low residual, with the largest deviations being observed in the peaks and valleys of the Kiessig fringes, which may be due to a substrate waviness or a small film nonuniformity along the measurement direction.²⁵ The Cr layers’ effect on the reflection process is observable near 9 deg. The 1.487 keV specular reflectivity measurements in Fig. 6 indicate that a thin intermediate layer of Cr does not affect the Pt surface roughness because the slope of the reflectance after the critical angle is similar for the three samples.

Fig. 7

1.487 keV specular reflectivity measurements of samples (a) ds0008, (b) ds0021, and (c) ds0027, including the best-fit model. Table 2 includes the fitted model parameters.

Table 2

Fitted model parameters of the 1.487 keV specular reflectivity measurements of samples ds0008, ds0021, and ds0027. Figure 8 includes the measured data and fitted model.

The best-fit parameters in Table 2 show that the Cr roughness is a factor of 2 higher compared with the Pt surface roughness, due to the grainy growth of the Cr thin film during deposition.¹⁹ The surface roughness of the Pt film increased slightly (6.9%) when deposited on top of Cr due to the high Cr roughness. This trend is also reported by Massahi et al.¹⁹ in a Cr/Ir bilayer structure, in which the Ir surface roughness increases with increasing the Cr thickness. The fitted model parameters show that the Pt thicknesses are within 8% of their aimed values, which is acceptable and under our estimated 10% DC magnetron thickness accuracy. We obtained an average Pt density that is 94% of bulk density²⁷ ($21.5\mathrm{g}/{\mathrm{cm}}^3$). The modeled Cr densities were 6.88 and $7.19\mathrm{g}/{\mathrm{cm}}^3$ corresponding to 96% and 100% of the bulk density²⁷ ($7.19\mathrm{g}/{\mathrm{cm}}^3$), respectively. Different models were tested, which account for misalignment, but it did not improve the fitted model. The average best-fit thickness of the C–H–O overlayers derived from the 1.487 keV x-ray reflectivity (XRR) data was 1.6 nm, which is in agreement with the range of values reported by Massahi et al.¹⁹

The normalized nonspecular measurements at 0.3 deg, 0.9 deg, and 2.5 deg are included individually in Fig. 8. The measurement at 0.3 deg agrees with the results from the INAF-OAB technical report,²⁶ which show that a thin intermediate layer of Cr decreases the nonspecular reflectance. The measurements at 0.9 deg and 2.5 deg also agree with this trend, showing that the Pt single layer exhibits a higher level of nonspecular scatter than the bilayers, which suggests higher roughness due to the poor adhesion of the Pt and consequent delamination. Note that the measurements are known as rocking curve or $\omega$ scans, with the detector stage being fixed at $2\theta$ while scanning the sample in the interval $\theta =[\mathrm{0,2}\theta ]$. This explains the asymmetrical spectrum as each angle represents a different beam illumination area of the sample.

Fig. 8

Normalized 1.487 keV nonspecular reflectivity measurements at (a) 0.3 deg, (b) 0.9 deg, and (c) 2.5 deg of samples ds0008, ds0021, and ds0027.

We performed a rudimentary tape test with transparent 3M Scotch tape to evaluate the adhesion on the witness samples. A piece of Scotch tape was firmly attached onto the surface of the coating for each sample and subsequently pulled off the surface. Then, a visual inspection of the surfaces was performed, and the Cr/Pt bilayer films showed no visible residual on the tape and proved to withstand the removal of the tape. As can be seen in Fig. 9, the Pt single layer displays a visible residual from delamination.

Fig. 9

Tape test on Pt single layer, sample ds0008.

We can conclude that the surface roughness of the Pt film increased slightly when deposited on top of Cr due to the high Cr roughness. This slight roughness increase is however negligible in relation to how the thin intermediate Cr layer greatly improves the adhesion of Pt thin films. The reflectivity and smoothness of the Pt surface is not damaged by a thin Cr interface and, in fact, improves the nonspecular reflectance and effectively prevents delamination. These results favor the Cr/Pt bilayer mirror coating design.

4.2.

Nonuniformity

Based on the previous results in Sec. 4.1, a center mirror coating consisting of 4 to 5 nm Cr + 30 nm Pt is chosen for the parabolic mirror. Due to the geometric structure and current equipment drive systems of the DC magnetron coating facility, it is currently not possible to deposit a thin film with a uniform coating thickness across the beam direction of the mirror substrate. We however showed in Sec. 2 that a 20% to 60% thickness reduction across the parabolic mirror did not affect the BEaTriX beam’s efficiency, though the system performance was affected by the amount of scatter due to the roughness nonuniformity introduced by the varying TSD and incidence angle of the sputtered material. Therefore, as part of the thin film coating development for the 456-mm-long parabolic mirror, we evaluated the thickness and roughness nonuniformity along the length of the mirror. Figure 10 shows the parabolic mirror mounted in the chamber after coating. Due to the parabolic mirror’s length and the sample size limitation on the available reflectometry equipment, it was not possible to measure the coated parabolic mirror. A reference coating was therefore performed after the parabolic mirror coating with the same deposition parameters, which included 5 witness samples divided across 456 mm, as illustrated in Fig. 5.

Fig. 10

Parabolic mirror mounted in the DC magnetron coating chamber after coating.

The 5 reference samples were measured by the 8.048 keV reflectometer at DTU Space, and the specular reflectivity measurements of samples ds0077 to ds0081, including their best-fit models, are shown in Fig. 11. It is observed that the specular reflectivity of samples ds0077 and ds0078 includes smeared features, indicating a larger roughness than the other samples. The data were analyzed and modeled as described in Sec. 3.2. Unlike the 1.487 keV XRR measurements, we did not fit the Cr and Pt densities to model the 8.048 keV XRR data obtained from the Cr/Pt bilayers. After preliminary attempts to model the Cr and Pt densities, these parameters could not be constrained, indicating an alteration in the samples model structures. We therefore used a Cr density of $7.19\mathrm{g}/{\mathrm{cm}}^3$ and a Pt density^19,27 of $21.5\mathrm{g}/{\mathrm{cm}}^3$. The best-fit parameters are shown in Table 3. The fitted model parameters show that the center sample ds0079 has a Pt thickness of 30 nm and the Cr thickness is 4.1 nm.

Fig. 11

(a)–(e) 8.048 keV specular reflectivity measurements of the BEaTriX reference coating samples, ds0077 to ds0081, including the best-fit model. Table 3 includes the fitted model parameters.

Table 3

Fitted model parameters of the 8.048 keV specular reflectivity measurements of the BEaTriX reference coating samples. Figure 11 includes the measured data and fitted model. The sample positions are illustrated in Fig. 5.

A uniformity map of the best-fit Cr and Pt thicknesses is shown in Fig. 12. The fitted Pt thickness shows a close to symmetric nonuniformity, in which the thickness decreases $\sim 9\%$ from the center to the midway and $\sim 28\%$ at the very edge of the mirror. The Cr thickness nonuniformity is not as symmetric, compared with the Pt thickness. The Cr thickness decreases between $\sim 5\%$ and 12% to the edge of the mirror. This nonsymmetric variation can be due the difficulty of sputtering and fitting $\mathrm{Cr}<5\mathrm{nm}$ in a bilayer structure or may be attributed to the presputtering. Samples ds0077 and ds0078 may have been affected by the angular spread of particles from the Pt target during presputtering, despite not directly facing it. Samples ds0081 and ds0082 may correspondingly have been affected by the presputtering of the Cr target. This may explain the skewed Pt and Cr thickness nonuniformity of all samples and likely may be the reason for the unconstrained densities in the preliminary models. The coating contamination due to the large spread of particles from the magnetron has since been evaluated and confirmed, and new collimators are being designed for future use.

Fig. 12

The BEaTriX reference coating samples fitted coating (a) thickness and (b) roughness deviation relative to the center sample ds0079. The fitted model parameters are shown in Table 3.

The measured Pt and Cr thicknesses are not consistent with the expected thicknesses when assuming that the deposition rate reduction follows a simple inverse square law dependency described by Eq. (4). This underestimation by a factor of two of the expected thickness as a function of rotation is due to the assumption of the target being 1D, and Eq. (4) does not account for the angular particle distribution.

The fitted roughnesses are included in Fig. 12. The roughness is expected to increase toward the edges due to the increased TSD and increasing angle of incidence of the sputtered particles onto the substrate. The fitted Pt roughnesses indicate a smooth surface uniformity of $\sim 0.47\mathrm{nm}$. The fitted Cr and substrate roughnesses support the notion that the observed results are due to the presputtering. The smeared features and high roughness of samples ds0077 and ds0078 can be explained by a thin Pt layer applied to the substrate during presputtering, causing a higher roughness due to the poor adhesion of the Pt. Disregarding samples ds0077 and ds0078, the fitted model parameters indicate a trend of increasing roughness toward the edge of the mirror, which is attributed to the increased TSD and the increasing angle of incidence of the sputtered particles. Vecchi et al.⁹ reported that the parabolic mirror surface roughness slightly decreased after coating and that there is no indication of performance degradation due to the deposited coating as measured at 1.487 or 4.511 keV.