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: http://www.sao.ru/precise/Laboratory/Publications/2000/0822_AA_v0/node9.html
Дата изменения: Sat Mar 11 12:22:26 2000 Дата индексирования: Sat Sep 11 20:55:17 2010 Кодировка: Поисковые слова: 2df survey |
H I line observations were carried out in July 1998 and in February 1999 with the Nançay 300m radio telescope (NRT). The NRT has a half-power beam width of 37 (EW) 22 (NS) at the declination Dec. = 0.
Since HS 0822+3542 had a known optical redshift, we split the 1024-channel autocorrelator in two halves and used a dual-polarization receiver to increase the S/N ratio. Each correlator segment covered a 6.4 MHz bandwidth, corresponding to a 1350 km s-1 velocity coverage, and was centred at the frequency corresponding to the optical redshift. The channel spacing was 2.6 km s-1 before smoothing and the effective resolution after averaging pairs of adjacent channels and Hanning smoothing was 10.6 km s-1. The system temperature of the receiver was 40 K in the horizontal and vertical linear polarizations. The gain of the telescope was 1.1 K/Jy at the declination Dec. = 0. The observations were made in the standard total power (position switching) mode with 1-minute on-source and 1-minute off-source integrations.
The data were reduced using the NRT standard programs DAC and SIR, written by the telescope's staff. Both H and V polarization spectra were calibrated and processed independently, and were finally averaged together. Error estimates were calculated following Schneider et al. ([1986]). With an integration time of 210 minutes, the r.m.s. noise is of 1.4 mJy after smoothing. HS 0822+3542 is detected with S/N=11. The spectrum is presented in Fig. 3.
(Å) Ion | F()/F(H) | I()/I(H) |
3727 [O II] | 0.331 0.013 | 0.331 0.014 |
3835 H9 | 0.077 0.005 | 0.080 0.007 |
3868 [Ne III] | 0.317 0.018 | 0.318 0.018 |
3889 H8 + He I | 0.199 0.009 | 0.203 0.010 |
4026 He I | 0.026 0.005 | 0.026 0.005 |
4101 H | 0.271 0.011 | 0.274 0.012 |
4340 H | 0.479 0.018 | 0.481 0.018 |
4363 [O III] | 0.123 0.007 | 0.123 0.008 |
4471 He I | 0.039 0.005 | 0.039 0.005 |
4861 H | 1.000 0.033 | 1.000 0.034 |
4922 He I | 0.009 0.003 | 0.009 0.003 |
4959 [O III] | 1.192 0.042 | 1.190 0.042 |
5007 [O III] | 3.550 0.121 | 3.542 0.121 |
5876 He I | 0.098 0.005 | 0.097 0.005 |
6300 [O I] | 0.004 0.003 | 0.004 0.003 |
6312 [S III] | 0.010 0.003 | 0.010 0.003 |
6548 [N III] | 0.005 0.004 | 0.005 0.004 |
6563 H | 2.743 0.087 | 2.729 0.094 |
6584 [N II] | 0.015 0.012 | 0.015 0.012 |
6678 He I | 0.033 0.004 | 0.033 0.004 |
6717 [S II] | 0.029 0.004 | 0.028 0.004 |
6731 [S II] | 0.018 0.004 | 0.018 0.004 |
C(H) dex | 0.0050.04 | |
F(H) | 0.47 erg s-1cm-2 | |
EW(H) Å | 2923 | |
EW(abs) Å | 0.60.7 |
Value | HS 0822+3542 | SBS 0335-052E1,2 | SBS 0335-052W3 | I Zw 18NW4 | I Zw 18SE4 |
(O III)(K) | 20,360850 | 20,300300 | 17,200500 | 19,700200 | 18,800400 |
(O II)(K) | 15,790600 | 15,800200 | 14,700400 | 15,600150 | 15,300300 |
(S III)(K) | 18,600700 | 18,500200 | 16,000400 | 18,000200 | 17,300350 |
(S II)(cm-3) | <10 | 524204 | 10 | 90 | 10 |
O+/H+(105) | 0.2470.025 | 0.200.1 | 0.600.05 | 0.220.01 | 0.490.03 |
O++/H+(105) | 1.9670.190 | 1.700.1 | 1.080.08 | 1.160.03 | 1.040.06 |
O/H(105) | 2.2140.191 | 1.900.1 | 1.680.10 | 1.450.03 | 1.540.07 |
12+log(O/H) | 7.350.04 | 7.290.01 | 7.220.03 | 7.160.01 | 7.190.02 |
N+/H+(107) | 0.9920.770 | 0.600.01 | 1.720.15 | 0.640.02 | 1.430.08 |
ICF(N) | 8.962 | 8.66 | 2.81 | 6.59 | 3.14 |
log(N/O) | -1.400.34 | -1.580.03 | -1.540.06 | -1.560.02 | -1.530.04 |
Ne++/H+(105) | 0.3550.041 | 0.270.05 | 0.240.03 | 0.190.01 | 0.230.03 |
ICF(Ne) | 1.126 | 1.13 | 1.55 | 1.25 | 1.48 |
log(Ne/O) | -0.740.07 | -0.800.03 | -0.650.06 | -0.800.01 | -0.650.04 |
S+/H+(107) | 0.4240.057 | 0.400.1 | 1.090.11 | 0.350.01 | 0.670.03 |
S++/H+(107) | 2.8150.873 | 1.900.3 | 2.150.64 | 1.960.21 | 2.070.30 |
ICF(S) | 2.26 | 2.21 | 1.29 | 1.82 | 1.32 |
log(S/O) | -1.480.09 | -1.590.04 | -1.600.08 | -1.550.03 | -1.630.04 |
Y(mean) | 0.2550.013 | 0.2490.006 | 0.2380.005 | 0.2170.005 | 0.2420.009 |
References: 1 Izotov et al. ([1997a]); 2 Izotov & Thuan ([1999]); 3 Lipovetsky et al. ([1999]); 4 Izotov & Thuan ([1998]). |
Band | P25 | E25 | ||||||
mag arcsec-2 | arcsec | mag arcsec-2 | arcsec | pc | pc | mag | mag | |
(1) | (2) | (3) | (4) | (5) | (6) | (7) | (8) | |
B | 20.960.04 | 1.410.02 | 20.400.02 | 1.580.02 | 118 | 318 | 18.22 | 19.46 |
V | 20.860.04 | 1.420.03 | 19.920.02 | 1.610.03 | 126 | 333 | 18.10 | 18.68 |
R | 20.570.08 | 1.380.04 | 19.790.03 | 1.610.03 | 129 | 342 | 17.88 | 18.60 |
(1) Central surface brightness of the LSB component obtained from the decomposition of each SB profile, weighted by its photometric uncertainties. | ||||||||
(2) Exponential scale length of the LSB component. | ||||||||
(3) Central surface brightness of the gaussian (SF burst) component. | ||||||||
(4) Effective size (FWHM) of the gaussian (SF burst) component. | ||||||||
(5) Linear extent of the luminous component in excess of the LSB component at a surface brightness level of 25 mag arcsec-2. | ||||||||
(6) Linear extent of the LSB component at a surface brightness level of 25 mag arcsec-2. | ||||||||
(7) Total apparent magnitude of the LSB component estimated by extrapolation of the exponential fitting law to R* = (equation 2). | ||||||||
(8) Total apparent magnitude of the SF component. |