As Crab Nebula sets behind or rises from the limb of Earth as seen by Insight-HXMT, the X-ray flux from the Crab Nebula detected by Insight-HXMT varies due to the absorption of X-ray photons by Earth's atmosphere. The observation geometry of the X-ray Earth occultation of the Crab Nebula with Insight-HXMT is shown in Fig. . In the process of the X-ray Earth occultation, the atmosphere reduces the flux of the X-rays detected by Insight-HXMT. As the line of sight moves closer to the Earth's surface (setting), more X-ray photons are absorbed by the atmosphere, and vice versa.

The observation data of the low-energy X-ray telescope (LE) are used in this study. We select the photons observed by detectors for LE because the extinction effect at a lower energy band during the occultation is obvious due to the larger cross section of the Earth's upper atmospheric compositions (Fig. ). LE consists of three detector boxes each containing 32 pieces of CCD236 , which is the second-generation swept charge device (SCD) designed for X-ray spectroscopy . The collimators divide each detector box of LE into four kinds of fields of view (FOV). For each detector box, 20 CCD236 devices have small FOVs of 1.6∘ × 6∘, 6 CCD236 devices have wide FOVs of 4∘ × 6∘, 2 CCD236 devices are blind FOVs, and 4 CCD236 devices have large FOVs of about 50–60∘ × 2–6∘ . The detector response matrix is generated through the calibration database hxmt CALDB (v2.05) (http://hxmtweb.ihep.ac.cn/caldb/628.jhtml, last access: 7 May 2022). Only observations from the small FOV detectors, excluding the detectors with ID 29 and 87 that are damaged, are used for analysis in order to get an accurate background in this paper.

The information of the observation data selected in the data reduction is listed in Table , including the observation ID, the start and end time of the observation, the target source, and the right ascension and declination of the source in the coordinate system J2000. In the data reduction process, using HXMTsoft(v2.04) (http://hxmtweb.ihep.ac.cn/software.jhtml, last access: 7 May 2022), we extract the light curves and spectra of the Crab Nebula during Earth occultation recorded with LE. For the LE instrument, the photon counts are recorded by CCD236 detectors. Since we mainly study the occultation process of the Crab Nebula by the Earth atmosphere, the good time interval is screened by the following criteria: ELV (the elevation of the pointing direction above the horizon) less than 10∘.

The comparison of the X-ray energy spectra during the occultation process is shown in Fig. . Five X-ray spectra in different altitude ranges are shown for clarity. These five energy spectra in blue, red, orange, magenta, and green in Fig.  are derived from the results of subsamples at altitudes of 160–170, 120–130, 100–110, 90–100, and below 70 km, starting from an unattenuated energy spectrum to the partially attenuated energy spectrum and ending with a fully attenuated energy spectrum. It is shown that the flux of the X-ray energy spectrum attenuates with reducing tangent point altitude during the occultation. Moreover, the absorption of X-ray photons by the atmosphere decreases with increasing energy.

In the process of X-ray Earth occultation of the Crab Nebula, the Crab Nebula and Earth's atmospheric disks are tangent at four contact times tI-tIV, illustrated in Fig. . The total duration is tT=tIV-tI, the full duration is tF=tIII-tII, the ingress duration is to=tII-tI, and the egress duration is to′=tIV-tIII. The occultation depth δ is the X-ray flux attenuation due to the extinction.

The egress duration is about 14 s during the occultation process analysed in this study. We divide this duration into 35 bins in order to have good time resolutions and a high signal-to-noise ratio (SNR). The light curves of three different energy bands during the occultation process are shown in Fig. . The abscissa time is converted to tangent point altitude. In this study, the maximum height difference between two adjacent tangent points is 836 m, and the mean height difference between two adjacent tangent points is about 673 m. For clarity, the data points in Fig.  are displayed by taking 1 point every 10 points from the initial data points. The dashed blue, red, and green lines represent the modelled light curves. The green and blue shaded regions correspond to the extinction process for the occultation in the energy bands of 1.319–1.725 and 7.006–7.412 keV, respectively. For clarity, the height range for occultation between 3.350 and 3.756 keV is not marked. The light curve in the energy range of 1.319–1.725 keV starts to attenuate at 150 km, and it is completely attenuated at 102 km. The light curve in the energy range 7.006–7.412 keV starts to attenuate at 100 km, and it is completely attenuated at 85 km.

The attenuation process of X-rays in the atmosphere can be described by the Beer–Lambert law: 1I=I0e-τ, where I0 is the unattenuated source spectrum, which is a function of energy, e-τ is the transmittance, and τ is the optical depth, which has the form 2τ=∑sγ∫l0∞nsσsdl, where s labels the gas components in the Earth's atmosphere, γ is the total correction factor, and ns is the number density of each component of the atmosphere along the line of sight. Based on the spherical symmetry assumption of the Earth atmosphere, the number density is converted to column density by the Abel integral. σs is the X-ray cross section (photoelectric absorption and scattering cross section) of each component in the atmosphere. X-ray photons are absorbed or scattered by atoms, and in the energy range of interest in this paper, the scattering effect can be ignored because it is too small relative to the photoelectric absorption effect. However, the scattering cross section is still included in the calculation.

The modelled light curves with this forward model are shown in Fig.  from Insight-HXMT for the X-ray Earth occultation of the Crab Nebula. The normalized flux with the orbital phase is shown. From Fig. , we can see that the occultation depths (the difference between the highest and lowest point of the same light curve) for different energy bands are very different. Here, the atmospheric model NRLMSISE-00 is chosen as our input data in the light curve calculations in Fig. .

I0 was fitted by using Xspec, a standard software package for spectrum fitting in X-ray astronomy. To fit the unattenuated spectrum of the Crab Nebula, we use the model wabs × powerlaw , where “wabs” is the interstellar absorption model in Xspec . The model “powerlaw” represents a simple power law shape of spectrum to fit. The data description and fitting result of unattenuated energy spectrum are listed in Table . The reduced χ2 value is 1.06 in this fitting, which indicates that the fit is good. The best-fit model and the unattenuated energy spectrum data are shown in Fig. a. The blue dots with the error bars are the unattenuated spectrum of the Crab Nebula observed by LE. The solid red line is the best-fit model. Figure b shows the residuals of the fit.

The main atmospheric components causing extinction are oxygen (O, O2), nitrogen (N, N2), and argon during the occultation. The absorption of N and O to X-ray has similar characteristics because the energy dependence of the X-ray cross sections of N and O is similar in our interest energy band . In other words, it is impossible to distinguish N and O through X-ray occultation in our interest energy band, but their total atmospheric density (N + O + O2 + N2) distribution can be calculated. In addition, although X-ray photons interact directly with the K- and L- shell electrons of atoms (including atoms within molecules), the O2 (or N2) counts as one absorbing “particle” in the calculation. Ar is an atmospheric constituent of less content relative to N and O in the Earth's atmosphere. The atmospheric density of Ar is 0.029 %–0.943 % of the total density of N and O according to the NRLMSISE-00 model in the altitude range of 20–200 km. But the X-ray cross section of Ar is larger by almost 1 order of magnitude than that of N and O over the energy range of interest. Therefore, Ar is included in our model.

The number density of each atmospheric component needs to be given as input data in the process of density profile retrieval with a forward model . In the following, the atmospheric models NRLMSISE-00 and NRLMSIS 2.0 are chosen as our input data in the modelling. The NRLMSISE-00 model is one of the most widely used and relatively accurate atmospheric model for the Earth's upper and middle atmosphere. The NRLMSIS 2.0 model is an upgraded version of the NRLMSISE-00 model. The input parameters of NRLMSISE-00 and NRLMSIS 2.0 for the calculation of model atmospheric density are listed in Table . In Table , the time corresponds to the middle tangent point altitude during occultations. The geographical latitude and longitude are calculated with coordination transformation from the coordination of the tangent point in J2000. F10.7 and Ap are the solar activity index and the geomagnetic activity at this time. The F10.7 index is one of the most widely used indices to characterize the level of solar activity , and the Ap index is used to characterize the geomagnetic activity . These data are obtained from the Space Environment Prediction Center (http://eng.sepc.ac.cn/index.php, last access: 7 May 2022).

The X-ray cross section σs of each component of the gas can be obtained through the photon cross section database XCOM . The X-ray cross sections of Ar, O, and N are shown in Fig. .

The specific form of the forward model of X-ray occultations is as follows : 3M=RI0e-τ+B, where R is the detector response matrix . In addition, the forward model also contains background noise B. The background noise should be included in the forward model, as shown in Eq. ().

Instead of subtracting the background, the background and the source counts can be modelled synchronously using Poisson statistics in the Bayesian framework . Bayes' theorem combines observation data with the prior distribution of the parameter of interest θ from a specific model to obtain the posterior probability distribution of the parameter. In this work, the posterior probability distribution of θ={γ,B} for the forward model shown in Eq. () applied to the data D can be given by Bayes' theorem : 4p(θ|D,M)=p(θ|M)p(D|θ,M)p(D|M), where D is the observation data, M is the forward model, p(θ|M) is the prior distribution, p(D|θ,M) is the likelihood, and p(D|M) is the Bayesian evidence.

Both the X-ray-observed counts and the background data follow Poisson statistics, so that the X-ray likelihood function, L, is given by 5ln⁡L=∑iDiln⁡Mi-Mi-ln⁡Di!, where Di is the observation data in the ith bin, and Mi is the ith forward model value. The natural logarithm of the likelihood function can also be used for parameter estimation as the C statistic .

In this paper, we analyse the light curve in the energy range of 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV; it is found that these energy ranges are indeed sensitive to the altitude range of 105–200, 95–125, and 85–110 km, respectively, as shown in Fig. . The red shading in Fig.  indicates the occultation range, and the blue shading in Fig.  indicates the energy range.

The Markov chain–Monte Carlo (MCMC) method is one of the parameter estimation methods used for Bayesian inference . The density profile retrieval implements the MCMC method, which samples from a probability distribution using Markov chains . MCMC is implemented by emcee that uses an affine-invariant ensemble sampler. A total of 200 000 steps with 10 walkers are used in the sampling process. A 20 000-step MCMC chain for each walker led to 1 standard deviation estimates for the correction factor γs and the background B as [0.871–0.905] and [0.609–0.720], [0.787–0.834] and [0.797–0.924], and [0.811–0.948] and [1.399–1.558] based on NRLMSISE-00 and to 1 standard deviation estimates for the correction factor γs and the background B as [1.075–1.118] and [0.621–0.735], [0.897–0.951] and [0.793–0.919], and [0.936–1.905] and [1.398–1.558] based on NRLMSIS 2.0 in the energy range of 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV, respectively, where the first 1000 steps in each walker are burned. The posterior probability distribution of the correction factor γs and the background B is obtained, as shown in Fig. . In this corner plot, the vertical dashed black lines are the quantiles 0.16 and 0.84 of the posterior probability distribution respectively. The vertical dashed red line indicates the median for the posterior probability distribution of the correction factor γs and the background B. The median of the posterior probability distribution and the interval with the quantiles of 0.16 and 0.84 are marked above the histogram. The retrieved results of atmospheric density can be obtained by multiplying γs by the input data. Therefore, γs can be used as an average scaling factor for NRLMSISE-00 and NRLMSIS 2.0 density models.

The comparison for the retrieved density profile with XEOS in the energy range of 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV, the previous retrieval results based on RXTE in the altitude range of 100–120 km , the NRLMSISE-00 model density profile, and the NRLMSIS 2.0 model density profile are shown in Fig. . The density profiles marked by the legend of Insight-HXMT (XEOS-00) and Insight-HXMT (XEOS-2.0) in each panel in Fig.  are the retrieved results based on the NRLMSISE-00 model and the NRLMSIS 2.0 model, respectively. There is an obvious gap between the XEO measurement and the model prediction from NRLMSISE-00. The retrieved density profiles from Insight-HXMT based on the NRLMSISE-00 and NRLMSIS 2.0 models by fitting the light curves in the energy range of 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV are qualitatively consistent with the previous retrieved results from RXTE, and there are two intersections between the retrieved density with Insight-HXMT by fitting the light curve in the energy range of 2.5–6.0 keV and the retrieved density from RXTE. The XEO-retrieved density is approximately 88.8 % of the density of the NRLMSISE-00 model and 109.7 % of the density of the NRLMSIS 2.0 model in the altitude range of 105–200 km at the same time and location, respectively. The XEO-retrieved density is approximately 81.0 % of the density of the NRLMSISE-00 model and approximately 92.3 % of the density of the NRLMSIS 2.0 model in the altitude range of 95–125 km at the same time and location, respectively. The XEO-retrieved density is approximately 87.7 % of the density of the NRLMSISE-00 model and 101.4 % of the density of the NRLMSIS 2.0 model in the altitude range of 85–110 km at the same time and location, respectively. The previous retrieval density based on RXTE by XEOS is approximately 50 % of the density of the NRLMSISE-00 model in the altitude range of 100–120 km on 14 November 2005. The latest semi-empirical atmospheric model, NRLMSIS 2.0, which belongs to the MSIS family, has recently been released, and it is a significant upgrade of the previous version, NRLMSISE-00. The density profile from NRLMSIS 2.0 is about 8.5 %–21.9 % lower than the densities from NRLMSISE-00 in the altitude range of 95–125 km. Nevertheless, the gap between the retrieved density profile and the model prediction from NRLMSISE-00 and NRLMSIS 2.0 still needs to be verified further.

Comparisons between the observed light curve data points and the model light curves based on the best-fit density profiles and model-predicted light curves based on the NRLMSISE-00 and NRLMSIS 2.0 model simulation are shown in Fig. . Panels (a), (b), and (c) indicate the light curves in the energy range of 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV, respectively. The residuals between observed light curves and model light curves are also shown in Fig. . For clarity, the data points for observed light curve in Fig.  are displayed by taking one point every three points from the initial data points, and the residuals corresponding to the four light curves are shifted vertically in the lower sub-panel of each panel. Four extinction curves of each panel are obtained using the forward model based on the four density profiles for comparison with the XEO observation data, among which the density profiles mainly include the two XEOS-retrieved density profiles and the NRLMSISE-00- and NRLMSIS 2.0-model-predicted density profile for approximately the same date, time, and geographic latitude and longitude. In order to show the difference between the light curves, we amplified the observed light curve and the four model light curves in the altitude range of 120–124, 106–109, and 95–100 km in Fig. a, b, and c, respectively.

In this section, Pearson's χ2 test is used to test the XEO measurements and NRLMSISE-00 and NRLMSIS 2.0 model prediction for the description of the XEO light curve.

In this study, the following null hypotheses are proposed. The light curves predicted by the XEO-measured density profile and the NRLMSISE-00- and NRLMSIS 2.0-model-simulated density profile fit the observed light curve well. It is found that the null hypothesis can not be rejected even at the 84 % and 90 % confidence level for the two XEO measurements in the energy range of 1.0–2.5 keV, the null hypothesis can not be rejected even at the 55 % and 64 % confidence level for the two XEO measurements in the energy range of 2.5–6.0 keV, and the null hypothesis can not be rejected even at the 68 % and 69 % confidence level for the two XEO measurements in the energy range of 6.0–10.0 keV, as shown in Table . It is found that the null hypothesis can not be rejected at the 95 % confidence level for both the NRLMSISE-00 and NRLMSIS 2.0 predictions, except for the NRLMSISE-00 predictions by the model light curve in the energy range of 1.0–2.5 keV. Goodness-of-fit testing results between the observed light curve and the extinction curve predictions with XEO-measured density profiles and the NRLMSISE-00- and NRLMSIS 2.0-model-simulated density profiles are also listed in Table .

Goodness-of-fit testing is carried out for the observed light curve and four model light curves in the energy range of 1.0–2.5 keV. As shown in Table , the χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSISE-00 are 1.0599 and 0.1604, where dof represents the degrees of freedom, i.e., the number of sample points minus the number of variables. In this paper, 551 sample points are used for fitting, with two variables of correction factor and background noise, so dof = 549. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSIS 2.0 are 1.0756 and 0.1074. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSISE-00-predicted density profile are 1.1220 and 0.0249. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSIS 2.0-predicted density profile are 1.0783 and 0.0997. The results show that the light curves based on XEO-retrieved density can better describe the observed light curve. Compared with the retrieved results, the atmospheric density predicted by the NRLMSISE-00 model overestimates by 11.2 %, and the atmospheric density predicted by the NRLMSIS 2.0 model underestimates by 9.7 %.

Goodness-of-fit testing is carried out for the observed light curve and four model light curves in the energy range of 2.5–6.0 keV. As shown in Table , the χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSISE-00 are 1.0091 and 0.4540. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSIS 2.0 are 1.0612 and 0.3669. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSISE-00-predicted density profile are 1.3321 and 0.0802. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSIS 2.0-predicted density profile are 1.3331 and 0.0797. It is found that the light curve predictions based on the XEO-retrieved density profiles can describe the observed light curve better, and gaps between the retrieved density profiles and the model-simulated ones exist. Compared with our retrieved results, the density profile of the NRLMSISE-00 model is overestimated by 19 %, and the density profile of the NRLMSIS 2.0 model is overestimated by 7.7 %.

Goodness-of-fit testing is carried out for the observed light curve and four model light curves in the energy range of 6.0–10.0 keV. As shown in Table , the χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSISE-00 are 1.0936 and 0.3293. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the XEO-retrieved density profile based on NRLMSIS 2.0 are 1.1012 and 0.3193. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSISE-00-predicted density profile are 1.2085 and 0.1967. The χ2/dof and p value between the observed light curve and the extinction curve predicted with the NRLMSIS 2.0-predicted density profile are 1.0955 and 0.3268. The results show that the light curves based on XEO-retrieved density and the NRLMSIS 2.0-predicted density can better describe the observed light curve. The retrieved results based on the light curve in the energy range of 6.0–10.0 keV are basically consistent with the model density of NRLMSIS 2.0, but the density profile of NRLMSISE-00 is overestimated by about 12.3 %.

From the above results, it is found that the altitude ranges that correspond to the light curve attenuations are indeed sensitive to different energy ranges, and they often overlap. For example, the energy band of 1.0–2.5 keV is sensitive to the altitude range of 105–200 km, and the energy band of 6.0–10.0 keV is sensitive to the altitude range of 85–110 km. Therefore, the overlap range between the sensitive altitude ranges for the two energy bands is 105–110 km. But the retrieved density profiles of different energy bands are different in the overlap altitude range. This is because the XEOS retrieval by light curve fitting is an altitude-dependent method, different energy bands have different sensitive altitude ranges, and the retrieved results can be different, even if there are overlapping altitude areas. The retrieved results are a simple scaling of MSIS density. The occultation data of X-ray detectors with larger effective area or stronger detection ability can be used to retrieve atmospheric density to reduce the influence of energy integration.

Since the Earth's middle and upper atmosphere is greatly affected by solar activity and geomagnetic activity, it will also have an impact on the density of the Earth's upper and middle atmosphere, so the possible systematic uncertainty of the predicted XEO light curve due to variations of solar and geomagnetic activity is discussed. Common solar activity includes sunspots, flares, and corona. Here, the effects can be demonstrated by the predicted XEO light curve with the NRLMSISE-00 density profile for the changing solar activity index F10.7 and geomagnetic activity index Ap. The values of the model light curves under extreme solar activity, very low solar activity , a severe geomagnetic storm, and quiet geomagnetic activity are calculated, as shown in Fig. . The energy range of the light curve in Fig. a–c is 1.0–2.5, 2.5–6.0, and 6.0–10.0 keV, respectively. For clarity, the data points are displayed by taking one point every five points from the initial data points in Fig. . In order to show the difference between the light curves under the different solar activities and geomagnetic activities, the observed light curve and the model light curves in the altitude range of 105–150, 95–125, and 85–110 km are locally amplified in Fig. a, b, and c, respectively. The Akaike information criterion (AIC) and the Bayesian information criterion (BIC) are calculated for these model comparisons, and the results are listed in Table . AIC and BIC are used for model selection and can also be used to compare models. Usually, we choose the model with the smallest AIC and BIC. However, the values of AIC and BIC in this paper show that solar and geomagnetic activity has a great influence on model shape. because AIC and BIC values vary greatly under different solar and geomagnetic activity in a relatively low energy range. Goodness of fit between the observed light curve and the model light curves under the different solar activities and geomagnetic activities is also evaluated by the χ2/dof and p value in Table . It can be shown that the solar activity and the geomagnetic activity have great influence on the shape of model light curves. In addition, with the increase of altitude, solar and geomagnetic activities have a greater impact on the model light curves. The effects of solar activities and geomagnetic storms on the XEO light curve modelling and density retrieval will be further investigated in the future.

Based on the energy spectrum fitting method during X-ray occultation , the altitude-independent atmospheric-density-retrieved results can be obtained, and the overlap of the tangent point altitude can be effectively avoided. In order to prove the reliability of our retrieved results in the paper, we compare our results with the results of energy spectrum fitting . The optical depth of the forward model based on energy spectrum fitting is given by the following equation: 6τ=∑sγh∫l0∞nsσsdl, where γh represents correction factors in different altitudes ranges. By combining Eqs. () and (), the forward model of the energy spectrum fitting for different altitude ranges is given. By fitting the energy spectrum data in different altitude ranges, the correction factors in corresponding altitude ranges can be obtained, namely γh. So multiplying γh with the input data from the NRLMSIS 2.0 model, the atmospheric density in different altitude ranges can be retrieved independently.

In the paper, by fitting the energy spectrum data in the energy range of 1–10 keV, we obtain the atmospheric density values in the altitude range of 100–200 km and extract the energy spectrum data every 10 km. The comparison between the best-fit model and energy spectrum observational data is shown in Fig. . The retrieved results based on energy spectrum fitting and the results with light curve fitting are shown in Fig. , where the solid blue line represents the retrieved results of spectrum fitting, the solid red line represents the model density profile of NRLMSIS 2.0, and the solid green line represents the retrieved results with light curve fitting in the energy range of 1.0–2.5 keV. It is found that the retrieved results based on the light curve fitting are qualitatively consistent with the retrieved results of the energy spectrum fitting method. In the altitude range of 180–200 km, because the number of X-ray photons absorbed by the Earth's atmosphere is less than the X-ray photon counting error, the retrieved results based on energy spectrum fitting have large uncertainty. However, the reliability of the results based on light curve fitting is proved to be consistent with that by the altitude-independent method by spectrum fitting.