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 | JOURNAL OF SYNCHROTRON RADIATION |
A new imaging technology based on Compton X-ray scattering
aInstituto Galego de Física de Altas Enerxías (IGFAE), Rúa de Xoaquín Díaz de Rábago, s/n, Campus Vida, 15782 Santiago de Compostela, Spain, bSynchrotron Radiation Research and NanoLund, Lund University, Box 118, 221 00 Lund, Sweden, and cI3N, Physics Department, University of Aveiro, Campus Universitário de Santiago, 3810-193 Aveiro, Portugal
*Correspondence e-mail: angela.saa.hernandez@usc.es
A feasible implementation of a novel X-ray detector for highly energetic X-ray photons with a large solid angle coverage, optimal for the detection of Compton X-ray scattered photons, is described. The device consists of a 20 cm-thick filled with xenon at atmospheric pressure. When the Compton-scattered photons interact with the xenon, the released photoelectrons create clouds of which are imaged using the produced in a custom-made multi-hole acrylic structure. Photon-by-photon counting can be achieved by processing the resulting image, taken in a continuous readout mode. Based on Geant4 simulations, by considering a realistic detector design and response, it is shown that photon rates up to at least 1011 photons s−1 on-sample (5 µm water-equivalent cell) can be processed, limited by the spatial diffusion of the photoelectrons in the gas. Illustratively, if making use of the Rose criterion and assuming the dose partitioning theorem, it is shown how such a detector would allow obtaining 3D images of 5 µm-size unstained cells in their native environment in about 24 h, with a resolution of 36 nm.
Keywords: Compton scattering; hard X-rays; cell imaging; time projection chamber; electroluminescence.
1. Introduction
Despite some X-ray facilities and experiments making use of Compton scattering to probe for instance the electronic and magnetic structure of materials (Sakurai, 1998![[Sakurai, Y. (1998). J. Synchrotron Rad. 5, 208-214.]](../../../../../../logos/arrows/s_arr.gif "Sakurai, Y. (1998). J. Synchrotron Rad. 5, 208-214.")
; Tschentscher et al., 1998), the limited and (brightness) that is currently available at the required high energies (≳20 keV) seem to have precluded the popularization of these techniques. With the advent of the fourth generation of synchrotron light sources, such as ESRF-EBS (Admans et al., 2014), the projected APS-U (APS, 2019), Petra IV (Schroer et al., 2019) and SPring-8-II (Asano et al., 2014), as well as the proposal of novel facilities based on X-ray free-electron lasers (Huang, 2013), which increase the and coherent for hard X-rays by at least two orders of magnitude beyond today's capability, a unique opportunity arises to use Compton scattering in ways that were not conceived before. An example of these new possibilities is scanning Compton X-ray microscopy (SCXM) (Villanueva-Perez et al., 2018). This technique has the potential of obtaining tens of nanometre resolution images of biological or radiosensitive samples without sectioning or labelling. Thus, it bridges the capabilities of optical and electron microscopes. Exploiting Compton interactions for biological imaging is possible because, in spite of its inelastic nature, the SCXM technique makes an optimal use of the number of scattered photons per unit dose, i.e. the deposited energy per unit of mass. Generally speaking, an efficient use of Compton scattering implies, first and foremost, that a nearly 4π-coverage is required (Fig. 1), at an optimal energy around 64 keV if aiming for instance at resolving DNA structures (Villanueva-Perez et al., 2018). This poses a formidable challenge for current detection technologies, which are costly and have detection areas much below the required size. Conversely, at lower X-ray energies (≲10 keV), imaging based on coherent scattering has benefited from the development of ultra-fast pixelated silicon detectors, capable of performing photon-counting up to 107 counts s−1 pixel−1. A nowadays typical detection area is 40 cm × 40 cm, sufficient for covering the coherent forward cone at a distance of about 1 m, at near 100% (Förster et al., 2019). At higher energies, silicon must be replaced by a semi-conductor with a higher to X-rays, e.g. CdTe. However, targeting a geometrical acceptance around 70% at 64 keV, while providing enough space to incorporate a compact setup (namely the sample holder, step motor, pipes, shielding and associated mechanics), would imply an imposing active area for these type of detectors, well above 1000 cm2. For comparison, PILATUS3 X CdTe 2M, one of the latest high-energy X-ray detectors used at synchrotron sources, has an active area of 25 cm × 28 cm (DECTRIS, 2019). Clearly, the availability of a 4π/high-energy X-ray detector would soon become an important asset at any next-generation facility, if it can be implemented in a practical way.
![[Figure 1]](gy5021fig1thm.gif) | Figure 1 Differential cross section for Compton-scattered photons on DNA (in barn per stereoradian) for a linearly polarized X-ray beam of 64 keV as obtained with Monte Carlo simulations [using Geant4 (Agostinelli et al., 2003 )] and tabulated values (Hubbell et al., 1975) (dashed lines), for different azimuthal regions: ϕ = [0–10]° (green), ϕ = [85–95]° (blue) and integrated over ϕ (red). ϕ indicates the angle relative to the direction of the polarization vector. |
In this work we have implemented a novel approach for the detection of 4π Compton-scattered photons based on a technology borrowed from particle physics: the Electroluminescent Time Projection Chamber (EL-TPC), discussing its performance as an SCX microscope. TPCs, introduced by D. Nygren in 1974 (Nygren, 1974, 2018), are nowadays ubiquitous in particle and nuclear physics, chiefly used for reconstructing particle interactions at high track multiplicities (Alme et al., 2010), and/or when very accurate event reconstruction is needed (Phan et al., 2016; Acciarri et al., 2016; González-Díaz et al., 2018). The main characteristics of the particular TPC flavour proposed here can be summarized as: (i) efficient to high-energy X-rays thanks to the use of xenon as the active medium, (ii) continuous readout mode with a time sampling around ΔTs = 0.5 µs, (iii) typical temporal extent of an X-ray signal (at mid-chamber): ΔTx-ray = 1.35 µs, (iv) about 2000 readout pixels/pads, (v) single-photon-counting capability, and (vi) an energy resolution potentially down to 2% FWHM for 60 keV X-rays, thanks to the mode (Kowalski et al., 1989), only limited by the Fano factor F.1 Importantly, the distinct advantage of using instead of conventional avalanche multiplication is the suppression of ion space charge, traditionally a shortcoming of TPCs operated under high rates.
Our design is inspired by the proposal of Nygren (2007), that has been successfully adopted by the NEXT collaboration in order to measure neutrino-less double-beta decay (Monrabal et al., 2018), but we include three main simplifications: (i) operation at atmospheric pressure, to facilitate the integration and operation at present X-ray sources, (ii) removal of the photomultiplier-based energy plane, and (iii) introduction of a compact all-in-one structure, purposely designed for photon-counting experiments.
In this paper we discuss, starting from Section 2, the main concepts and working principles leading to our conceptual detector design. Next, in Section 3, we study the photon-counting capabilities of a realistic detector implementation. We present the expected performance when applied to the SCXM technique in Section 4. Finally, we assess the limits and scope of the proposed technology in Section 5.
2. TPC design
2.1. Dose and intrinsic resolving power
In a scanning, dark-field, configuration, the ability to resolve a feature of a given size embedded in a medium can be studied through the schematic representation shown in Fig. 2 (top), that corresponds to an arbitrary step within a two-dimensional (2D) scan, in a similar manner as presented by Villanueva-Perez et al. (2018).
![[Figure 2]](gy5021fig2thm.gif) | Figure 2 Top: study case. A cubic DNA feature (size d) is embedded in a cubic water cell (l = 5 µm), surrounded by air/helium (a = 5 mm). The photon beam scans regions containing only water (case 0), or water and DNA (case f). These two cases are used to evaluate the of SCXM at a given dose. Bottom: dose needed to resolve a DNA feature as a function of its size assuming 100% for X-ray energies of 30 keV and 64 keV, obtained, respectively, with Geant4 (Agostinelli et al., 2003 ) (solid lines) and using NIST values (Berger et al., 2010) (dotted line), and the formulas in the text. The black line represents the estimated from coherent scattering experiments (Howells et al., 2009). |
Three main assumptions lead to this simplified picture: (i) the dose fractionation theorem (Hegerl & Hoppe, 1976), based on which one can expect three-dimensional (3D) reconstruction capabilities at the same resolution (and for the same dose) than in a single 2D scan, (ii) the ability to obtain a focal spot, d′, down to a size comparable with (or below) that of the feature to be resolved, d, and (iii) a depth of focus exceeding the dimensions of the sample under study, l. A possible technical solution to the latter two problems was introduced by Villanueva-Perez et al. (2018), targeting a 10 µm depth of focus at a 10 nm focal spot, thanks to the combination of multi-layer Laue lenses (MLLs; Bajt et al., 2018) with a stack of negative refractive ones. Since that technique would enable any of the scenarios discussed hereafter, we adopt the situation in Fig. 2 (top) as our benchmark case, and we use the Rose criterion (Rose, 1946) as the condition needed to discern case f (feature embedded within the scanned volume) from case 0 (no feature), that reads in the Poisson limit as
![[{{|N_{f}-N_{0}|} \over {\big({\sigma_{N_{f}}^{2}+\sigma_{N_{0}}^{2}} \big)^{1/2}}} = {{|N_{f }-N_{0}|} \over {\left({N_{f}+N_{0}} \right)^{1/2}}} \,\,\geq\, 5, \eqno(1)]](teximages/gy5021fd1.svg)
with N being the number of scattered photons. Substitution of physical variables in equation (1) leads directly to a required fluence of
![[\phi \,\geq\, \phi_{\rm{min}} = 25\,{{(2l-d)\,\lambda^{-1}_{w}+d\lambda^{-1}_{f}+4a\lambda^{-1}_{a}} \over {d^{\prime2}\,d^{2}\,(\lambda^{-1}_{f}-\lambda^{-1}_{w})^{2}}}, \eqno(2)]](teximages/gy5021fd2.svg)
and we will assume d′ ≃ d. Here λw, λf, λa are the Compton-scattering mean free paths of X-rays in water, DNA and air (or helium), respectively (Table 1), and dimensions are defined in Fig. 2 (top). Finally, we evaluate the dose that will be imparted at the feature in these conditions as
![[\eqalignno{ {\cal D} = {}& \phi_{\rm{min}}\,\varepsilon\, {{N_{\rm{A}}}\over{M_{f}}} \bigg\{ \sigma_{\rm{ph}} \cr& + \int{{{\rm{d}}\sigma_{\rm{C}}}\over{{\rm{d}}\Omega}} \, \bigg[ 1-{{1}\over{ 1+(\varepsilon/m_{\rm{e}}c^2)(1-\cos\theta)}} \bigg] \,{\rm{d}}\Omega \bigg\}, &(3)}]](teximages/gy5021fd3.svg)
where σph is the photoelectric and ![[{\rm{d}}\sigma_{\rm{C}}/{\rm{d}}\Omega]](teximages/gy5021fi1.svg)
is the differential for Compton scattering, both evaluated at the feature. Mf is the feature molar mass, NA the Avogadro number, ɛ the photon energy and θ its scattering angle. The dose inherits the approximate l/d4 behaviour displayed in equation (2).
| ||||||||||||||||||||||
Working with equation (3) is convenient because it has been used earlier, in the context of coherent scattering, as a metric for assessing the maximum radiation prior to inducing structural damage (Howells et al., 2009). By resorting to that estimate [black line in Fig. 2 (bottom)], the doses required for resolving a feature of a given size can be put into perspective. These doses, obtained using Geant4 (Agostinelli et al., 2003) for a DNA feature embedded in a 5 µm water-equivalent cell, are shown as continuous lines. Results resorting to NIST values (Berger et al., 2010) and Hubbell parameterization for (Hubbell et al., 1975) are displayed as dashed lines, highlighting the mutual consistency in this simplified case. Clearly, SCXM can potentially resolve 33 nm-size DNA features inside 5 µm cells, and down to 26 nm if a stable He atmosphere around the target can be provided.
Using equation (3) as a valid metric for inter-comparison between SCXM and coherent scattering is at the moment an open question and will require experimental verification. In particular, the formula assumes implicitly that the energy is released locally. However, a 10 keV photoelectron has a range of up to 2 µm in water, while a 64 keV one can reach 50 µm. An approximate argument can be sketched based on the fact that the average energy of a for 64 keV X-rays (in the range 0–14 keV) is similar to that of a 10 keV photo-electron stemming from 10 keV X-rays, a typical case in coherent diffraction imaging (CDI). Given that at 64 keV most (around 70%) of the energy is released in Compton scatters, the situation in terms of locality will largely resemble that of coherent scattering. Hence, compared with CDI, only about 30% of the energy will be carried away from the interaction region by the energetic 64 keV photoelectrons. On the other hand, at 30 keV (the other energy considered in this study) the photoelectric effect contributes to 90% of the dose, so one can expect a higher dose tolerance for SCXM than the one estimated here.
Naturally, the shielding pipes, the structural materials of the detector, the detector efficiency, the instrumental effects during the reconstruction, and the accuracy of the counting algorithms can limit the achievable resolution, resulting in dose values larger than the ones in Fig. 2. These effects are discussed in the following sections.
2.2. Technical description of the TPC working principle
When X-rays of energies of the order of tens of keV interact in xenon gas at atmospheric pressure, the released photoelectron creates a cloud of (containing thousands of electrons) with a typical (1σ) size of 0.25–1 mm [Fig. 3 (top)]. If the X-ray energy is above that of the xenon K-shell, characteristic emission around 30–34 keV will ensue, in about 70% of the cases. At these energies, X-ray interactions in xenon take place primarily through the photoelectric effect, with just a small (![[\lesssim1\%]](teximages/gy5021fi3.svg)
) probability of Compton scattering.
![[Figure 3]](gy5021fig3thm.gif) | Figure 3 Top (a): ionization distributions in xenon gas, stemming from X-rays interacting in an infinite volume. They are obtained after aligning each X-ray ionization cloud by its barycenter, and projecting it over an arbitrary axis. Calculations from Geant4 are compared with the microscopic code DEGRAD developed by S. Biagi (Biagi, 2020 ). Top (b): probability of in xenon for an incident photon energy of 30 keV (red) and 64 keV (blue), in Geant4. The K-shell (green) and L-shell (orange) lines, as tabulated in Thompson et al. (2001), are shown for comparison. Bottom (a): transverse size of a point-like ionization cluster after drifting along 50 cm, obtained from Magboltz. Bottom (b): longitudinal size of a point-like ionization cluster (in time units), in the same conditions. Results for pure xenon and a fast `counting' mixture based on Xe/CH4 are shown for comparison. |
The ionization clouds (hereafter `clusters') drift, due to the electric field Edrift of the TPC, towards the electroluminescence/anode plane, as shown in Fig. 4 (top), following a diffusion law as a function of the drift distance z,
![[\sigma_{z[x,y]}(z) = D_{\rm{L[T]}}^{*}\sqrt{z}, \eqno(4)]](teximages/gy5021fd4.svg)
where ![[D_{\rm{L}}^{*}]](teximages/gy5021fi4.svg)
and ![[D_{\rm{T}}^{*}]](teximages/gy5021fi5.svg)
are the longitudinal and transverse diffusion coefficients, respectively (McDonald et al., 2019). In fact, diffusion is impractically large in pure noble gases, given that the cooling of ionization electrons is inefficient under elastic collisions only. Addition of molecular additives, enabling vibrational at typical electron energies, is a well established procedure known to improve the situation drastically, and can be accurately simulated with the electron transport codes Magboltz/Pyboltz (Biagi, 1999; Al Atoum et al., 2020). In particular, a small (0.4%) addition of CH4 is sufficient to reduce the cluster size well below that in pure xenon [Fig. 3 (bottom)], as required for An essential ingredient to the use of Xe–CH4 admixtures is the recent demonstration that the signal is still copious in these conditions (Henriques, 2019).2 Hence, for a drift field Edrift = 110 V cm−1, the cluster's longitudinal size can be kept at the σz = 4 mm level even for a 50 cm-long drift, corresponding to a temporal spread of σt = 0.75 µs, while the transverse size approaches σx, y = 10 mm.3 The electron drift velocity is vd = σz/σt = 5 mm µs−1.
![[Figure 4]](gy5021fig4thm.gif) | Figure 4 Top: schematic representation of the working principle of the EL-TPC. Photons scattered at the sample reach the xenon gas, creating ionization clusters that drift, while diffusing, towards the anode plane, where they induce electroluminescence. Bottom: close-up of the electroluminescence region, based on the recently introduced acrylic-based electroluminescence multipliers, developed in collaboration between IGFAE and the CERN-RD51 workshops (González-Díaz et al., 2019 ). |
The proposed detection concept is depicted in Fig. 4 (top), with Fig. 4 (bottom) displaying a close-up of the pixelated readout region, that relies on the recent developments on large-hole acrylic multipliers (González-Díaz et al., 2019). Provided sufficient field focusing can be achieved at the structure, as shown in Fig. 4 (bottom), the ionization clusters will enter a handful of holes, creating a luminous signal in the corresponding silicon photomultiplier (SiPM) situated right underneath, thus functioning, in effect, as a pixelated readout. In summary: (i) X-rays that Compton-scatter at the sample interact with the xenon gas and give rise to clusters of characteristic size somewhere in the range 1–10 mm-σ, depending on the distance to the plane; (ii) given the relatively large X-ray of around 20 cm in xenon at 1 bar, one anticipates a sparse distribution of clusters, that can be conveniently recorded with 10 mm-size pixels/pads, on a readout area of around 2000 cm2 (Npix = 2000).
From the FWHM per X-ray cluster at about mid-chamber: Δx,y|x-ray = ![[(2.35/\sqrt{2})\,\sigma_{x,y}]](teximages/gy5021fi6.svg)
= 16 mm, an average multiplicity M of around 4 per cluster may be assumed if resorting to 10 mm × 10 mm pixels/pads. The temporal spread, on the other hand, can be approximated by: ΔTx-ray = ![[(2.35/\sqrt{2}\,)(\sigma_z/v_{\rm{d}})]](teximages/gy5021fi7.svg)
= 1.35 µs.
Heuristically, by taking as a reference an interaction probability of Pint = 2.9 × 10−4 (5 µm water-equivalent cell, 10 mm of air), a 70% ε, and an m = 20% pixel occupancy, this configuration yields a plausible estimate of the achievable as
![[r_{\rm{max}} = {{1}\over{{\epsilon}P_{\rm{int}}}} \, \left({{N_{\rm{pix}}}\over{M}} \, {{m}\over{\Delta{T}_{\rm{xray}}}}\right) = 3.6\times10^{11}\ ({\rm{photons}}\ {\rm{s}}^{-1}), \eqno(5)]](teximages/gy5021fd5.svg)
compatible a priori with the beam rates for hard X-rays foreseen at the new generation of light sources (Admans et al., 2014). However, in order to have a realistic estimate of the actual counting performance, it is imperative to understand which level of occupancy/pile-up can be really tolerated by the detector, before the photon-counting performance deteriorates above the Poisson limit or proportionality of response is irreparably lost. We address this problem specifically in Section 3.
2.3. Geometry optimization with Geant4
The suitability of the TPC technology for SCXM depends primarily on the ability to detect ∼60 keV photons within a realistic gas volume, in the absence of pressurization. Given that the of 60 keV X-rays in xenon is 20 cm, the most natural 4π-geometry adapting to this case is a hollow cylinder with a of around half a meter. On the other hand, the geometrical acceptance is a function of ![[\arctan(2R_{\rm{i}}/L)]](teximages/gy5021fi8.svg)
, with L being the length and Ri the inner radius of the cylinder. In order to place the sample holder, step motor, optics, pipes and associated mechanics, we leave an Ri = 5 cm inner bore.
Finally, the xenon thickness (Ro − Ri), that is the difference between the outer and inner TPC radii, becomes the main factor for the detector efficiency, as shown in Fig. 5. We discuss two photon energies: 30 and 64 keV. The latter represents the theoretical optimum for SCXM in terms of dose, while the former, sitting just below the K-shell energy of xenon, is a priori more convenient for counting due to the absence of characteristic (K-shell) X-ray re-emission inside the chamber. The is similar for the two energies, therefore no obvious advantage (or disadvantage) can be appreciated in terms of detector efficiency, at this level of realism.
![[Figure 5]](gy5021fig5thm.gif) | Figure 5 Efficiency as a function of the thickness of the xenon cylinder (Ro − Ri) for different lengths, at energies of 30 and 64 keV. The dotted line indicates the benchmark geometry considered in the text, for a length L = 50 cm. |
We consider now a realistic geometry, opting for an inner cylinder shell made out of 0.5 mm-thick aluminium walls, with 2 mm HDPE (high-density polyethylene), 50 µm kapton and 15 µm copper, sufficient for making the field cage of the chamber, that is needed to minimize fringe fields (inset in Fig. 6). The HDPE cylinder can be custom-made and the kapton–copper laminates are commercially available and can be adhered to it by thermal bonding or epoxied, for instance. The external cylinder shell may well have a different design, but it has been kept symmetric for simplicity. We consider in the following a configuration that enables a good compromise in terms of size and flexibility: L = 50 cm and Ro = 25 cm. The geometrical acceptance nears in this case 80%. An additional 10 cm would be typically needed, axially, for instrumenting the readout plane and taking the signal cables out of the chamber, and another 10 cm on the cathode side, for providing sufficient isolation with respect to the vessel, given that the voltage difference will near 10 kV. Although those regions are not discussed here in detail, and have been replaced by simple covers, the reader is referred to Monrabal et al. (2018) for possible arrangements. With these choices, the vessel geometry considered in simulations is shown in Fig. 6, having a weight below 10 kg.
![[Figure 6]](gy5021fig6thm.gif) | Figure 6 (a) TPC geometry in Geant4, aimed at providing nearly 4π-coverage for SCXM. (b) Detail of the region faced by X-rays when entering the detector, that includes the vessel and field cage. (c) Detail of the sample region and the shielding cones. |
The necessary structural material of the walls and the presence of air in the hall reduce the overall efficiency from 62.8% to 58.5% (64 keV) and from 64.5% to 40.0% (30 keV). The beam enters the experimental setup from the vacuum pipes (not included in the figure) into two shielding cones (made of stainless steel and covered with lead shields) and from there into the sample region. Our case study is that of a 33 nm DNA feature inside a 5 µm cell, and 5 mm air to and from the shielding cones. The conical geometry is conceived not to crop the angular acceptance of the X-rays scattered on-sample, providing enough space to the focusing beam, and enabling sufficient absorption of stray X-rays from beam–air interactions along the pipes. In a 4π geometry, as the one proposed here, the cell holder and step motor could be mounted over a rail system, ideally placed along the polarization axis (as provided by standard undulators), where the is lower (Fig. 1). Due to the small focal distance of the MLLs, they should also be placed inside the TPC. The horizontally and vertically focusing MLLs, with slightly different focal lengths, would focus the incident beam to the same spot downstream, where the sample is located, following the so-called `nanoprobe' configuration described by Murray et al. (2019). A simplified sketch of a possible setup is shown in Fig. 7.
![[Figure 7]](gy5021fig7thm.gif) | Figure 7 Sketch of a possible setup for 4π-SCXM (not to scale). The system of rails could be used to move in and out the steel/lead shielding cones, with adequate counter-weight on which wheels or sliders could be attached. Rails would be mechanically fixated to the rigid end-plates of the TPC, at around the TPC mid-plane and outside the active area, where the readout instrumentation is placed. The sample could be mounted on a nano-positioner piezo system, installed over the rail, downstream of the focusing optics, at the position of the image plane, enabling high-precision 3D translations. A slit system would be used to collimate the incident beam and illuminate only the MLLs. The contributions produced by the scattering of photons from the slit system and the focusing optics into the detector, which would reduce the Compton contrast, will be absorbed by the lead shielding cones. The focusing efficiency of the MLLs is high, therefore a minimal contribution from the zero-order (non-diffracted) photons is expected. However, a platinum order-sorting blade could be inserted downstream of the lenses, just before the exit of the shielding cone, if it is shown that further attenuation of the non-diffracted X-ray photons is necessary. |
2.4. Image formation in the TPC
The parameters used for computing the TPC response rely largely on the experience accumulated during the NEXT R&D program. We consider a voltage of −8.5 kV at the cathode and 3 kV across the structure, with the anode sitting at ground, a situation that corresponds to fields around Edrift = 110 V cm−1 and Eel = 6 kV cm−1 in the drift and regions, respectively. The gas consists of Xe/CH4 admixed at 0.4% in volume in order to achieve a 40-fold reduction in cluster size compared with operation in pure xenon [Fig. 3 (bottom)]. The plane will be optically coupled to a SiPM matrix, at the same pitch, forming a pixelated readout. The optical coupling may be typically done with the help of a layer of ITO (indium–tin oxide) and TPB (tetraphenyl butadiene) deposited on an acrylic plate, following Monrabal et al. (2018). This ensures wavelength shifting to the visible band, where SiPMs are usually more sensitive. The number of SiPM photoelectrons per incoming ionization electron, nphe, that is the single most important figure of merit for an EL-TPC, can be computed from the layout in Fig. 4 (bottom), after considering: an Y = 250 photons e−1 cm−1 at Eel = 6 kV cm−1 (González-Díaz et al., 2019), a TPB wavelength-shifting efficiency WLSETPB = 0.4 (Benson et al., 2018), a solid angle coverage at the SiPM plane of ΩSiPM = 0.3 and a SiPM QESiPM = 0.4. Finally, according to measurements by Henriques (2019), the presence of 0.4% CH4 reduces the scintillation probability by Pscin = 0.5, giving, for a h = 5 mm-thick structure,
![[n_{\rm{phe}} = Y \, h \, {\rm{WLSE}}_{\rm{TPB}} \, \Omega_{\rm{SiPM}} \, {\rm{QE}}_{\rm{SiPM}} \, P_{\rm{scin}} \,=\, 3. \eqno(6)]](teximages/gy5021fd6.svg)
Since the energy needed to create an electron–ion pair in xenon is WI = 22 eV, each 30–64 keV X-ray interaction will give rise to a luminous signal worth 4000–9000 photoelectrons (phe), spanning over 4–8 pixels, hence well above the SiPM noise. The energy resolution (FWHM) is obtained from Henriques (2019) as
![[\eqalignno{ {\cal R}(\varepsilon\!=\!64\,{\rm{keV}}) & \,\simeq\, 2.355\left[F+{{1}\over{n_{\rm{phe}}}} \left(1+{{\sigma_{G}^{2}}\over{G^{2}}}\right)\right]^{1/2} \left({{{W_{\rm{I}}}\over{\varepsilon}}}\right)^{1/2} \cr& \,=\, 3.1\%, &(7)}]](teximages/gy5021fd7.svg)
with σG/G being the width of the single-photon distribution (around 0.1 for a typical SiPM) and F ≃ 0.17 the Fano factor of xenon. For comparison, a value compatible with ![[{\cal R}(\varepsilon\!=\!64\,{\rm{keV}})]](teximages/gy5021fi9.svg)
= 5.5% was measured for acrylic hole multipliers by González-Díaz et al. (2019). In present simulations, the contribution of the energy resolution has been included as a Gaussian smearing in the TPC response.
Finally, the time response function of the SiPM is included as a Gaussian with a 7 ns width, convoluted with the transit time of the electrons through the structure ΔTEL = 0.36 µs, being both much smaller in any case than the typical temporal spread of the clusters (dominated by diffusion). The is taken to be ΔTs = 0.5 µs as in Monrabal et al. (2018), and a matrix of 1800 10 mm-pitch SiPMs is assumed for the readout. Images are formed after applying a 10 phe-threshold to all SiPMs.
A fully processed TPC image for one time slice (ΔTs = 0.5 µs), obtained at a beam rate of r = 3.7 × 1010 photons s−1 for a photon energy ɛ = 64 keV, is shown in Fig. 8. The main clusters have been marked with crosses, by resorting to `Monte Carlo truth', i.e. they represent the barycenter of each primary ionization cluster in Geant4. The beam has been assumed to be continuous, polarized along the x-axis, impinging on a 5 µm water cube surrounded by air, with a 33 nm DNA cubic feature placed at its centre. The Geant4 simulations are performed at fixed time, and the X-ray interaction times are subsequently distributed uniformly within the dwell time corresponding to each position of the scan. It must be noted that interactions taking place at about the same time may be recorded at different times depending on the z-position of each interaction (and vice versa, clusters originating at different interaction times may eventually be reconstructed in the same time slice). This scrambling (unusual under typical TPC operation) renders every time slice equivalent for the purpose of counting. In principle, the absolute time and z position can be disambiguated from the size of the cluster, using the diffusion relation in equation (4), thus allowing photon-by-photon reconstruction in time, space and energy. A demonstration of the strong correlation between z-position and cluster width, for 30 keV X-ray interactions, can be found in González-Díaz et al. (2015) for instance.
![[Figure 8]](gy5021fig8thm.gif) | Figure 8 A typical TPC image reconstructed from the SiPM signals (in phe), as recorded in one time-slice (ΔTs = 0.5 µs), for a beam rate of r = 3.7 × 1010 s−1. The crosses show the clusters' centroids, obtained from `MC-truth' information. |
The design parameters used in this subsection are compiled in Tables 2–5 of Appendix B.
3. Photon-counting capabilities
3.1. Ideal counting limit
The attenuation in the structural materials, re-scatters, characteristic emission, as well as the detector inefficiency, are unavoidable limiting factors for counting. These intrinsic limitations can be conveniently evaluated from the signal-to-noise ratio (S/N), defined from the relative spread in the number of ionization clusters per scan step (see Fig. 2), as obtained by the Monte Carlo method (nMC),
![[{\rm{S/N}} = n_{\rm{MC}}/\sigma_{n_{\rm{MC}}}. \eqno(8)]](teximages/gy5021fd8.svg)
Figure 9 shows the deterioration of the S/N for 64 keV photons, as the realism of the detector increases. It has been normalized to the relative spread in the number of photons scattered on-sample per scan step, ![[\sqrt{N_0^{\vphantom{^{a}}}}]](teximages/gy5021fi10.svg)
, so that it equals 1 for a perfect detector (see Appendix A),
![[{\rm{S/N}}^{*} \,\equiv\, {{1}\over{\sqrt{N_{0}^{\vphantom{^{a}}}}}}\,{\rm{S/N}}. \eqno(9)]](teximages/gy5021fd9.svg)
The figure also shows S/N* in `calorimetric mode', with the counting performed by simply integrating the total collected light per scan step (ɛtot), instead of photon-by-photon. S/N* is defined in that case, equivalently, as S/N* = ![[(\varepsilon_{\rm{tot}}/\sigma_{\varepsilon_{\rm{tot}}})/\sqrt{N_{0}^{\vphantom{^{a}}}}]](teximages/gy5021fi11.svg)
. The values obtained are just slightly below the ones expected considering detector inefficiency alone (see Appendix A),
![[{\rm{S/N}}^{*} \,\simeq\, \sqrt{\epsilon}, \eqno(10)]](teximages/gy5021fd10.svg)
therefore suggesting a small contribution from re-scatters in the materials or other secondary processes.
![[Figure 9]](gy5021fig9thm.gif) | Figure 9 Intrinsic counting performance (using Monte Carlo truth information) for 64 keV X-ray photons, characterized by the signal-to-noise ratio (relative to case 0). Photon-counting (green) and calorimetric mode (red) are displayed as a function of the realism of the simulations. |
3.2. Real counting
Given the nature of the detector data (Fig. 8), consisting of voxelized ionization clusters grouped forming ellipsoidal shapes, generally separable, and of similar size, we select the K-means clustering method (MacQueen, 1967) to perform cluster counting. The counting algorithm has been implemented as follows:
(i) The `countable' clusters are first identified time-slice by time-slice using Monte Carlo truth information, as those producing a signal above a certain (ɛth) in that slice. The is chosen to be much lower than the typical cluster energies. In this manner, only small clusters are left out of the counting process when most of their energy is collected in adjacent time-slices from which charge has spread out due to diffusion, and where they will be properly counted once the algorithm is applied there.
(ii) A weighted inertia (I) distribution is formed, as conventionally done in K-means, and a threshold (δIth) is set to the variation of the inertia with the number of clusters counted by the algorithm (n) (Fig. 10). The threshold is optimized for each beam rate condition. We concentrate on beam rates for which the average efficiency and purity of the cluster identification in 2D slides is larger than 80%, as the ones illustratively depicted in Fig. 11. The and purity can be used as evaluation criteria for cluster assignment quality. is defined as the number of correctly assigned clusters, nmatched, divided by the total number of true (or MC) clusters, nMC, while purity is defined as the number of correctly assigned clusters divided by the clusters counted by the algorithm n. Thus, bad clustering has purity (and efficiency) values close to 0, while a perfect clustering has a purity (and efficiency) of 1,
![[\epsilon_{\rm{counting}} = {{ n_{\rm{matched}} }\over{ n_{\rm{MC}} }}, \eqno(11)]](teximages/gy5021fd11.svg)
![[p_{\rm{counting}} = {{ n_{\rm{matched}} }\over{ n }}. \eqno(12)]](teximages/gy5021fd12.svg)
The K-means optimization parameters have been chosen to simultaneously maximize the while achieving n ≃ nMC, therefore εcounting ≃ pcounting.
![[Figure 10]](gy5021fig10thm.gif) | Figure 10 The K-means cluster-counting algorithm evaluates the partition of N observations (voxelized ionization clusters in our case) in n clusters, so as to minimize the inertia I, defined as the sum of the squared distances of the observations to their closest cluster centre. In the plot: convergence of K-means for a beam rate of 1011 photons s−1. A Savitzky–Golay filter is applied for the purpose of smoothing the variation of the inertia δI. |
![[Figure 11]](gy5021fig11thm.gif) | Figure 11 Cluster counting performance for typical ΔTs = 0.5 µs time-slices, for different energies (ɛ) and beam rates (r). Crosses indicate the cluster centroids from MC and circles are the clusters found by K-means. The average counting-efficiency and purity along the detector are given below in brackets. Top left: ɛ = 64 keV and r = 3.7 × 1010 photons s−1 (εcounting = 88.2%, pcounting = 86.9%). Top right: ɛ = 64 keV and r = 7.5 × 1010 photons s−1 (εcounting = 84.2%, pcounting = 83.2%). Bottom left: ɛ = 30 keV and r = 6.5 × 1010 photons s−1 (εcounting = 87.9%, pcounting = 87.5%). Bottom right: ɛ = 30 keV and r = 1.3 × 1011 photons s−1 (εcounting = 83.9%, pcounting = 83.1%). For ɛ = 30 keV only about half of the clusters are produced, which enables measuring at higher beam rates than ɛ = 64 keV, at comparable efficiency and purity. |
Figure 12 (top) shows the performance of the counting algorithm, presenting the average number of clusters counted per 2D slice as a function of beam rate, with ɛth and δIth optimized for each case as described above (green line). Red lines indicate the predictions outside the optimized case, that illustrate the consistent loss of linearity as the beam rate increases. Figure 12 (bottom) shows the relative spread in the number of counted clusters σn/n, and comparison with Monte Carlo truth. These results can be qualitatively understood if recalling that, by construction, the threshold inertia is strongly correlated with the average number of clusters and its size. Therefore, a simple K-means algorithm will inevitably bias the number of counted clusters to match its expectation on I, if no further considerations are made. Therefore, once δIth has been adjusted to a certain beam rate, there will be systematic overcounting for lower beam rates, and undercounting for higher ones, as reflected by Fig. 12 (top). In present conditions, a second-order polynomial is sufficient to capture this departure from proportionality introduced by the algorithm. A similar (although subtler) effect takes place for the cluster distributions obtained slice-by-slice, where this systematic overcounting–undercounting effect makes the cluster distribution marginally (although systematically) narrower, as seen in Fig. 12 (bottom). As a consequence, the directly related magnitude S/N* [equations (8) and (9)] is not deteriorated by the counting algorithm. On the other hand, proportionality is lost, and its impact needs to be addressed, depending on the application. The particular case of SCXM is scrutinized in the next section.
![[Figure 12]](gy5021fig12thm.gif) | Figure 12 Top: counting performance characterized through the average number of clusters counted per 2D time-slice as a function of the beam rate for ɛ = 64 keV. Bottom: relative spread of the number of clusters per 2D time-slice from Monte Carlo truth and counted with K-means. The ![[1/\sqrt{r}]](teximages/gy5021fi16.svg) expectation (dashed) is shown for comparison. |
Finally, the photon-counting efficiency [equation (11)] can be assessed through Fig. 13 (top), where it is displayed as a function of the beam rate on target. It can be seen how, for the case of 30 and 64 keV photons, its value exceeds 85% for rates up to 1011 photons s−1 and 0.5 × 1011 photons s−1, respectively. At these high beam rates, counting capability suffers from event pile-up while, at low beam rates, it is limited by the presence of low-energy deposits (corresponding to X-ray interactions for which most of the energy is collected in adjacent slices). It must be recalled, at this point, that a complete reconstruction requires combining 2D time-slices as the ones studied here, in order to unambiguously identify clusters in 3D. Given that each cluster extends over 4–6 slices due to diffusion, and clusters are highly uncorrelated, a 3D well above 90% can be anticipated in the above conditions.
![[Figure 13]](gy5021fig13thm.gif) | Figure 13 Top: efficiency of the cluster counting process as a function of the beam rate for X-rays of 30 and 64 keV. Bottom: time to reach the dose-limited resolution as a function of the beam rate. A minimum is reached when the product Cl 2×r reaches a maximum, i.e. the time decreases with beam rate until the effect of the non-proportional counting (resulting from event pile-up) becomes dominant. The optimum beam rate and corresponding are marked with a dotted line for both energies. |
4. Projections for SCXM
We propose the characterization of the EL-TPC technology in light of its performance as a cellular microscope, through the study of the smallest resolvable DNA-feature (size d) as a function of the scan time (ΔTscan). Justification of the following derivations can be found in Appendix A, starting with
![[d = \left[ R^{2}\,2l^{\,2} \, {{ (l\lambda_{w}^{-1}+2a\lambda_{a}^{-1}) }\over{ (\lambda_{f}^{-1}-\lambda_{w}^{-1})^{2}}} \, {{ 1 }\over{ C_{l}(r)^{2}\,{\rm{S/N}}^{*2}\,r\,\Delta{T}_{\rm{scan}} }} \right]^{1/4}. \eqno(13)]](teximages/gy5021fd13.svg)
Here R equals 5 under the Rose criterion and the rate-dependent coefficient Cl < 1 depends on the deviation of the counting algorithm from the proportional response, its expression being given in Appendix A. Other magnitudes have already been defined. Since the smallest resolvable feature size (d†) is ultimately determined by the dose imparted at it when structural damage arises [equation (3), Fig. 2], the necessary scan time to achieve such performance (![[\Delta{T}_{\rm{scan}}^{\,\dagger}]](teximages/gy5021fi12.svg)
) can be readily obtained,
![[\Delta{T}_{\rm{scan}}^{\,\dagger} = R^{2}\,2l^{\,2} \, {{ (l\lambda_{w}^{-1}+2a\lambda_{a}^{-1}) }\over{ (\lambda_{f}^{-1}-\lambda_{w}^{-1})^{2} }} \, {{ 1 }\over{ C_{l}(r)^{2} \,\, {\rm{S/N}}^{*2} \, r \,(d^{\dagger})^{4} }}. \eqno(14)]](teximages/gy5021fd14.svg)
For a detector with finite efficiency, the value of d† can be recalculated by simply accounting for the necessary increase in fluence (and hence in dose), as
![[\phi \,\rightarrow\, \phi^{\,\prime} = \phi/\epsilon, \eqno(15)]](teximages/gy5021fd15.svg)
![[{\cal D} \,\rightarrow\, {\cal D}^{\,\prime} = {\cal D}/\epsilon, \eqno(16)]](teximages/gy5021fd16.svg)
that results in slightly deteriorated values compared with Fig. 2: d† = 36 nm instead of d† = 33 nm for ɛ = 64 keV, and d† = 44 nm instead of d† = 37 nm for ɛ = 30 keV.
The limiting scan time (i.e. above which structural damage will appear) can be hence assessed from the behaviour of equation (14) with beam rate, as shown in Fig. 13 (bottom). For 64 keV, the loss of linearity of the counting algorithm at high rates results in a turning point at 9.3 × 1010 photons s−1, above which an increase in rate stops improving the ability to resolve an image. For 30 keV, due to the absence of characteristic emission, only about half of the clusters are produced and the optimum rate is found at a higher value, r = 1.6 × 1011. The and purity in these conditions is in the range 82–84%.
It is now possible to evaluate equation (13) under different scenarios: (i) a relatively simple calorimetric mode (total energy is integrated), for which we assume a hard X-ray beam rate typical of the new generation of synchrotron light sources as r = 1012 photons s−1, and (ii) a rate-limited photon-by-photon counting scenario, for the optimum rates r = 9.3 × 1010 photons s−1 (64 keV) and r = 1.6 × 1011 photons s−1 (30 keV), obtained above. Values for Cl(r) are extracted from second-order fits as discussed in Appendix A. The remaining parameters are common to both modes: S/N* = 0.71, efficiency ![[\epsilon]](teximages/gy5021fi13.svg)
= 58.5% (64 keV), S/N* = 0.63, = 40.0% (30 keV); finally we assume l = 5 µm, a = 5 mm, R = 5, with the mean free paths (λ) taken from Table 1. Results are summarized in Fig. 14. At 64 keV, the dose-limited resolution d† = 36 nm can be achieved in approximately 24 h while, at 30 keV, d† = 44 nm is reached in just 8 h. In the absence of systematic effects, operation in calorimetric mode would bring the scan time down to ≤1 h in both cases, although abandoning any photon-by-photon counting capabilities.
![[Figure 14]](gy5021fig14thm.gif) | Figure 14 Resolution achievable with a 64 keV photon beam (left) and a 30 keV photon beam (right) as a function of the scan time for a cell of 5 µm (green line). The red line shows the limit in which a calorimetric measurement is performed and photon-by-photon counting is abandoned. The horizontal line shows the dose-limited resolution in each case, prior to inducing structural damage. |
5. Discussion
The results presented here illustrate the potential of the proposed technology for high-energy X-ray detection (up to ∼60–70 keV) at high-brightness synchrotron light sources, in particular for cellular imaging. In deriving them, we have adopted some simplifications, that should be superseded in future work, and are analyzed here:
(i) Availability of photon-by-photon information. Cluster reconstruction with high efficiency and purity enables x, y, t + tdrift and ɛ determination, and arguably the interaction time t and z position can be obtained from the study of the cluster size, as it has been demonstrated for 30 keV X-rays at near-atmospheric pressure before (González-Díaz et al., 2015). This can help at removing backgrounds not accounted for, as well as any undesired systematic effect (beam or detector related). Since this technique provides a parallax-free measurement, the concept may be extended to other applications, e.g. X-ray crystallography. The presence of characteristic emission from xenon will unavoidably create confusion, so if unambiguous correspondence between the ionization cluster and the parent X-ray is needed, one must consider operation at ∼30 keV.
(ii) Data processing and realism. Performing photon-by-photon counting at a rate nearing 5 × 107 photons s−1 over the detector (≡ 1011 photons s−1 over the sample), as proposed here, is a computer intensive task, that will require high transfer rates too. Despite the relatively high the pixel occupancy is about 20% only, in the most extreme conditions considered, so zero-suppression of data before streaming is necessary. In that case, if assuming about 10 bits per 3D energy-voxel, a pixel multiplicity of 4 (Δx,y|x-ray = 16 mm, pixel size = 10 mm), and about four time bins per photon (ΔTx-ray = 1.35 µs, ΔTs = 0.5 µs), a transfer rate of about 8 Gb s−1 can be inferred. This is in the order of the typical data rates of Gb s−1 produced in tomography experiments, for which gigabit-fast readout systems have been developed (Mokso et al., 2017).
Optimizing the counting algorithm and its speed will need to be accomplished, ultimately, with real data. To this aim, the availability of parallel processing (for groups of time-slices, for instance) as well as the possibility of simultaneous operation in calorimetric mode are desirable features. In stable detector and beam conditions, a calorimetric measurement will suffice for counting. This will be studied in the near future through a dedicated experiment.
(iii) Simplicity and compactness. The detector geometry proposed here has been conceived as a multi-purpose permanent station. A portable device, however, could simply consist of a cubic 25 cm × 25 cm × 25 cm vessel that may be positioned, e.g. on top of the sample (at a distance of about ∼5 cm). The geometry would thus have an overall efficiency around 30% for 64 keV photons. For SCXM, and given that S/N* ≃ ![[\sqrt{\epsilon}]](teximages/gy5021fi15.svg)
as shown in this work, a loss of efficiency can be almost fully compensated by means of the corresponding increase in beam rate, at the price of a deteriorated value for the dose limited resolution d†. In this case, a value corresponding to d† = 41 nm could be achieved in 12 h, for our test study.
(iv) Feasibility. The proposed technology comes from the realm of high-energy physics, with an inherent operational complexity. On the one hand, the necessary high voltage and purity levels have been demonstrated in NEXT-DEMO (Álvarez et al., 2013), that operates at 10 bar, conditions for which the technical specifications are much harsher than for the proposed detector (×10 higher operating voltage, ×100 less O2 contamination). On the other hand, adapting the SiPM readout seems to present some additional difficulties, related to design, prototyping and testing, needed to produce a rugged and stable readout structure, besides the need to develop waveform processing algorithms as well as a customized data acquisition system. While it is possible to build on the existing NEXT experience, it seems just timely to consider an alternative that largely simplifies the above aspects, by resorting to ultra-fast (1.6 ns resolution) hit-based TimePix cameras (e.g. Amsterdam Scientific Instruments, 2019; Nomerotski, 2019). The camera would be coupled to a suitable VUV lens so a larger scintillating area can be fully imaged in small sensor, allowing 256 × 256 pixel readout at 80 Mhits s−1, more than sufficient for this application. Large-volume optical TPCs have been read out with this concept already in ARIADNE (Lowe et al., 2020). The vessel would just house, in such a case, the acrylic hole multiplier and cathode mesh, together with the power leads; it would be filled with the xenon mixture at atmospheric pressure and interfaced to the outside with a VUV-grade viewport. This would compromise partly the ability to disentangle clusters by using time information, as well as energy information, since only the time over threshold would be stored and not the temporal shape of each cluster, or its energy. On the other hand, it would enhance the spatial information by a factor of 30 relative to the SiPM matrix proposed here (the hole pitch of the acrylic hole multiplier should be reduced accordingly). Indeed, TimePix cameras are regularly used nowadays for photon- and ion-counting applications (Hirvonen et al., 2017; Fisher-Levine et al., 2018), but have not been applied to X-ray counting yet, to the best of our knowledge. The counting and signal processing algorithms could be in this way directly ported, given the similarity with the images taken in those applications. The readiness of such an approach, aiming at immediate implementation, represents an attractive and compelling avenue.
The imaging criterion and study case chosen in this work are inspired by Villanueva-Perez et al. (2018), where a dose-limited resolution of 34 nm was obtained for SCXM, compared with around 75 nm for CDI. A typical biomolecule feature was chosen, embedded in a 5 µm cell placed in vacuum. The present study shows that a 36 nm DNA feature can be resolved in similar conditions even after accounting for the presence of beam-shielding, air, photon transport through a realistic detector, including the detector response in detail, and finally implementing photon-counting through a K-means algorithm.
6. Conclusions and outlook
We introduce a new 4π-technology (EL-TPC) designed for detecting ∼60 keV X-ray photons at rates up to 5 × 107 photons s−1 over the detector (1011 photons s−1 over the sample), with an overall (including geometrical acceptance) around 60%. At these rates, photon-by-photon counting can be achieved at an efficiency and purity above 80%, and plausibly well above 90% after straightforward improvements on the counting algorithm employed in this work. The technology has been re-purposed from its original goal in particle physics (the experimental measurement of ββ0ν decay) and, with a number of simplifications, it has been optimally adapted to the task of Compton X-ray microscopy in upcoming light sources. The proposed detector can be used either as a permanent station or a portable device. In the latter case, it is possible to combine Compton detection with other modalities, e.g. X-ray diffraction measurements in the forward direction and perpendicular to the beam, where Compton scattering is minimal.
Concentrating on 5 µm cells as our test case, we estimate that, under the Rose imaging criterion, and assuming the dose fractionation theorem, 36 nm DNA features may be resolved in 24 h by using a permanent station, and 41 nm in 12 h with a portable device. Alternatively, the scan time could be brought down to less than 1 h by resorting to the calorimetric mode, although the photon-by-photon counting capability would need to be abandoned. Our analysis includes detailed Geant4 transport, a realistic detector response and a simplified 2D-counting algorithm based on K-means. Thus, the obtained rate capability (and scan time) should be understood as lower (upper) limits to the actual capabilities when using more refined 3D-algorithms, including constraints in energy and cluster size.
Although substantially below the nominal photon-counting capabilities of solid-state pixelated detectors, we believe that a number of applications could benefit from the proposed development, targeting specifically at the newly available fourth-generation synchrotron light sources, capable of providing high-brightness hard X-rays. Indeed, previous conceptual studies point to about a factor of two increase in for SCXM compared with CDI, in similar conditions to ours. The present simulation work just comes to support the fact that a complete 3D scan would be realizable in about 24 h time, under realistic assumptions on the experimental setup, detector response and counting algorithms.
APPENDIX A
Relation between resolution and scan time
A1. Proportional (ideal) case
We start from the imaging criterion, applied to an arbitrary position of the step motor within a cell-scan,
![[{{|N_{f}-N_{0}|} \over {\left({\sigma_{N_{f}}^{2}+\sigma_{N_{0}}^{2}} \right)^{1/2}}} \,=\, R, \eqno(17)]](teximages/gy5021fd17.svg)
where R = 5 corresponds to the Rose condition. Nf is the number of scattered photons from a water medium with a `to-be-resolved' feature inside it, and N0 contains only water, instead [see Fig. 2 (top)]. This equation can be re-expressed as
![[{{|N_{f}-N_{0}|} \over {\left[{N_{f}^{2}\left({{\sigma_{N_{f}}}/{N_{f}}}\right)^ {2}\,\,+\,\,N_{0}^{2}\left({{\sigma_{N_{0}}}/{N_{0}}}\right)^{2}} \right]^{1/2}}} \,=\, R, \eqno(18)]](teximages/gy5021fd18.svg)
that, under the assumption Nf ≳ N0, and defining the signal-to-noise ratio as S/N ![[\equiv]](teximages/gy5021fi21.svg)
![[N_{f}/\sigma_{N_{f}}]](teximages/gy5021fi22.svg)
≃ ![[N_{0}/\sigma_{N_{0}}]](teximages/gy5021fi23.svg)
can be rewritten, in general, as
![[{{1} \over {\sqrt{2}}} \, {{N_{f}-N_{0}}\over{N_{0}}} \,\, {\rm{S/N}} \,=\, R. \eqno(19)]](teximages/gy5021fd19.svg)
When considering it is understood that a relation can be established between the distribution of ionization clusters that are counted in the detector (mean n, standard deviation σn) and the distribution of scattered photons (mean Nf ≃ N0, standard deviation ![[\sigma_{N_{f}}]](teximages/gy5021fi24.svg)
≃ ![[\sigma_{N_{0}}]](teximages/gy5021fi25.svg)
). If resorting to an unbiased counting algorithm, this relation will be proportional. In that case, the pre-factors on the left-hand-side of equation (19) remain, and any detector-related effect is contained in the quantity
![[{\rm{S/N}} = {{N_{f}} \over {\sigma_{N_{f}}}} \,\simeq\, {{N_{0}}\over{\sigma_{N_{0}}}} \,\rightarrow\, {{n}\over{\sigma_{n}}}. \eqno(20)]](teximages/gy5021fd20.svg)
At fixed number of scattered photons (≃ N0) the relative fluctuations in the number of counted clusters will increase due to efficiency losses, characteristic emission, and re-scatters on the cell itself, air or structural materials, thereby resulting in a loss of signal-to-noise. It is convenient to normalize this definition to the Poisson limit for a perfect detector,
![[{\rm{S/N}}^{*} = {{1}\over{\sqrt{N_{0}^{\vphantom{b}}}}}\,\,{\rm{S/N}} \eqno(21)]](teximages/gy5021fd21.svg)
and so the new quantity S/N* is now defined between 0 and 1, with S/N = n/σn obtained, in the main document, from detailed simulations of the photon propagation through the experimental setup. Substitution of Nf and N0 by physical quantities in equation (19) yields
![[{{1}\over{\sqrt{2}}} \, {{d(\lambda_{f}^{-1}-\lambda_{w}^{-1})}\over{l\lambda_{w}^{-1}+2a\lambda_{a}^{-1}}} \,\, {\rm{S/N}}^{*} \, \sqrt{N_{0}} \,=\, R, \eqno(22)]](teximages/gy5021fd22.svg)
with d being the feature size, l the cell dimension, and λf,w,a the mean free paths in the feature, water and air, respectively, as defined in the text.
Now, we make use of the fact that N0 = ![[r\,\Delta{T_{\rm{step}}}(l\lambda_{w}^{-1}+2a\lambda_{a}^{-1})]](teximages/gy5021fi27.svg)
, with r being the beam rate, ΔTstep a time step within the scan, and ΔTscan the total time for a 2D scan: ![[\Delta{T_{\rm{scan}}}]](teximages/gy5021fi28.svg)
= ![[\left({{l}/{d}}\right)^{2}\Delta{T_{\rm{step}}}]](teximages/gy5021fi29.svg)
. By replacing N0 in the previous equation we obtain
![[{{1}\over{\sqrt{2}}} \, {{d^{2}(\lambda_{f}^{-1}-\lambda_{w}^{-1})}\over{l(l\lambda_{w}^{-1}+2a\lambda_{a}^{-1})^{1/2}}} \,\, {\rm{S/N}}^{*} \, \left({r\Delta{T_{\rm{scan}}}}\right)^{1/2} \,=\, R, \eqno(23)]](teximages/gy5021fd23.svg)
from which the time needed for a complete 2D scan can be expressed as
![[\Delta{T_{\rm{scan}}} = R^{2} \, {{2l^{\,2}}\over{d^{4}}} {{(l\lambda_{w}^{-1}+2a\lambda_{a}^{-1})}\over{(\lambda_{f}^{-1}-\lambda_{w}^{-1})^{2}}} {{1}\over{{\rm{S/N}}^{*2}\,r}}, \eqno(24)]](teximages/gy5021fd24.svg)
and, solving for d,
![[d = \left[ R^{2}2l^{\,2} \, {{(l\lambda_{w}^{-1}+2a\lambda_{a}^{-1})}\over{(\lambda_{f}^{-1}-\lambda_{w}^{-1})^{2}}} \, {{1}\over{{\rm{S/N}}^{*2} \, r \, \Delta{T}_{\rm{scan}}}} \right]^{1/4}. \eqno(25)]](teximages/gy5021fd25.svg)
Expression (25) can be approximated under the simplifying assumption that S/N* is mainly limited by Poisson statistics and by the efficiency of the detector (modelled through a simple binomial distribution), disregarding production of secondary particles or re-scatters across structural materials, hence
![[{\rm{S/N}}^{*} = {{1}\over{\sqrt{N_{0}^{\vphantom{b}}}}}{{n} \over {\sigma_{n}}} \simeq {{1}\over{\sqrt{N_{0}^{\vphantom{b}}}}} \, {{N_{0}\epsilon} \over {\left[{\epsilon^{2}N_{0}+\epsilon(1-\epsilon)N_{0}} \right]^{1/2}}} = \sqrt{\epsilon}, \eqno(26)]](teximages/gy5021fd26.svg)
from which it can be seen that detector efficiency and beam rate enter as a product in the denominator in formulas (24) and (25). Consequently, detector inefficiency increases the scan time linearly, as intuitively expected.
A2. Non-proportional case
We consider now the more realistic case where there is a non-proportional response of the counting algorithm. This is characterized, for the K-means algorithm implemented in the text, as a second-order polynomial (Fig. 11),
![[n = a+br+cr^{2}. \eqno(27)]](teximages/gy5021fd27.svg)
By analogy, if the K-means parameters are optimized for a certain beam rate, r, the response to cell regions causing a different number of scattered photons N, relative to the water-only case, will be
![[n = a+b\,{{N}\over{N_{0}}}+c\,\left({{N}\over{N_{0}}}\right)^{2}, \eqno(28)]](teximages/gy5021fd28.svg)
and a(r), b(r), c(r) are now rate-dependent. Equation (19) should be rewritten, accordingly, as
![[{{1}\over{\sqrt{2}}} \, {{n_{f}-n_{0}}\over{n_{0}}} \,\, {\rm{S/N}} = R, \eqno(29)]](teximages/gy5021fd29.svg)
and the relative variation in n becomes
![[{{n_{f}-n_{0}}\over{n_{0}}} = {{1}\over{a+b+c}} \, \left(b\,{{N_{f}-N_{0}}\over{N_{0}}} + c\,{{N_{f}^{\,2}-N_{0}^{\,2}}\over{N_{0}^{\,2}}}\right), \eqno(30)]](teximages/gy5021fd30.svg)
that, for Nf ≃ N0, can be re-expressed as
![[{{n_{f}-n_{0}}\over{n_{0}}} \,=\, C_{l}(r) \, {{N_{f}-N_{0}}\over{N_{0}}}, \eqno(31)]](teximages/gy5021fd31.svg)
with Cl(r) = (b+2c)/(a+b+c). Hence, a loss of linearity during the counting process enters linearly in equation (19). The general expression for the resolvable feature size as a function of the beam rate is, finally, by analogy with equation (25),
![[d = \left(R^{2}2l^{\,2} \, {{(l\lambda_{w}^{-1}+2a\lambda_{a}^{-1})}\over{(\lambda_{f}^{-1}-\lambda_{w}^{-1})^{2}}} \, {{1}\over{C_{l}(r)^{2} \,\, {\rm{S/N}}^{*2} \, r \, \Delta{T}_{\rm{scan}}}}\right)^{1/4}, \eqno(32)]](teximages/gy5021fd32.svg)
that is the expression used in the main document, for the achievable resolution as a function of the scan time, under a given imaging criterion R. The detector response enters this final expression in three ways:
(i) Through the increased fluctuation in the number of detected clusters, relative to the ideal (Poisson) counting limit, characterized through the signal-to-noise ratio, S/N*.
(ii) The non-linearity of the counting algorithm, Cl.
(iii) The assumed maximum operating rate, r, for which the product Cl 2 r reaches a maximum, as for larger rates stops improving the ability to resolve an image.
APPENDIX B
EL-TPC parameters
In Tables 2, 3, 4 and 5 we compile the main parameters used for the simulation of the TPC response, together with additional references when needed.
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![[\Delta{T}_{\rm{s}}]](teximages/gy5021fi20.svg)
Footnotes
1A non-zero value of F stems from the the intrinsic spread of primary ionization, as the partition of energy between excitations and ionizations changes event by event.
2This unanticipated result, that might not look significant at first glance, results from a very subtle balance between the quenching of the xenon and the cooling of drifting electrons through inelastic collisions (Azevedo et al., 2018).
3In the following we use σx,y,z,t to refer to the cluster width arising from diffusion after L = 50 cm drift.
Acknowledgements
We thank Ben Jones and David Nygren (University of Texas at Arlington), as well as our RD51 colleagues for stimulating discussions and encouragement, and specially to David José Fernández, Pablo Amedo, and Pablo Ameijeiras for discussions on the K-means method, and Damián García Castro for performing the Magboltz simulations.
Funding information
A. Saá Hernández is funded through the project ED431F 2017/10 (Xunta de Galicia) and D. González-Díaz through the Ramon y Cajal program, contract RYC-2015-18820. C. D. R. Azevedo is supported by Portuguese national funds (OE), through FCT - Fundação para a Ciência e a Tecnologia, IP, in the scope of the Law 57/2017, of 19 July.
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