1997年3月9日日全食8.6mm波段射电观测

１９９７年３月９日日全食８．６ｍｍ波段射电观测资料的分析表明,８．６ｍｍ波段射电太阳的半径为１．０１２Ｒ,总流量为２５４０ｓｆｕ（１ｓｆｕ＝１０＾－２２Ｗ／ｍ＾２Ｈｚ）,日面平均亮温度为９６３２Ｋ,径向亮温度分布,在日面光学边缘内侧０．９３６－０．９９２Ｒ处,存在临边增亮,平均增亮幅度相对于日面中心为９．７％。     

8.6毫米波段太阳射电亮温度分布的日环食测定

本文根据１９８７年９月２３日的８．６毫米波段射电日食观测资料，计算了太阳射电的径向亮温度分布，计算结果表明：８．６毫米波段太阳径向亮温度分布呈临边增亮；增亮幅度相对于日面中心部分为５．１％，中国部分也存在着增亮的征兆；日食当天８．６毫米波段太阳射电辐射的剖流量为２３４６Ｓ、ｆ、Ｕ；食甚时的剩余流量约为１２．５％，掩食半径为１．０１４光学太阳半径。     

8.6毫米波段太阳射电亮度温度分布

本文根据１９８０年２月１６日的８．６毫米波长射电日食观测资料，计算了太阳射电辐射的亮度温度的径向分布，由日食过程的第一，第二和第三接触的计算结果表明，在日面光学边缘内侧的二角分范围内，均存在明显的单峰状增亮结构。三个接触的平均增亮峰值约为１８％，增亮区的射电辐射占日面总辐射的４％。日食当天在８．６毫米波段上测得的日面平均亮度温度为９７２７Ｋ。     

三颗类星体的亚毫角秒结构

使用全球ＶＬＢＩ网在１．３ ｃｍ波段对三颗类星体０４２０－０１４、０７４８＋１２６和２２５１＋１５８（３Ｃ ４５４．３）进行了观测,获得了这三个类星体的亚毫角秒分辨率的混杂图,给出了类星体核区内的亮度分布．通过用高斯模型对观测数据进行拟合,得到了组成它们的各个子源的参数．类星体２２５１＋１５８呈现出核－喷流结构,核区沿着ＰＡ～－１３０°方向拉长,喷流呈弯曲状．１９９２．９历元的观测展现了２２５１＋１５８处于一次大爆发,并伴随一系列相继出现的小爆发的情景．最强子源的积分流量密度为 ４．１１Ｊｙ（占探测到的总流量的 ６７％）,主要集中在０．１６ × ０．０１ ｍａｓ的区域内,可能由于多普勒增亮效应造成高达２．６×１０１２的亮温度．     

大天线太阳射电观测和流量归算的一种方法

本文介绍了高空间分辨率的太阳射电观测流量的归算方法，即对观测的太阳天线温度值作天线功率方向图Ｋ因子的修正，即可得到太阳射电流量值．文中推导了不同温度分布模型下的Ｋ因子表达式，并计算了日面宁静太阳流量值和部分射电源的ＳＶＣ辐射流量值．对日面宁静区的射电辐射而言，因Ｋ的年变化（０．０２３６—０．０２５２）不大，因此按其平均值０．０２４４可计算出２２ＧＨｚ频率上宁静太阳流量ｓ。＝０．１５Ｔａ。（以ｓｆｕ为单位，Ｔａ。是宁静区辐射的太阳天线温度），相应的宁静太阳温度为１０１００土３００Ｋ．１９９０年７月２日源区的ＳＶＣ辐射计算结果表明：日面源区的ＳＶＣ辐射总和为２０ｓｆｕ，约占日面总辐射的２．４％．     

1.0—2.0GHz,2.6—3.8GHz微波爆发与共生的HXR爆发的统计关系

利用日本ＹＯＨＫＯＨ卫星ＨＸＴ提供的ＨＸＲ爆发资料,和中国科学院北京天台的大亨是射电宽频带动态频谱仪（１．０－２．０ＧＨｚ,２．６－３．８ＧＨｚ）提供的微波爆发资料,对共生事件进行了初步统计分析,并对其中两例典型事件：１９９７年１１月２８日０５０３ＵＴ事件及１９９８年５月９日０３４０ＵＴ事件与共生的ＨＸＲ爆发进行了详细比较,给出了几点有意义的结果及理论解释。     

1993年10月2日太阳射电爆发事件的证认和分析

分析了１９９３－１０－０２ ０７３９．５－０７４５．０ＵＴ在２．８４０ＧＨｚ－２．５４５ＧＨｚ观测到的一次太阳射射电爆发事件，证认了这次爆发的一部分是微波类Ⅲ型爆发。计算结果表明，这次Ⅲ型爆发是由速度为１．０×１０＾８ｍ／ｓ的相对论性电子束所引起的，产生电子束的源区背景温度为Ｔ－３×１０＾７Ｋ，射电爆发亮温度Ｔｂ＝１０６１２Ｋ，爆发源区的悄度Ｌ－３．４×１０＾２ｋｍ。     

1997年3月9日的日冕偏振CCD观测

给出１９９７年３月９日日全食时所作的日冕偏振ＣＣＤ观测资料的处理结果,包括太阳赤道东西和两极等十二个方向的中冕（１．６－３．２Ｒ）绝对亮度分布和偏振度分布。     

太阳黑子极小期的日冕总光通量测量

在漠河１９９７年３月９日日全食期间,使用３°测量视场的光电光度计,测量了日冕总光通。仪器的光谱响应符合Ｖ（λ）函数,测量结果：太阳黑子极小期日冕的总光通Φｃ与太阳总光通Φｓ之间的关系为Φｃ＝０．６９×１０－６Φｓ。     

1993年10月2日太阳射电爆发事件的证认和分析

分析了１９９３－１０－０２０７３９．５－０７４５．０ＵＴ在２．８４０ＧＨｚ－２．５４５ＧＨｚ观测到的一次太阳射电爆发事件，证认了这次爆发的一部分是微波类ＩＩ型爆发．计算结果表明，这次ＩＩ型爆发是由速度为１．０×１０８ｍ／ｓ的相对论性电子束所引起的，产生电子束的源区背景温度为Ｔ～３×１０７Ｋ，射电爆发亮温度Ｔｂ～１０１２Ｋ，爆发源区的尺度Ｌ～３．４×１０２ｋｍ．     

Observation of the 1997-03-09 total eclipse at 8.6 mm

COPY THE ORIGINAL Analysis of the total eclipse observation of 1997 March 9 at wavelength 8.6 mm, shows that, at this wavelength, the solar radius is 1.012 R_⊙, the total flux density is 2540 sfu, the mean brightness temperature of the solar disk is 9632 K, and the brightness temperature distribution shows limb brightening at the inner edge of the solar disk, the average brightness at 0.936−0.992 R_⊙ being 9.7% above the central brightness.     

Brightness temperatures of the quiet sun and new moon at the 6 mm wavelength

Absolute brightness temperatures and brightness temperature ratios of a quiet region near the center of the solar disk and the central region of the new moon were measured simultaneously at the 6 mm wavelength. The measured quiet sun/new moon brightness temperature ratios and reported central brightness temperatures of the new moon confirm the measured brightness temperature of the quiet sun at the 6 mm wavelength.Reported central brightness temperatures of the new moon are tabulated and graphed as a function of frequency and wavelength. The equation of a linear regression line for the reported measurements is given for estimating the brightness temperature of the new moon at any millimeter wavelength. Estimated brightness temperatures of the new moon and measured quiet sun/new moon ratios are used to estimate solar brightness temperatures at several millimeter wavelengths. The solar brightness temperatures, the regression line, and the Van de Hulst theoretical model are presented graphically as a function of frequency and wavelength. The regression line equation is given for estimating solar brightness temperatures at any wavelength in the 6 to 1 mm wavelength interval and is solved for the wavelength of the measured ratios.Reported solar brightness temperatures in the millimeter wavelength region are tabulated. The measured temperatures in the 6 to 1 mm wavelength interval and a linear regression line are presented graphically as a function of frequency and wavelength. The regression line equation is given and solved for the solar brightness temperatures at the 6 mm wavelength.This work supported by the U.S. Air Force under Contract No. F04701-69-C-0066.     

Brightness temperature distribution in solar corona based on RATAN-600 observations of the maximum phase of the March 29, 2006 solar eclipse

We describe the technique and results of modelling the solar radio emission during the maximum phase of the solar eclipse of March 29, 2006 on the RATAN-600. The aim of modelling is to refine the brightness temperature of the solar corona at the distances up to two solar radii from the center of the optical disk of the Sun. We obtained the distribution of brightness temperature in the vicinity of the coronal hole above the solar North Pole at the wavelength of 13 cm. The results of modelling showed that brightness temperatures of the coronal hole at the distances greater than 1.02 R_C (here R_C is the radius of the optical disk of the Sun) is substantially lower than the expected average brightness temperature of a typical coronal hole, and that of the quiescent Sun (below 30000 K) at the wavelength of 13 cm. The classical Baumbach-Allen formula for electron density in a spherically symmetric corona agrees with the results of observations starting at distances of (1.4–1.5) R_C.     

The distribution of the 9 cm radio emission over the solar disk during the sunspot minimum

The brightness distribution of the quiet sun on 9.1 cm wavelength is determined from the Stanford pencil-beam radioheliograms for three periods in the recent solar activity minimum, centred at July 15 and September 15, 1964 and at April 5, 1965. The brightness maxima near the limbs are not symmetric with respect to the central meridian, but are situated at 76 °E and 66 °W longitude, respectively. On the disk, the brightness temperature is likewise distributed asymmetrically, but the direction of this asymmetry changes as the new cycle starts. The asymmetries are tentatively explained by assuming the presence of inhomogeneous streamers in the solar atmosphere, which are tilted by the solar rotation. The eastward shift of the limb maxima with respect to the optical disk is confirmed by the 21 cm-heliograms obtained at Fleurs near Sydney, Australia.     

The radius of the Sun at centimeter waves and the brightness distribution across the disk

We report observations of the solar radio radius at wavelengths between 1.2 and 11 cm performed with the Bonn 100 m-telescope. In combination with former measurements of the centre-to-limb variation of the solar brightness these observations are discussed in terms of atmospheric models. We consider the solar disk to be covered by arches at low latitudes, while at the poles coronal holes are located. The temperature dependence on height is taken from EUV-line intensities, hydrostatic equilibrium is adopted, spicules are assumed to be responsible for the relatively low brightening. The interpretation of our measurements demands certain values of the brightness temperature of spicules as a function of wavelength within a modest interval.     

Variation of Spectral Radiance of the Zenith Sky During the Annular Eclipse on May 21, 2012

The absolute brightness of the zenith sky was measured using a simple calibrated spectrometer during the annular solar eclipse event on May 21, 2012 in Fujioka City, Japan (36.2924°N, 139.0823°E). The sensitivity of the spectrometer was calibrated as a function of wavelength between 400 and 700 nm with an integral sphere. The brightness of the sky decreased to 6 % of its usual condition at the maximum magnitude of the annular eclipse of 0.95 for all wavelengths. The curve describing the variation of sky brightness accords well with the total luminosity of the solar disk estimated by a simple model that accounts for the limb darkening effect. This study provides zenith sky radiance as a function of wavelength and solar elevation angle, which is useful for the investigation of new optical instruments for atmospheric studies.     

Observations of Saturn at a wavelength of 49.5 cm

Radio emission from the planet Saturn was detected and measured by an unusually efficient observing technique at a wavelength of 49.5cm. The corresponding equivalent disk brightness temperature was hence determined to be 390 ± 65°K, providing further evidence for a mild enhancement in the emission at long wavelengths. It is pointed out that the currently available measurements of the disk brightness temperature in the wavelength range 1mm-1m are, as a whole, inadequate for estimating with confidence the detailed shape of the spectrum and that the exiguous, long wavelength observations should be supplemented with more and accurate measurements.     

A recalibration of the quiet Sun millimeter spectrum based on the Moon as an absolute radiometric standard

The solar millimeter continuum between 1 and 20 mm is recalibrated using observations of the average lunar brightness temperature at the center of lunar disk and new Moon brightness temperatures. The solar data are placed on a common scale according to the average lunar brightness temperature distribution proposed by Linsky. A least-squares parabolic regression curve is proposed for the solar millimeter continuum. A small departure from this regression curve near 8 mm may indicate the existence of an absorption feature.Staff member, Laboratory Astrophysics Division, National Bureau of Standards.     

The 3.3-mm brightness distribution of the quiet sun

Center-to-limb brightness distribution measurements of the quiet Sun at a wavelength of 3.3 mm show that there is a slight limb brightening at this wavelength. Within the measurement accuracy of the system used, the limb brightening function is only radially dependent. At 3.3 mm, the measurements are consistent with a solar brightness curve that is flat to about r = 0.8 with a rapid increase to a peak value of about 1.3 at the limb. The results show that most of the central disk 3.3-mm emission comes from a thin layer of relatively constant temperature about 1500–3500 km above the photosphere. This work was supported by the U.S. Air Force under Contract No. F04701-69-C-0066.     

Ultraviolet ion chamber measurements of the solar minimum brightness temperature

The solar ultraviolet flux in the wavelength bands 1580–1640 Å and 1430–1470 Å (FWHM) has been measured using photon ion chambers carried on the satellite WRESAT I (1967-118A). These observations of the integrated ultraviolet flux from the entire disk indicate a value of (4570 ± 50) K for the solar temperature minimum. The results are compared with other estimates of the minimum value of the solar brightness temperature.Died August, 1971.