Using the Archeops and WMAP data, we perform a study of the anticenter Galactic diffuse emissions—thermal dust, synchrotron, free-free, and anomalous emissions—at degree scales. The high-frequency data are used to infer the thermal dust electromagnetic spectrum and spatial distribution allowing us to precisely subtract this component at lower frequencies. After subtraction of the thermal dust component, a mixture of standard synchrotron and free-free emissions does not account for the residuals at these low frequencies. Including the all-sky 408 MHz Haslam data we find evidence for anomalous emission with a spectral index of −2.5 in TRJ units. However, we are not able to provide coclusion regarding the nature of this anomalous emission in this region. For this purpose, data between 408 MHz and 20 GHz covering the same sky region are needed.
1. Introduction
The anomalous microwave emission (AME in the following) is an important contributor of the Galactic diffuse emissions in the range from 20 to 60 GHz. It was first observed by [1, 2] and then identified by [3] as free-free emission from electrons with temperature Te>106 K. Draine and Lazarian [4] argued that AME may result from electric dipole radiation due to small rotating grains, the so-called spinning dust. Models of the spinning dust emission [5] show an electromagnetic spectra peaking at around 20–50 GHz being able to reproduce the observations [6–13]. The initial spinning dust model has been refined regarding the shape and rotational properties of the dust grains [14–17]. An alternative explanation of AME was proposed by Draine and Lazarian [18] based on magnetic dipole radiation arising from hot ferromagnetic grains. This kind of models associated to single domain predict polarization fraction much bigger than the electric dipole ones [19]. Original models have been mainly ruled out by many studies [10, 20–23] although modern variants of those may still be of interest (B. Draine private communication).
Correlation between microwave and infrared maps, mainly dominated by dust thermal emission [24], was observed for various experiments, for example, on COBE/DMR [2, 25], OVRO [3], Saskatoon [1], survey at 19 GHz [26], and Tenerife [27]. Similar signal was found in small region by [6] and in some molecular clouds based on data from COSMOSOMAS [8, 28], AMI (AMI Consortium [29, 30]), CBI [10, 31], VSA [13], and Planck [32]. Recent studies based on several sets of data [33] found similar results.
Independently, Bennett et al. [34] proposed an alternative explanation of AME based on flat-spectrum synchrotron emission associated to star-forming regions to explain part of the WMAP first-year observations. This hypothesis seems to be in disagreement with results from de Oliveira-Costa et al. [7]; Fernández-Cerezo et al. [35]; Hildebrandt et al. [36]; Ysard et al. [37], which showed that spinning dust was the most trustable emission to explain the excess below 20 GHz. Furthermore, Davies et al. [38] showed the existence of important correlation between microwave and infrared emissions in regions outside star-forming areas. More recently, Kogut et al. [39] discussed the fact that spinning dust fits better to ARCADE data (3.8 and 10 GHz) than a flat-spectrum synchrotron.
We propose here to study the Galactic diffuse emissions in the Galactic plane, particularly focusing on the anticenter region. The observational data, from 408 MHz to 3000 GHz, used for this study are presented in Section 2. Section 3 discusses in details the contribution of the diffuse Galactic thermal dust emission using the high-frequency data. In Section 4, we consider a simple free-free and canonical synchrotron emission model for the thermal dust-subtracted microwave data. The possible contribution from anomalous emission is discussed in Section 5. We draw conclusions in Section 6.
2. Microwave and Millimeter Observations
We describe in this section the data used for the analysis presented in this paper. As we are interested in the Galactic diffuse emission, we consider only large coverage sky surveys in the radio, microwave, millimeter, and infrared domain including the 408 MHz all-sky survey and the WMAP ARCHEOPS and IRAS data.
2.1. The 408 MHz All-Sky Survey
In the radio domain, the 408 MHz all-sky continuum survey [40] at a resolution of 0.85 degrees is a good tracer of the synchrotron emission. In particular, we use the 408 MHz all-sky map available on the LAMBDA website in the HEALPix pixelisation scheme [41]. The 408 MHz all-sky survey map was smoothed down to a resolution of 1 degree and downgraded to Nside=64 in the HEALPix pixelisation scheme [41]. The uncertainties on this map are assumed to be of 10% following Haslam et al. [40] and are mainly due to calibration errors.
2.2. WMAP
In order to estimate the diffuse Galactic emission at microwave frequencies, we used the maps in temperature using the K, Ka, Q, V, and W band maps of the WMAP mission of its 7-years WMAP [42]. In particular, we used the coadded maps available on the the LAMBDA web site, also smoothed down to a resolution of 1 degree and downgraded to Nside=64. Uncertainties in the WMAP data were computed assuming an uncorrelated anisotropic noise as described in [42]. The variance per pixel at the working resolution was computed using the variance of a single hit and the number of hits per pixels.
2.3. Archeops
In the millimeter wavelengths, we use the ARCHEOPS balloon experiment [43] data. ARCHEOPS observed the sky at four frequency bands: 143, 217, 353, and 545 GHz, with resolutions of 11, 13, 12, and 18 arcmin respectively [44]. The ARCHEOPS survey covers about 30% of the sky mainly centered in the Galactic anti-center region. We use here the original ARCHEOPS maps which were also smoothed down to a resolution of one degree and downgraded to Nside=64.
2.4. IRAS
In the infrared, we have used the new generation of the IRAS data (InfraRed Astronomical Satellite) at 100 and 60 μm (3000 and 5000 GHz). This release of the IRAS data is called IRIS (Improved Reprocessing of the IRAS data) [45] and has been built with a better destriping ability, a better subtraction of the zodiacal light, and a calibration and a zero level compatible with the far infrared instrument, FIRAS, of COBE. The IRIS maps were also smoothed down to a resolution of one degree and downgraded to Nside=64.
In order to avoid the contamination from the CMB at intermediate frequencies, 30–200 GHz, we have restricted our study to the Galactic plane where the Galactic emissions dominate over the cosmological CMB emission. In practice, we selected those regions in the ARCHEOPS 353 GHz map with intensity above 3000 μKRJ or higher. This corresponds to 1391 pixels at Nside=64 in the anticenter region.
3. Diffuse Galactic Thermal Dust Emission
We first study the electromagnetic and spatial properties of the thermal dust diffuse Galactic emission. In order to model the intensity of the thermal dust emission, we use a simple grey body spectrum of the form
(1)Iν=I0νβdBν(Td),
where βd is the spectral index of the thermal dust emission and Td is the dust temperature.
We used the ARCHEOPS and IRIS 100 μm maps to characterize the dust thermal emission model. We fitted the data to the model pixel by pixel using as free parameters I0, βd, and Td, and the following likelihood function
(2)-logℒν=∑ν(Dνp-Mνp)2σνp2,
where Dνp and Mνp correspond to the data and model at the pixel p within the mask and for the observation frequency ν (=143, 217, 353, 545, and 3000 GHz). σνp is the 1-σ error bar associated with Dνp. βd and Td were explored using an uniformly spaced grid (as defined in Table 2), while I0 was computed via a linear fit for each pair (βd,Td). The instrumental noise in the ARCHEOPS maps has been estimated using simulations of the noise in the ARCHEOPS Time Ordered Information (TOI) following the method described in Macías-Pérez et al. [44]. The variance per pixel was calculated from 250 simulated noise maps at one degree resolution and Nside=64. The error bars for the IRIS data at 100 μm were set to 13.5% following [45] as they are dominated by calibration errors.
In Figure 1 we, present maps of the dust temperature and spectral index within the considered mask. We also show the statistical uncertainties on these parameters. As expected,, the errors increase significantly on the edges of the maps. These noisy pixels will be excluded from the analysis hereafter. We can also notice that in the inner regions, the statistical errors are significantly smaller than the observed dispersion for the two parameters. We observe that the mean dust temperature is 20.0 K with 2.1 K dispersion, while the mean instrumental uncertainties are of the order of 1 K. In the same way, the mean dust spectral index is 1.40 with a dispersion of 0.25, and the mean instrumental uncertainties of the order of 0.1.
From top to bottom and from left to right: maps of the best-fit thermal dust emission spectral indices and temperature and uncertainties at 2σ (95% C.L.) (right).
Figures 1 and 2 compare the best-fit thermal dust model to the IRAS and ARCHEOPS data. From left to right, we show the data, the model, and residuals for all frequencies. For the ARCHEOPS data, the residuals are at most 10% of the total intensity. In the case of the IRAS data, the model reproduce rather well the 100 μm map. However, at 60 μm, the residuals are important, and the model is not able reproduce the structure in the data. Residuals can be as important as 60% of the total intensity. This can be explained by the presence of a hotter dust component as discussed in Désert et al. [24]. This component is out of the scope of this study and does not have any consequence in the following study. Table 1 presents the rms of the ARCHEOPS and IRAS data as well as the rms of the residuals after subtraction of the dust model. The last column of the table represents the mean standard deviation of the noise in the original maps. We observe that except for the 5000 GHz data, the residuals are of the order of magnitude of the noise.
Rms of the high-frequency data and of the residuals after subtraction of the dust model.
Frequency (GHz)
Data rms (mKRJ)
Residual rms (mKRJ)
Noise standard deviation (mKRJ)
143
0.194407
0.0240274
0.0241575
217
0.315175
0.0306455
0.0406982
353
0.498923
0.0705655
0.0404479
545
0.699145
0.113738
0.157994
3000
0.0973817
0.00830546
0.0197808
5000
0.0134645
0.00974734
0.00176314
Range of values considered for the parameters of the thermal dust emissivity model.
Parameters
Range
Step
βd
[−1.0, 4.0]
0.02
Td
[10.0, 37.0]
0.1
Temperature maps (mKRJ) for the ARCHEOPS data (left), the thermal dust emission model (center), and residuals (right). From top to bottom, we present the 545, 353, 217, and 143 GHz maps.
4. Diffuse Galactic Free-Free and Synchrotron Emissions
In order to estimate the contribution of the diffuse Galactic free-free emission, which is expected to be important at the WMAP bands, we use the extinction-corrected h-alpha foreground template (Hα) map built by Finkbeiner [6]. This map was computed using data from the Virginia Tech Spectral line Survey (VTSS) for the North and of data from the Southern H-Alpha Sky Survey Atlas (SHASSA) for the South sky (Figure 3). Correction factors are applied to take into account dust absorption [6]. We started from a map at resolution Nside=512 and downgraded it, as the other maps, at a resolution of Nside=64. In order to obtain a template of the free-free emission at 23 GHz using the Hα map, we follow Bennett et al. [34]. In antenna temperature units and defining the emission measure as EM=∫ne2dn, one can write
(3)TAff(μK)=1.44EMcm-6·pc·[1+0.22ln(Te/8000K)-0.14ln(ν/41GHz)](ν/41GHz)2(Te/8000K)1/2.
The intensity of the HαI(R) emission (in Rayleigh units) is defined by
(4)I(R)=0.44EMcm-6·pc(Te8000K)-1/2×(1-0.34ln(Te8000K)).
Thus, the intensity of the free-free emission (in mKRJ) is given as a function of the intensity of the Hα emission (in Rayleighs) by
(5)Tff=1.440.44I(R)×(1+0.22ln(Te/8000K)-0.14ln(ν/41GHz))(ν/41GHz)2(1-0.34ln(Te/8000K)).
We have extrapolated this free-free emission template at each of the WMAP frequencies assuming that the electromagnetic spectrum of the free-free emission is well represented by a power law of the form νβff [34], where
(6)βff=-2-110.48+1.5ln(Te/8000K)-ln(ν/41GHz).
We set a standard value for the electronic temperature at 8000 K, following [46]. The values of the spectral index obtained at the WMAP frequencies assuming these hypotheses are given in Table 3.
Spectral index of the free-free emission at the WMAP frequencies assuming an electronic temperature of Te=8000 K.
Central frequency (GHz)
23
33
41
61
94
βff
-2.090
-2.093
-2.095
-2.099
-2.103
From left to right: residuals after subtraction of the thermal dust and free-free and anomalous emission models for the 61 (top) and 23 GHz (bottom) maps.
In order to model the synchrotron contribution, we used the 408 MHz all-sky continuum survey as a template map. We extrapolated it at all the considered frequencies assuming a power law-like electromagnetic spectrum in antenna temperature with fix spectral index that we set to −2.7 [34].
In the second column of Table 5, we present the rms of the residuals after subtraction, of the Galactic thermal dust, synchrotron and free-free emission models. These residuals are significant: up to 90% of the original emission (first column of the table). We have observed both point-like and diffuse structures in these residuals. The former are more probably related to uncertainties in the modeling of the free-free emission. By contrast, the extra diffuse emission is most probably related to anomalous emission. This hypothesis is considered in the following section.
5. Study of the Anomalous Emission
In the previous section, we concluded that the observed emission in the range from 23 to 94 GHz cannot be explained only by the combination of the canonical Galactic diffuse emission: thermal dust, soft synchrotron, and free-free emission. Indeed, we have observed that in some compact regions there seems to be extra free-free emission with respect to the predictions from the Hα template. Furthermore, the diffuse emission is underestimated in general indicating either an extra component or a softer synchrotron component. In order to investigate these two problems, we have considered a two-component model composed of free-free and anomalous emissions in addition to diffuse thermal dust emission. We assume that the free-free and the anomalous emissions follow a simple power-law model such that
(7)Mν=Aanomνβanom+Affνβff(Te,ν),
where Mν are the observed maps in KRJ units at the frequency ν after subtraction of the contribution from thermal dust. Finally, we consider 4 free parameters in the model: the normalization coefficients Async and Aff, the spectral index βs of the anomalous component, and the free electron temperature. To simplify the fitting procedures, we vary βs and Te in the ranges shown in Table 4. Notice that we have not explicitly considered the canonical synchrotron emission in this model. Indeed, our so-called anomalous component will be a mixture of real anomalous emission and canonical synchrotron emission.
Range of the parameters considered for the anomalous and free-free emission models.
Parameters
Ranges
Step
βs
[−3.7, −2.3]
0.01
Te (K)
[4000.0, 14000]
1000
Rms of the WMAP data and of the residuals after subtraction of the dust, free-free, and standard synchrotron model and of the dust, free-free, and anomalous emission model compared to the standard deviation of the noise.
Frequency (GHz)
Data rms (mKRJ)
Residual DFS rms (mKRJ)
Residual DFA rms (mKRJ)
Noise standard deviation (mKRJ)
23
2.03831
2.02387
0.353262
0.183557
33
0.907433
0.884012
0.0881647
0.0612279
41
0.562764
0.531677
0.0372230
0.0438113
61
0.256907
0.205086
0.0377750
0.0205909
94
0.209367
0.112932
0.0530679
0.0239733
We fit this two-component model to the dust-subtracted WMAP maps and to the 408 MHz map for which the thermal dust emission is negligible. As discussed before, the uncertainties on the WMAP data have been calculated assuming anisotropic white noise on the maps. We compute the variance r pixel using the variance per single observation provided on the LAMBDA website and maps of the number of hit counts. For the 408 MHz map, we assume 10% uncertainties as discussed in Section 2. It is important to notice that an alternative three-component model (including free-free, canonical synchrotron, and anomalous emissions) would imply at least 6 free parameters to be fitted on only 6 sky maps. That is why we have chosen to consider a two-component model only.
From the results of the fit, we observe that the anomalous emission seems to dominate the diffuse component at 1 GHz, while the free-free emission seems to be mainly located in few compact regions. In Figure 4, we present the map of the reconstructed spectral index for the anomalous emission, βs. We observe that the anomalous emission seems to be well represented by a power law with average spectra index of −2.5. Similar results have been found by Bennett et al. [34] and Hinshaw et al. [47] who claim conclusive evidence for hard synchrotron emission. In our analysis, we did not dispose of data in the frequency range from 10 to 20 GHz to discriminate between this hypothesis and spinning dust emission (refer to [4] for a more complete review on spinning dust emission). It is important to notice that, currently, spinning dust emission has mainly been found in particular Galactic clouds (e.g., see [8, 27, 32, 33, 36, 37, 48–50]). Regarding the electron temperature, we have found that a physically accessible temperature is associated to only 40 out of 1039 pixels considered. These pixels correspond to the intense regions on the free-free map at 1 GHz. For the other pixels, the temperature is higher than the upper limit allowed [46] and then can not be linked to the free-free emission.
Map of the spectral index of the anomalous emission (right).
6. Summary and Conclusions
We have presented in this paper a detailed analysis of the Galactic diffuse emissions at the Galactic anticenter in the frequency range from 23 to 545 GHz. We have shown that a simple grey-body model can be used to describe the thermal dust emission in the frequency range from 100 to 3000 GHz. We find a mean temperature of 20 K with an intrinsic dispersion of 2.1 K and a spectral index of 1.4 with intrinsic dispersion of 0.25. These values are significantly larger and lower than expected from canonical models of the dust emission, Tdust~17K and βdust = 1.8–2 (e.g., see [51, 52]). The same kind of results have been found by Ade et al. [53] although as they fixed the spectral index to 1.8, they obtains a lower temperature of 14 K. We have performed a similar analysis fixing βdust=1.8, and we have also obtained lower dust temperatures. At high frequencies (above 3000 GHz), extra hot thermal dust emission from small dust grains is needed to account for the observations [24].
The former dust models have been used to extrapolate the thermal dust emission to microwave frequencies from 23 to 100 GHz. After subtraction of the thermal dust emission, we have shown that the microwave data can not be simply explained by a combination of free-free and canonical synchrotron emission. A more detailed analysis including AME has shown that the latter can be well approximated by a power law of average spectral index -2.5 in KRJ units. This anomalous emission seems to dominate the diffuse emission at microwave frequencies, while free-free emission seems to be located in few compact regions. Indeed, we have found that outside those regions, the data that required electron temperature has not been physically meaningful.
The spectral index found for the anomalous emission is consistent with hard synchrotron emission [34, 47]. However, we can not formally conclude on this as our analysis did not include data in the 1 to 20 GHz that would help discriminating this hypothesis from spinning dust emission by Draine and Lazarian [4] for which conclusive evidence has been found on some Galactic clouds by de Oliveira-Costa et al. [27, 48]; Lagache [49]; Watson et al. [8]; Ysard et al. [37]; Dickinson et al. [50]; Bot et al. [33]; Ade et al. [32], and as diffuse emission by Hildebrandt et al. [36].
Acknowledgments
The authors would like to thank R. Davies and C. Dickinson for useful discussions. S. R. Hildebrandt would like to thank the LPSC and, especially, Dr. Juan Macias and Professor Daniel Santos for the time they spent at LPSC during 2010.
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