Abstract
1 Introduction
Polarization is one of the fundamental characteristics of electromagnetic radiation[1]. Polarimetry, the quantitative determination of the polarization state, is a multifunctional and sensitive method to study light–matter interaction. In general, a polarimeter consists of two polarizers – called polarizer and analyzer – and their linear polarization transmission directions have an angle to each other, usually using orthogonal polarization settings (refer to Figure 1): a beam from the light source becomes linearly polarized by the polarizer. The linearly polarized light undergoes a change in polarization as it passes through the anisotropic sample. Only the beam component whose polarization meets the transmission direction of the analyzer can finally pass through the analyzer and can be detected by the detector. The physical properties of the sample can be obtained by detecting the change in polarization of the beam before and after it passes through the sample.
Figure 1.Basic scheme of polarimetry. Essential is the pair of polarizers with different and variable orientations to each other to study the effect of a sample in between on the polarization.
Polarimetry with high resolution, which breaks the limitations of low spatial resolution inherent in traditional measurement methods, is an emerging detection tool for atmospheric remote sensing, astronomy, biomedical diagnostics and much more[2,3]. For instance, by combining it with multi-spectral and multi-angle functionality, polarimetry allows for the analysis of an aerosol’s microphysical properties and chemical composition in atmospheric remote sensing[4,5]. In biomedical diagnostics, the degree of polarization depends on the properties of the biological tissues. Polarimetry is a diagnostic for tissue properties and provides a useful method for early cancer detection[6].
At the beginning of the 20th century, Barkla[7–9] pointed out that X-rays are polarized. X-ray polarimetry has been developed gradually in many research fields because of the short wavelength and great penetration of X-rays[10,11]. For the detection of magnetic fields, polarized X-rays have the appropriate ability to explore the features of magnetic structures in structural magnetism and the X-ray polarization can discriminate chiral from helimagnetic structures[12–15]. In the measurement of X-ray optical activity, Siddons et al.[16] successfully observed the optical activity and obtained 2 mrad rotations in a chiral organometallic compound.
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Moreover, polarimetry with high sensitivity can be applied to explore the nonlinear properties of a vacuum. In the quantum electrodynamics (QED) description of vacuum[17], virtual particle–antiparticle pairs, called quantum fluctuations, are allowed for ultra-short times. In strong external electric or magnetic fields, these virtual particle pairs can be partially aligned, resulting in an optical property of the vacuum.
In essence, fields
More attractive to scientists is the case of controllable fields, that is, laboratory vacuum and laboratory fields. The reason for the interest is the dependence on
Considering two different origins of the fields, a strong background field and a weak probing field, the right-hand part of Equation (1) describes a correction
Hence, the difference of the phase velocities yields a birefringence of the vacuum[17–19,29–36], whereas the difference from
So far, vacuum birefringence laboratory experiments have employed linearly polarized optical laser beams in magnetic fields and are reported for PVLAS[40,41], BMV[42] and Q&A [43,44]. Ejlli et al.[41] concluded that the final limits on vacuum magnetic birefringence
The major challenge of vacuum birefringence experiments is the extremely small effect, where two laboratory quantities may leverage (i) the provision of sufficiently strong external fields by intense radiation and (ii) using a shorter probe wavelength. The former argument is pretty clear when considering Equation (4) and
For the above-mentioned studies, the effective path is generated by a Fabry–Pérot setup in meter-long magnetic fields, providing
This stimulated scientists to improve the performance of X-ray polarimetry. Here, we review the related studies. In this paper, the contents are as follows. We introduce X-ray polarimetry in Section 2. First of all, we discuss the polarization purity of X-rays and the influencing factors and limitations in Section 2.1, followed by details for a high-quality X-ray polarizer in Section 2.2. In Section 3, we present the details of detecting vacuum birefringence, including experimental setups (Section 3.2) and general signal estimates (Section 3.3). We further discuss available facilities (Section 3.4) and related instrumentation (Section 3.4.4). Section 4 provides a brief description of the applications of X-ray polarimetry to nuclear resonant scattering, strong-field physics and astrophysics.
Figure 2.Basic diffraction geometry for anomalous transmission of X-rays (Borrmann effect). Reprinted from Ref. [45], with the permission of AIP Publishing.
2 X-ray polarimetry
The basic schematic shown in Figure 1 can be transferred to the X-ray domain, such that polarizing elements are required for the roles of polarizer and analyzer. Here we discuss the crucial components and potential accuracy of X-ray polarimetry. First, we would like to introduce two methods to obtain polarized X-rays.
The Borrmann effect, or anomalous transmission, was discovered by Borrmann[46] in 1941. Polarized X-rays are produced when X-rays pass through crystals because of the different absorbance of two orthogonal polarization planes[45,47]. The polarization state with the electric vector in the plane of incidence is preferentially absorbed, in comparison to the polarization state with the electric vector perpendicular to the plane of incidence. Here, polarizers based on the Borrmann effect are applied to the investigation of the electric-magnetic properties of ferroelectric materials and optical properties in chiral compounds[16,48]. The drawbacks of this polarizer are the low efficiency and a narrow angular acceptance[49]. In 1961, Cole et al.[45] constructed a polarizer-monochromator, where the polarizer is made from a single germanium crystal slab with 1 mm thickness, and the diffracted beam based on the Borrmann effect is polarized, as shown in Figure 2. The best intensity ratio of the two orthogonal polarization states based on the Borrmann effect is less than
Alternatively, polarized X-rays can be produced on perfect crystals with the Bragg diffraction at nearly 45° and thereby exploiting Brewster’s law[10,50]. As shown in Figure 3, the Bragg diffraction happens near the crystal surface for low absorption. The polarization component parallel to the plane of diffraction (
Figure 3.Geometry of the Bragg diffraction at 45°. Unpolarized radiation is polarized because the -component, being in the plane of incidence, is not allowed for reflection (Brewster’s law). Used with the permission of SPIE, from Ref. [50]; permission conveyed through Copyright Clearance Center, Inc.
2.1 Polarization purity
Here we discuss the generation of pure linear polarization states of X-rays based on Bragg diffraction at perfect crystals[51–54]. The polarization purity
Obviously
The intensity ratio of the polarization components
In the following, we discuss the requirements and limitations of extremely high purities
2.1.1 Beam divergence
As very simple geometric effect, a beam divergence leads to a deviation from a Bragg angle of exactly 45° for some parts of a beam, impinging on a perfect crystal, and thus a minor contribution in the
In 2020, Bernhardt et al.[55] experimentally verified Schulze’s[52] theoretical analysis by studying the effect of beam horizontal divergence on X-ray polarization purity at beamline ID18 of the European Synchrotron Radiation Facility (ESRF). The comparison of the X-ray polarization purity between the fitted data (
17 μrad | ||
14 μrad | ||
8.4 μrad |
Table 1. Comparison of measured purity against the calculated limit given by the beam divergence for . Taken from Ref. [55], licensed under CC BY 4.0.
2.1.2 Crystal quality
Crystal quality affects the polarization purity in two ways. First, for similar geometric reasons to the divergence, all parts of a (perfectly parallel) beam of finite size must experience the same 45° incidence angle to allow for the same polarization suppression[54]. Second, imperfect crystals have varying lattice constants that affect the reflectivity curves and thus the spectral/angular acceptance and integrated reflectivity. Thus, the properties of the crystal material must be taken into account to avoid the depolarization of X-rays.
Researchers[53,55] have used artificial diamonds containing a mass of crystalline defects produced by chemical vapor deposition (CVD) as a polarizer in X-ray polarimetry. Contrary to expectations and the prediction of Hart and Rodrigues[54], imperfections of artificial diamonds have no observable influence on the polarization purity of X-rays but lead to low peak reflectivity and low transmittance of polarizers[55]. Furthermore, polarimetry at photon energies above 10 keV can benefit from imperfections because of the higher integrated reflectivity. For low photon energies, the nearly perfect crystals with high reflectivity are essential for the expected highly linearly polarized X-rays[55].
2.1.3 Detour reflections (Umweganregungen)
Another limitation of the polarization purity is detour reflections (Umweganregung)[57]. These are the result of consecutive Bragg diffractions on different lattice planes and therefore different Bragg angles, yielding in sequence the same beam reflection angle as the primary reflection. This is similar to a cat’s-eye retro-reflector, where the rays bounce off several surfaces, in contrast to a mirror where only one reflection occurs. In fact, the detours are only possible in 3D crystals due to the abundance of lattice planes in directions off the main reflection.
As a result, every partial Bragg diffraction does not happen with a 45° Bragg angle such that the Brewster condition is not fulfilled, and no strong ratios of
The Ewald sphere is a geometric construction to determine the diffraction direction of crystals, and diffraction will occur only for reciprocal lattice points that lie on the surface of the Ewald sphere. The consecutive reflections case happens at nearby lattice planes in 3D crystals if there are more than two reciprocal lattice points that lie on the Ewald sphere. Under some azimuth angles, the incident beam excites not only the required intended reflection with a 45° Bragg angle but also secondary reflections – not with a 45° Bragg angle. As a result, the latter reflections will cause the depolarization of X-rays when the secondary, detoured reflections exit into the same exit direction of the principal reflection[51,53,57], and the polarization purity is suppressed. Marx et al.[51] provided the reflection system for a silicon crystal and an X-ray energy of 12.914 keV, as shown in Figure 4. The radius of the Ewald sphere is
Figure 4.Kossel pattern of silicon at 12.914 keV. The bold black circle represents the exploited Si (800) reflection used for suppression of the component. All other possible reflections are depicted by thin colored circles. The vectors and describe the direction of the incident and diffracted wave, respectively. In order to avoid degradation of the polarization purity due to multiple-beam cases, the azimuth has to be chosen such that the ‘distance’ to the closest undesired reflections is as large as possible. Reprinted from Ref. [51], with the permission of APS.
2.1.4 Material dependence
It is obvious from the previous sections that the material has a strong influence, mainly to provide crystals of the highest quality (cf. Section 2.1.2). At present, Si (
For silicon and diamond, Bernhardt et al.[53] compared the reflectivity of those two materials for the Bragg reflection at a 45° angle, as illustrated in Figure 5. The solid line and dashed line are the reflectivity curves of diamond and silicon, respectively. The curve for diamond is higher but narrower than that for silicon. This is a quite general behavior[62] and the reason lies mainly in the number of electrons per atom,
Figure 5.Reflectivity of X-rays for the –polarization in 45° symmetric Bragg scattering geometry as a function of the angle of incidence, according to dynamical theory calculations. Solid line: the (400) Bragg reflection in diamond for 9.831 keV. Dashed line: the (400) Bragg reflection in silicon for 6.457 keV, as used by Marx
For applications, however, the integrated reflectivity can be of interest, for example, if the beam has a finite spectral bandwidth or divergence. The integrated reflectivity of diamond is much smaller than that of silicon. For example, a later work by Bernhardt et al.[55] used diamonds with many crystalline defects and showed a peak reflectivity of only 50%–60%, while the rocking curve broadened by a factor of approximately 2.
There is also a material dependence of detour reflections. Tischler and Batterman[63] provided that the resulting contribution of all reflections is dependent on the amplitude for each detour:
Figure 6.Schematic of a channel-cut polarizer with reflections. Thin lines indicate the lattice planes for the 45° Bragg reflection, which are parallel to the surface in this case.
Consequently, polarizers made by materials with low Z values are favorable to further mitigate the impact of detour reflections, apart from choosing a good azimuth angle.
2.2 Channel-cut precision X-ray polarizers
The significant optical element in X-ray polarimetry for high polarization purity is the polarizer. In 1978 and 1979, respectively, Hart[11] and Hart and Rodrigues[54] established X-ray polarimetry with two-fold Bragg-reflecting channel-cut germanium (Ge) crystals and pointed out that polarization with multiple Bragg reflections has been demonstrated for any X-ray wavelength by using offset grooved crystals. Figure 6 displays a channel-cut polarizer with four reflections at a 45° Bragg angle.
As can be seen in Figure 6, the polarizer consists of two opposing Bragg crystals for a 45° Bragg angle. For simplicity and convenience, the two surfaces are made from a single crystal with a groove or channel cut into it. Thereby, the two surfaces have naturally parallel lattice planes. With appropriate geometry, an even number of reflections can be obtained, maintaining the beam direction while improving the purity (see Section 2.2.1 below). The resulting parallel offset of the beam is a minor problem. The main advantage is the inherent parallelism of both (opposing) lattice planes, such that the Bragg angle is to be aligned only once for all occurring reflections.
Figure 7.Polarization ratios for
One method to machine grooves is lapping by low-damage blades of a crystal saw. Alternatively, etching technologies are also excellent to create near-perfect inner channel surfaces to avoid distortions of the X-ray wavefront[58,59]. Channel-cut crystals have been extensively used[51–54,64]. As early as 1965, Bonse and Hart[64] pointed out that the pairs of perfect crystals with a groove cut (Figure 6) obviously reduced the tails caused by the multiple reflections. In 1978, Hart[11] constructed an X-ray polarimeter with two-fold Bragg-reflecting channel-cut germanium crystals to generate elliptically polarized X-rays. Hart used a mixture of nitric acid and hydrofluoric acid to polish the channel-cut crystals and eliminate the strains introduced in the cutting process. For channel-cut crystals designs, Marx-Glowna et al.[60] pointed out that the calculation of the beam path of Compton scattered photons and the orientation of the crystal should be considered, which affect the polarization purity of X-rays.
2.2.1 Consecutive reflections
It is well known that a polarized light beam can be produced by several transmissions through a number of glass plates, even though each plate is only a partial polarizer. Similarly, channel-cut crystals improve the polarization purity[54,65] since they stack a number of reflections into a single optical element.
Regarding multiple successive Bragg reflections between the walls of a channel cut in an ideal crystal to increase the polarization purity of X-rays, the ratio of intensities of two polarization states for X-rays polarized by
Recently, high polarization purity of X-rays was achieved by multiple reflections. In 2011, Marx et al.[58] reported that the highest purity of polarization of X-rays reaches
2.2.2 Asymmetric cuts
The channel-cut crystals enhance the polarization purity of X-rays. However, the angular and spectral acceptance of channel-cut crystals tends to restrict the throughput of X-rays. To increase the acceptance of channel-cut crystals while maintaining the polarization filtering, researchers[66–68] came up with asymmetrically cut crystals with an asymmetry angle
Figure 8.The geometry for an asymmetrically cut channel-cut crystal with a Bragg angle near 45°. The lattice planes, as indicated in Figure 6, are oriented 45° to the beam, yet the crystal surface is slanted. The asymmetry angle is the angle between surface and lattice planes. It is negative for the case shown at the first surface where the incident beam is shallow and leaves with a larger diameter.
The angular acceptance of the crystal varies with the asymmetry angle as follows:
Figure 9.The effect of an asymmetric cutting angle on both the angular acceptance and the resulting polarization suppression for a silicon (840) channel-cut crystal. Reprinted from Ref. [67], with the permission of AIP Publishing.
Figure 9 displays the effects of the asymmetry angle on angular acceptance and polarization suppression[67]. The angular acceptance increases while the polarization suppression factor decreases when the asymmetry angle approaches 45°. However, a larger asymmetry angle requires larger crystals due to the beam footprint, imposing practical issues.
An overview of the calculated polarization purities of X-rays for different asymmetry angles
0 | 1 | 1.9 | 2.5 | 0.95 | |
0 | 2 | 1.9 | 2.5 | 0.90 | |
0 | 4 | 1.9 | 2.5 | 0.81 | |
–28 | 1 | 3.4 | 8.1 | 0.93 | |
–28 | 2 | 3.4 | 8.1 | 0.87 | |
–28 | 4 | 3.4 | 8.1 | 0.76 | |
–43 | 1 | 9.9 | 68.1 | 0.83 | |
–43 | 2 | 9.9 | 68.1 | 0.68 |
Table 2. Calculated polarization purity for asymmetry angle and number of reflections . Here, is the accepted beam divergence, is the beam footprint on the crystal surface and is the peak reflectivity. Taken from Ref. [68], licensed under CC BY 4.0.
2.2.3 Quasi-channel-cuts
It may be necessary to realize the two opposing surfaces by two separate crystals. This is called a quasi-channel-cut. It may help to tune the Bragg reflections separately by an angle offset[54] since the reflectivity curves for both polarizations
Furthermore, not all materials can be grown as large bulk as is done for silicon. For example, diamond is quite attractive because of its high thermal conductivity and low absorption in the X-ray region[55], but it is very challenging to produce at large sizes and to obtain high-quality diamond with few dislocations and stacking faults. A reflectivity as high as 99% of hard X-rays from nearly defect-free diamond crystals at near-normal incidence has been reported[69]. Nevertheless, low crystal quality and complicated production processes constrain the development of diamond in polarizers. Polarization purities of
The setup of a quasi-channel-cut is technically challenging in providing sufficient angular stability of both surfaces.
2.2.4 Temporal effects
Another feature, relevant for applications at XFELs in particular, is the inherent pulse stretching effect for Bragg crystals[70,71]. Due to the scattering at the lattice planes happening over many lattice planes (leading to the finite spectral bandwidth), a short X-ray pulse will become temporally stretched. The ray will enter the crystal at a certain depth where it is effectively diffracted out, being the Bragg-case extinction depth
This effect increases obviously with the Bragg angle and the number of consecutive reflections, and depends as well on the photon energy and material. The latter dependency is not straightforward. Higher photon energy usually leads to deeper penetration, but higher
2.3 Interim summary
In this section, we elaborated on the factors influencing the polarization purity of X-rays in X-ray polarimetry. For high polarization purity of X-rays, the requirements on the polarizer are four-fold: channel-cut crystal, being made of high-quality material, multiple Bragg reflections
For applications, not only purity
In 2022, Schulze et al.[59] reported an unprecedented purity of linear polarization of X-rays at the High Energy Density (HED) instrument of the European XFEL of
In contrast, the polarization purity could not be determined better due to limited photon flux and integration time, since the XFEL was operated in SASE mode with large spectral bandwidth, not matched with the polarizer acceptance. Thus, the polarization-independent transmission
3 X-ray polarimetry and vacuum birefringence
Many studies and concepts have been published for strong-field QED in general[39,73] and polarization effects in particular. Borysov et al.[74] proposed an indirect way to measure vacuum birefringence via experiments based on the photon-polarized nonlinear Breit–Wheeler (NBW) process. Xie et al.[75] reviewed the research progress of the pair production from vacuum in ultra-strong laser fields and investigated the effects of electric field polarizations on the number density of pair production. Koga et al.[76] presented the ultrahigh electric field generated by the interaction of micro-bubbles with ultra-intense laser pulses, which can be used to measure vacuum polarization via the bending of gamma rays traversing the imploded micro-bubble. Brezin and Itzykson[29] suggested using a laser beam and X-rays to study the small magnitude of effects predicted by QED. Correspondingly, X-ray polarimetry with excellent performance is proposed in detecting the vacuum birefringence phenomenon.
Currently, thanks to the development of ultra-intense optical lasers and XFELs, researchers[18–20,30,33,35,36,77,78] proposed to probe the characteristics of the QED vacuum. Here, the highly purified linearly polarized XFEL interacts with an intense optical laser in vacuum. The XFEL will change its polarization state from linearly polarized to elliptically polarized. This state can be detected via ‘flipped photons’ behind a polarizer that is crossed to the original linear polarization and thereby proves the vacuum birefringence.
3.1 Vacuum birefringence in the universe
Before going into details for laboratory studies, intense astrophysical magnetic fields are ideal to explore vacuum birefringence by X-ray polarimetry. Taverna et al.[79] calculated the polarization properties of X-ray radiation escaping from a magnetar magnetosphere via Monte Carlo code. By these simulations, they proved that polarimetric measurements are sufficiently sensitive to reveal QED effects due to vacuum polarization, and that X-ray polarimetry is an adequate tool to probe the ultra-strong magnetic fields in magnetars. In 2017, astronomers[80] experimentally proved the predictions of QED vacuum polarization effects via optical polarimetry measurement of isolated neutron stars. They measured the optical polarization degree to be
Although cosmic birefringence has been detected, its interpretation requires further models and assumptions but still can be controversial. This provides a solid case to study vacuum birefringence under controlled conditions in laboratories.
Figure 10.Proposed experimental setup for the demonstration of vacuum birefringence: a high-intensity laser pulse is focused by an
Figure 11.Schematic views of the experimental setup. Top: several meter-long parts of the X-ray beamline centered around the interaction point with the optical components inside a vacuum chamber. Left: zoom into a cm-sized neighborhood of the focus where the cleaning electrodes will be placed. Bottom left: another zoom into the cleaned region. The focus of the cleaning laser is about 10 μm wide. However, only a fraction (pink) of the cleaned region will be employed as the interaction region, where the PW optical laser () and the XFEL beam () are focused and superimposed. Bottom right: fundamental idea of probing QED vacuum birefringence caused by an intense optical laser with the XFEL beam. Beams are counter-propagating with their foci overlapping in space and time. To maximize the effect, the polarization directions must differ by 45°. A slight ellipticity in the polarization of the out-going probe pulse will occur. Used with the permission of IOP Publishing, from Ref. [19]; permission conveyed through Copyright Clearance Center, Inc.
3.2 Concepts for vacuum birefringence laboratory studies
Studies that were conducted with static magnetic fields and optical lasers have already been introduced in Section 1. Those studies could not identify vacuum birefringence due to insufficient sensitivity. As astrophysical phenomena indicate vacuum birefringence but cannot be controlled, numerous conceptions and schemes of vacuum birefringence detection have been published. Some of them, based on X-ray polarimetry, are presented in the following.
3.2.1 PW lasers and XFELs
In 2006, Heinzl et al.[20] considered a petawatt laser system with 140 fs pulse duration, 150 J pulse energy and
Schlenvoigt et al.[19] proposed an experimental scheme (Figure 11) based on the European XFEL and HED instrument in conjunction with the Relativistic Laser at Xfel (ReLaX) laser system being developed by the Helmholtz International Beamline for Extreme Fields (HIBEF). In this figure, the main part is the setup for vacuum birefringence detection. The PW laser is also focused by an OAP into the interaction area. The propagation of the XFEL is worth introducing in detail. A well-collimated XFEL is measured by an intensity monitor (IM) to record the number of X-ray photons. Then, the XFEL becomes a linearly polarized beam with
Moreover, the authors have studied the effect of plasma from residual gas particles on the signal of vacuum birefringence and proposed the method of vacuum cleaning. They plan to introduce another laser called a cleaning laser to ionize the gas particles, shown in yellow and named the cleaned volume, illustrated in the circle at the bottom left of Figure 11. The cleaned volume is much larger than the interaction volume, shown in pink. A static electric field is applied to remove charged particles from the cleaned volume. At the same time, the surrounding gas will repopulate the volume by diffusion, which can be mitigated by correct timing of the cleaning laser pulse. The bottom right shows the fundamental idea of probing QED vacuum birefringence by combining an XFEL and PW laser.
Subsequently, Shen et al.[35] and Xu et al.[77] presented an experimental design revolving around a 100 PW laser and a 12.914 keV XFEL beam with the Station of Extreme Light (SEL) at the Shanghai HIgh repetition rate XFEL aNd Extreme light (SHINE) facility. According to the parameters of the 100 PW laser and adopting the analysis of Schlenvoigt et al.[19], the ellipticity is about
There are further works presenting estimates for laser–XFEL studies, concentrating more on modeling and refined beam geometries[33,84]. They also consider 30 J, 30 fs, 1 PW laser systems in conjunction with
3.2.2 XFEL only
The common method of detecting vacuum birefringence is combining the XFEL with a PW-class optical laser. A novel way to detect vacuum birefringence by the collision of two consecutive XFEL pulses under a finite angle has been put forward by Karbstein et al.[86]. This idea takes the scaling of background field intensity (cf. Section 3.3) with wavelength,
Recently, the pulse duration of an XFEL was measured directly[87] to approximately 10 fs. This experiment demonstrates that the nonlinear regime of optics may be accessed in the X-ray domain, that is, sufficiently high photon densities can be produced. With a typical pulse energy of 1 mJ and the aforementioned pulse duration, the XFEL pulse power is about 100 GW. With
Facility | Soft/hard | Beam energy | Photon energy | Repetition rate |
---|---|---|---|---|
FLASH | Soft | 0.35–1.25 GeV | 14–620 keV | 4 kHz–1 MHz |
Both | 2.5–16.9 GeV | 0.28–28.8 keV | 120 Hz | |
Hard | 5.1–8.5 GeV | 4–20 keV | 60 Hz | |
FERMI | Soft | 1–1.5 GeV | 20–310 eV | 50 Hz |
PAL-XFEL | Both | 3.5–10 GeV | 0.28–20 keV | 60 Hz |
SwissFEL | Soft | 2.1–5.8 GeV | 250–1240 keV | 100 Hz |
Both | 8.5–17.5 GeV | 0.24–25 keV | 27 kHz | |
SXFEL | Soft | 1–1.6 GeV | 124–1000 eV | 50 Hz |
LCLS-II (HE) | Both | 4–15 GeV | 0.2–25 keV | 120 Hz, 1 MHz |
SHINE | Both | 8 GeV | 0.4–25 keV | 1 MHz |
Table 3. Overview of XFEL facilities. Bold facility names indicate facilities with an ultra-intense laser in operation. Italic represents planned facilities. Adapted from Ref. [90], licensed under CC BY-NC-ND 4.0.
From the installation diagram (Figure 12) we can see that the XFEL beam is focused twice to the interaction region from different directions. This employs the pulse train, such that pulse
Figure 12.Illustration of the experimental setup utilizing compound refractive lenses (CRLs) to focus and re-collimate the XFEL beam. Reflections at diamond crystals change the propagation direction, and a pair of diamond quasi-channel-cuts serve as the polarizer and analyzer, respectively. The original XFEL beam is focused with a CRL to constitute the pump field; the beam focus defines the interaction point. Subsequently, it is defocused with a CRL and by reflection at two diamond crystals directed back to the interaction point under an angle of . Before reaching the interaction point, it is polarized with a diamond polarizer and the resulting probe beam focused to the interaction point with a CRL. Finally, it is defocused with another CRL, analyzed with a diamond analyzer and the signal registered with a charge-coupled device. Taken from Ref. [86], licensed under CC BY 4.0.
Apart from X-ray polarimetry, scientists have presented a different approach for measuring vacuum birefringence using multi-MeV to GeV photons[37,91]. King and Elkina[37] carried out the analytical calculations and numerical simulations for the measurement of vacuum birefringence by multi-MeV photons, instead of X-ray or optical photons. Nakamiya and Homma[91] proposed combining a 10 PW laser system with a 1 GeV gamma-ray photon source to probe the vacuum birefringence effect and designed the gamma-ray polarimeter to measure the polarization flip of the probe gamma-rays. They derived theoretically the phase retardation of GeV probe photons via pairwise topology of the Bethe–Heitler process in a polarimeter, and concluded it would be possible to observe the vacuum birefringence effect with the accuracy of 4.7% for the averaged phase retardation
3.3 Estimated ellipticity
Referring to the previous contents, the highly linearly polarized XFEL changes its polarization state to elliptically polarized when it propagates through a vacuum that is polarized by focusing a light beam as the background field. This is slightly different from the quasi-constant fields employed in studies with optical laser polarimetry (cf. Section 1). The calculations lead to similar expressions, such that a difference of the refractive index, Equation (4), leads to a phase shift of two circular polarization components of the linearly polarized XFEL, as follows:
It must be noted that this effect is maximized if (i) the background field is counter-propagating to the probing pulse and (i) the background field polarization is 45° to the probe field polarization[20,35].
Heinzl et al.[20] considered for a Gaussian optical laser beam as the background field to set
Schlenvoigt et al.[19] refined the analytical framework of Heinzl et al.[20] by taking their result as a differential phase shift and integrated analytically for counter-propagating Gaussian beams with Gaussian pulse shapes, and accounted for temporal and spatial offsets, enabling an analysis for jittering conditions. This approach showed that
In view of considerably differing estimates due to many influencing factors, we only provide scalings[19,85] with the relevant quantities. First, we address the background field intensity:
The previous equations can be combined and yield, employing for clarity
Reference | Laser power | Intensity | Ellipticity |
---|---|---|---|
(PW) | (W/cm2) | ||
Heinzl et al.[ | 1 | ||
Schlenvoigt et al.[ | 1 | ||
Shen et al.[ | 100 | ||
Mosman and Karbstein[ | 0.3 |
Table 4. Comparison of laser parameters and expected ellipticity (for 13 keV photon energy) of the proposed experiments. Note that Heinzl
3.4 Readiness review
Regarding the detection of such ellipticity, a polarimeter with crossed polarizations would be realized. The ellipticity is effectively the probability that a probe beam photon flips its polarization state. Therefore, referring back to Section 2.1 and considering
In addition, such detection would require the integration of photons to achieve a certain confidence limit, probably by a number of repetitions
The integration time can be reduced by
3.4.1 XFEL facilities
XFELs are indispensable sources for structural analysis and have contributed to the development of ultra-fast processes. XFEL facilities have blossomed all over the world[90]. In Europe, Deutsches Elektronen-Synchrotron (DESY)[92,93], one of the accelerator centers, contains three large accelerators: PETRA III, FLASH and European XFEL. FLASH supplies soft X-rays and PETRA III and EuXFEL supply hard X-rays. Italian Elettra Sincrotrone Trieste[94] has two advanced light sources: Elettra and FERMI. The third-generation synchrotron radiation facility Elettra produces synchrotron radiation in a wavelength range from infrared to hard X-rays, while FERMI is a seeded free electron laser working in the ultraviolet and soft X-ray range. SwissFEL[95,96] is Switzerland’s X-ray free electron laser with a hard X-ray free electron laser with 0.1 nm wavelength and 20 fs pulse duration at the Paul Scherrer Institute (PSI).
In the USA, the Linac Coherent Light Source (LCLS)[97,98] at SLAC achieved the first lasing and FEL saturation at 0.15 nm in 2009. Its upgrade LCLS-II[99] is designed to produce high-energy X-rays covering the energy range from 200 eV to 1.5 keV for soft X-rays and from 1 to 5 keV for hard X-rays. A further upgrade[100] from 4 to 8 GeV beam energy will extend the photon energy range to at least 12.8 keV.
In Asia, the first FEL facility was the SPring-8 Ångström Compact Free-Electron Laser (SACLA)[101] in Japan, with a peak X-ray laser power of 1 GW and wavelength of 0.1 nm. It has matured to multi-beamline, soft and hard X-ray operation[102,103] and extreme intensities[87]. The Pohang Accelerator Laboratory X-ray Free Electron Laser (PAL-XFEL)[76] produces wavelengths of 0.1 and 1 nm for hard and soft X-rays, respectively. In China there are two facilities[104,105]: the Soft X-ray Free Electron Laser (SXFEL) performs the shortest wavelength of 2 nm, and the hard XFEL SHINE with a 0.05 nm wavelength is being constructed. All of these facilities with brilliant X-rays enable scientists to gain insights into the properties, ultrafast processes and essences of matter.
We are not discussing synchrotron sources for two reasons. They are currently limited in beam divergence and thus in polarization purity. Furthermore, their pulses are much longer than background field pulses and contain far fewer photons than XFEL pulses.
In the context of X-ray polarimetry of vacuum birefringence, it must be noted that probe beam photon numbers are often over-estimated in experiment proposals. Typical XFEL pulse energies are of the order of 1 mJ, which yields at 12 keV about
A relative spectral width of
For higher photon energies, for example, the solid curve in Figure 5 for
3.4.2 PW-class laser facilities
Ultra-intense pulsed lasers are known to produce the highest light intensities on Earth and are thus favorable tools to generate the background field in their focus, polarizing the vacuum helped by a counter-propagating probe light. Table 4 has already provided estimated ellipticities for relevant peak intensities. Those intensities are in reach of currently available laser technology. Recently, laser scientists at the Center for Relativistic Laser Science (CoReLS) in Korea reported a peak laser intensity exceeding
Ultra-intense laser systems are nowadays commercially available and are widely employed. They are in general based on the chirped pulse amplification scheme (CPA)[110] and exhibit pulse durations of from approximately 10 fs to approximately 1 ps, and typical wavelengths are 800 nm or 1.05 μm. An overview can be found at The International Committee on Ultrahigh Intensity Lasers (ICUIL)[111], where they provide an interactive map[112].
PW-class lasers are currently the top class of existing facilities, but there are several dozen and hence too many to list them all. Here we concentrate on facilities and projects significantly exceeding 1 PW.
The Extreme Light Infrastructure (ELI)[113–116] is an advanced laser-based research infrastructure with multiple sites. One of the sites is Extreme Light Infrastructure Nuclear Physics (ELI-NP), which succeeded in delivering the 10 PW @ 1 shot per minute in 2019.
In the UK, the Central Laser Facility (CLF)[117,118], part of the Rutherford Appleton Laboratory, is dedicated to high-energy laser systems. There are five laser facilities: ULTRA, Artemis, OCTOPUS, Gemini and Vulcan. Here, Gemini is a dual beam laser system with 2 × 15 J, 30 fs laser pulses. Vulcan has two kinds of laser modes. In its long pulse mode, the laser energy is up to 2.6 kJ with nanosecond pulse duration. In the short pulse mode, it has up to 1 PW peak power with 500 fs pulse duration and the focal intensity is about
In France, the Apollon laser system is a multi-beam, multi-petawatt facility to generate 10 PW pulses of 150 J energy and 15 fs (full width at half maximum (FWHM)) duration at a repetition rate of 1 shot per minute. The first available laser beam delivered on-target pulses of 10 J average energy, 24 fs duration and 1 PW nominal power in 2021[119].
The Institute of Applied Physics of the Russian Academy of Sciences has established a large infrastructure project, the Exawatt Center for Extreme Light Studies (XCELS)[120–122]. The aim of the project is to build high-power lasers with 200 PW power and 25 fs pulse duration by assembling 12 identical laser channels with 15 PW power for each. The intensity in the focus is expected to be approximately
Furthermore, the project of Shanghai HIgh repetition rate XFEL aNd Extreme light facility (SHINE) was founded[123] in Shanghai, China. In the future, the SEL of SHINE will provide a laser system with 100 PW and an expected focused laser intensity of
In view of vacuum birefringence, the gain of ellipticity
2011[ | 2013[ | 2015[ | 2016[ | 2020[ | 2021[ | 2022[ | 2022[ | |
---|---|---|---|---|---|---|---|---|
Facility | ESRF | ESRF | Petra III | ESRF | ESRF | Petra III | Eu. XFEL | Petra III |
Beamline | ID06 | ID06 | P01 | ID06 | ID18 | P01 | HED | P01 |
6.457 | 6.457 | 12.914 | 9.839 | 9.83 | 14.41 | 6.457 | 12.914 | |
Material | Silicon | Silicon | Silicon | Diamond | Diamond | Silicon | Silicon | Silicon |
Reflection | (400) | (400) | (800) | (400) | (400) | (840) | (400) | (800) |
4 | 6 | 6 | 2 | 4 | 4 | 6 | 4 | |
0 | 0 | 0 | 0 | 0 | 0 | 0 | ||
- | 10.3 | - | 10 | 8.4 | - | 0.273 | 18.8 | |
- | 2.9 | - | - | 6.1 | - | 25.9 | ||
- | - | - |
Table 5. Timeline of precision X-ray polarimetry. Here, denotes the number of reflections per channel-cut crystal, and represent the beam divergence, is the obtained polarization purity and is calculated from the divergence according to
3.4.3 Combined facilities
For the purpose of vacuum birefringence experiments where the background field is generated by an ultra-intense laser and X-ray polarimetry is employed for detection, it is mandatory to combine XFELs with such lasers. In most cases, XFEL facilities host several beamlines and/or several instruments per beamline. Thanks to the wide range of applications and thus an existing market, it is relatively straightforward to equip an XFEL instrument with an ultra-intense laser. Even for systems below the PW level there are enough use cases to use XFELs as probes in laser–matter interactions.
Referring to Table 3, there are three out of four existing hard X-ray facilities equipped with an ultra-intense laser. We can exclude soft X-ray FELs since a key for detection is a short probe wavelength. The facilities and instruments are: MEC at LCLS/SLAC, SACLA EH6 and HED/HIBEF at the European XFEL. Their respective parameters[35,91,98,111,125–127] are listed in Table 6.
Facility | End station | ||||
---|---|---|---|---|---|
LCLS | MEC[ | 1 J | 40 fs | 25 TW | |
LCLS-II(-HE) | MEC-U[ | 150 J | 150 fs | 1 PW | |
European XFEL | HED[ | 10 J | 30 fs | 300 TW | |
SACLA | EH6[ | 2 × 12.5 J | 30 fs | 2 × 500 TW | |
SHINE | SEL[ | 1500 J | 15 fs |
Table 6. Overview of facilities combining XFEL beams with PW-class lasers. Planned facilities are shown in italic. Please note that there is no common factorial relation between laser power and peak intensity. Focusing F-numbers very among the facilities, adapted to their overall mission. Furthermore, beam quality can reduce the encircled energy in the focal spot and therefore reduce the peak intensity[127]. The provided laser pulse wavefront control for the final focusing and reasonably tight focusing, per 1 PW, is realistic.
The Matter in Extreme Conditions (MEC) instrument is the facility at LCLS that produces extreme matter states with an intense laser radiation, where LCLS provides complete imaging and optical diagnostics methods. Nagler et al.[125] presented an overview of the beamline, the capabilities of the instrumentation and highlights of experiments. Glenzer et al.[130] summarized the first experiment of laser-compressed solids and the measurements of highly accurate X-ray diffraction and X-ray Thomson scattering on the MEC instrument at LCLS. Fletcher et al.[131] investigated bremsstrahlung from relativistic electrons generated by the interaction of a high-intensity femtosecond laser with solid μm-thick aluminum and polypropylene targets, and measured the energy spectrum and temperature of hot electrons via differential X-ray energy filtering.
Similar to the LCLS, the SACLA XFEL facility opened after the completion of commissioning[127,132]. This experimental platform is equipped with two beams of 800 nm wavelength, 1 Hz repetition rate and 12.5 J maximum energy in a 25 fs pulse duration and a 500 TW peak power after pulse compression. Yabuuchi et al.[127] characterized the light source performance during the commissioning of the experimental platform and confirmed that the XFEL and the high-intensity laser can operate normally with dedicated diagnostics.
In Europe, the HED scientific instrument at the European XFEL is a unique platform for experiments in extreme conditions of pressure, temperature or electromagnetic field[128,133]. Zastrau et al.[128] presented the scientific scope, technical infrastructure, diagnostics and experimental platforms. The HED scientific instrument supports a variety of X-ray methods, including X-ray polarimetry. The HIBEF user consortium contributes the high-intensity and high-energy laser systems[129,134] and their operation for users.
Another combined XFEL–laser facility will be the SEL at SHINE, which is designed to achieve laser intensities sufficient to explore the vacuum birefringence effect by colliding an XFEL[35,135].
Figure 13.Sketch of the experimental setup investigating CRL material properties. The multilayer mirrors collimate the X-rays from the rotating anode X-ray source. The combination of the polarizer, analyzer and charge-coupled device camera allows for polarization sensitive imaging. Reprinted from Ref. [61], with the permission of AIP Publishing.
In view of vacuum birefringence, currently operating facilities provide laser intensities of 1019–
These restrictions can be lifted for experiments dedicated to vacuum birefringence, for example, by providing a dedicated focusing element. We repeat here that a peak intensity of approximately
3.4.4 X-ray optics
Besides precision X-ray polarizers, CRLs are indispensable optical elements in the vacuum birefringence experimental setup with two purposes. Primarily, the XFEL beam must be focused into the interaction volume with the tightly focused PW laser. This is the purpose of the first CRL. On the other hand, the polarizers require a low divergence to provide a high extinction ratio. Therefore, the first CRLs must be located after the polarizer. In addition, the XFEL must be re-collimated by the second CRL, after the interaction but before the analyzer. In essence, two sets of CRLs are already inside the polarimeter setup. Therefore, the effects of the CRL material on the polarization must be studied and a suitable material must be found. Grabiger et al.[61] studied how the lens material itself influences the X-ray polarization. The setup is shown in Figure 13[61].
Grabiger et al.[61] analyzed three different grades of beryllium samples: high purity (PF-60), optical grade (O-30-H) and ultra-high purity grade (IF-1) beryllium. The results in the upper part of Table 7 clearly indicate that the beryllium samples greatly affect polarization purity. In this regard, the explanation given by the authors is the polycrystalline state of beryllium and they suggested two better options to focus X-rays. One alternative way is to employ reflective optical components, such as Kirkpatrick–Baez mirrors. Another option is to manufacture X-ray lenses from either single-crystal materials such as diamond, or from materials with an amorphous structure, such as glassy carbon and polymers.
Sample | Thickness (μm) | Polarization purity |
---|---|---|
No sample | - | |
Be PF-60 | 500 | |
Be IF-1 | 500 | |
Be O-30-H | 700 | |
CRL material | Transmission | Polarization purity |
No lenses | - | |
Be O-30-H | 0.93 | |
SU-8 | 0.64 | |
Diamond | 0.82 | |
Glassy carbon | 0.63 |
Table 7. Deterioration of polarization purity by CRL materials. Upper part for flat Be samples at approximately 8 keV; lower part for CRL telescopes with focal length at approximately 13 keV. Data taken from Ref. [61], with the permission of AIP Publishing, and from Ref. [72], licensed under CC BY 4.0.
Those materials were studied later by the same group[72]. They now used a synchrotron source for better sensitivity and investigated the impact of CRLs of different materials on the polarization purity, mimicking the general scheme of focusing and re-collimation proposed for vacuum birefringence X-ray polarimetry experiments[19,33,35,84,86]. However, they employed rather long focal lengths of approximately 6 m. For shorter focal lengths, more CRL materials would be exposed to the beam and probably deteriorate the purity more strongly than currently measured. The results are listed in the lower part of Table 7. CRLs were fabricated out of Be, SU-8 photo-polymer, diamond and glassy carbon. From all of those materials, the CRLs fabricated from SU-8 showed the least depolarization of X-rays.
It should be noted that data for Be cannot be easily compared across both parts of Table 7. The effective thickness of the Be CRLs is not provided, and both experiments employed different photon energies.
In regard to X-ray polarimetry for vacuum birefringence, the results show another limit. Even though the deteriorated purity
3.5 Interim summary
An attractive application of X-ray polarimetry is to detect the vacuum birefringence phenomenon. There is one widely recognized method, combining PW optical lasers with XFELs. Alternatively two XFEL pulses, out of a pulse train or by a split-and-delay setup, are proposed. Such scheme appears currently more demanding in terms of the X-ray beam path setup.
So far, X-ray polarizer technology has made tremendous progress (cf. Table 5). Material dependencies, beam dependencies (divergence, Equation (7)) and sophisticated alignment protocols (detour avoidance by azimuth alignment) are understood and have become practice. Despite that the transition from synchrotrons to XFELs for polarizer characterization allows for better purity due to the divergence dependence, the spectral width of XFELs is not matching that of polarizers, leading to low throughput. This limits the polarimeter in terms of photon flux: only very few photons arrive at the detector[59]. This can be optimized by spectral tailoring of the FEL process as well as increasing the acceptance of channel-cut crystals by using asymmetric cuts and appropriate polarizer material choice.
That optimization of integrated transmission is mandatory for X-ray polarimetry of vacuum birefringence in order to provide a high-signal photon number
It was further recognized that CRL material might affect the polarization purity, as CRLs are foreseen in most schemes for vacuum birefringence. The first investigation of traditional CRL material[61] was an important step towards applications of polarimetry, and has shown the need for further investigations and improvements of purity. A follow-up study, employing actual CRL telescopes (as often proposed for vacuum birefringence studies) fabricated from unconventional materials, showed that those materials have a much reduced impact on the purity[72].
As this impact is probably limiting the purity
In summary, measurements of vacuum birefringence in laboratory conditions from ultra-intense lasers by X-ray polarimetry are still pending and need proper preparation in regard to source photon count, beam divergence, spectral transmission, polarizer reflectivity, CRL transmission and depolarization, polarizer extinction and detector efficiency.
4 Further applications of X-ray polarimetry
Apart from probing vacuum birefringence, X-ray polarimetry is applied to other scientific cases: nuclear resonant scattering experiments[68,136–138], measuring the magnetic fields inside solid-density plasmas via Faraday rotation[139–141] and applications to astrophysics[34,82,142,143]. Now, we present those applications of X-ray polarimetry.
4.1 Nuclear resonant scattering
Nuclear resonant scattering is a technique for measuring the structural dynamics, magnetic and electronic properties of condensed matter. Compared to the usual radioactive sources, synchrotron radiation sources open up new perspectives for nuclear resonant scattering in the field of materials science[67,68,144]. Polarimetry with perfect crystals is adequate for preventing the non-resonant scattering called polarization filtering in nuclear resonant scattering experiments[67,68,145]. The elementary idea is to separate non-resonant scattering from a large background of resonantly scattered X-rays. The schematic setup is displayed in Figure 14[68]. The polarizer and analyzer are silicon (840) channel-cut crystals with two asymmetric reflections and are in the crossed position. Linearly polarized radiation will switch its polarization to mix polarization states when it is scattered by a medium placed in a magnetic field upon nuclear resonant reflection.
Figure 14.Schematic setup for nuclear resonant scattering with the polarization filtering method. The incoming radiation from the left is polarized by the first channel-cut crystal. Subsequently, the beam impinges on the magnetically anisotropic sample under investigation. The green arrow indicates the direction of the external magnetic field that induces optical activity via X-ray magnetic linear dichroism. The analyzer crystal in the crossed setting transmits only the photons that have undergone nuclear resonant - to –scattering. Taken from Ref. [68], licensed under CC BY 4.0.
4.2 Detection of magnetic fields
In 1990, Siddons et al.[16] observed the rotation of the polarization plane of a synchrotron X-ray beam in cobalt alloys by X-ray polarimetry, thereby detecting the optical Faraday effect in the X-ray domain. They also demonstrated the optical activity near the K-edge of cobalt in a chiral organometallic compound.
Faraday rotation is also a widely used diagnostic of plasmas[146,147], usually employing visible lasers in low-density plasmas, for example, magnetic confinement fusion plasmas[148]. With XFELs, this method can be transferred to solid-density plasmas. This is of great interest for plasmas driven by ultra-short ultra-intense lasers to probe self-generated magnetic fields[139]. The fields reach kilo- to megatesla (MT)-level field strength and originate from fast electron transport, balancing return currents and their respective resistivity inside the solid target[141]. Researchers[139–141] have proposed a method of examining the magnetic fields of the laser-irradiated plasma by X-ray polarimetry via Faraday rotation using XFELs.
Figure 15.An illustrated experimental setup of strong magnetic field generation by interaction of an ultra-short relativistic optical laser pulse with solid matter, probed by an XFEL via Faraday rotation. Taken from Ref. [140], licensed under CC BY 4.0.
Figure 15 depicts the experimental setup[140]. The optical ultra-short relativistic laser pulse is deployed to generate extreme multi-megagauss (MG) magnetic fields in a solid-density target. The XFEL acts as a probe to detect those laser-driven magnetic fields. The probe XFEL beam is perfectly horizontally polarized, and then the orientation of the polarization plane is rotated by the magnetic field component. The total rotation angle of the exiting XFEL beam is as follows[139,140]:
From Equations (19) and (20) we can see that the rotation angle is proportional to the wavelength of the probe beam. A beam with a long wavelength can obtain a large rotation angle but will have poor penetration depth in solid-density plasma. However, even though the wavelength of the XFEL is short, the XFEL is able to penetrate solid-density plasmas of up to several tens of micrometers thicknesses because of the high attenuation length. Therefore, it is advantageous to select the XFEL beam as the probe pulse. Studies proposing this scheme[139,141] estimate that the polarization of an XFEL with 6.457 keV photon energy will be rotated about
4.3 Astrophysics
X-ray polarimetry is an appealing tool to investigate geometric information, emission mechanisms and the structure of the magnetic fields in and around objects in the universe, such as supermassive black holes and neutron stars[34,82,142,143,149]. In astrophysics, the formation and subsequent evolution of the population of black holes are fascinating and can be determined by the mass and angular momentum given by X-ray polarimetry[142]. In 1976, Weisskopf et al.[149] measured the linear polarization of the X-ray flux from the Crab Nebula by the graphite crystal X-ray polarimeters aboard the OSO-8 satellite, as illustrated in Figure 16[149]. For reducing the background signal from cosmic rays, the parabolic surface is used to focus the diffracted X-rays. Caiazzo and Heyl[82] showed that vacuum birefringence affects changes of the X-ray polarization of stellar-mass and supermassive black holes. The model with QED can not only probe the spin and the magnetic field strength close to the innermost stable orbit of black-hole accretion disks, but also provides a validity check for theories of astrophysical accretion. For accretion-powered pulsars with known energy of cyclotron-resonant scattering features[150], X-ray polarimetry is suited to obtain information about the geometry of the accretion column and magnetic field strength. Besides, X-ray polarimetry has the potential to discover the mechanisms of astrophysical particle acceleration, such as supernova remnants (SNRs), pulsar wind nebulae (PWNe), pulsars and black-hole jets[143]. Heyl and Caiazzo[34] applied the equation of the polarization evolution to determine the atmosphere composition and the surface gravity of an X-ray pulsar. Furthermore, the radius of the star can be inferred from the photon energy at the polarization direction flips. Therefore, X-ray polarimetry is a powerful tool to study neutron stars and black holes. Its high sensitivity and resolution are promising to unravel crucial information of the physical processes and structure of astronomical objects.
Figure 16.Exploded view of the OSO-8 polarimeter assemblies. The crystal reflector employs approximately Bragg angle and is thereby polarization-filtering. Reprinted from Ref. [151], with the permission of Springer Nature.
5 Conclusions
This paper reviews the status of X-ray polarimetry and mainly its application for detecting vacuum birefringence. First, the main details of the factors affecting the polarization purity of X-rays were analyzed for 45° Bragg reflectors, employing Brewster’s law for suppression of a linear component in the plane of incidence. Crystal quality, beam quality and material dependencies were presented and detailed for channel-cut crystal polarizers. An unprecedented polarization purity of
This high level of polarization purity provides an opportunity to explore the nonlinear property of vacuum, such as vacuum birefringence. An all-optical laboratory scheme allows for precise measurements of QED nonlinearities in particular in the low-energy but strong-field limit, which is sensitive to new physics and particles beyond the standard model[21,38]. For this application, we summarized for various proposals the signal dependence on ultra-intense laser sources that offer extremely intense external fields to polarize the vacuum. We presented the scientific facilities of optical PW lasers and XFELs throughout the world. We assessed their status regarding proposed experimental schemes and added aspects beyond the sole polarization purity
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