Coordination of minor planet orbital studies: Past,present and future

A brief account is given of the coordination of astrometric observations and orbital studies of minor planets, particularly with regard to the role played in the past by the Astronomisches Rechen-Institut. The current situation is surveyed and thoughts are presented on future requirements.Presented at Frickefest, a colloquium held in Austin, Texas, on March 27, 1985, in honor of Walter Fricke on the occasion of his retirement as director of the Astronomisches Rechen-Institut in Heidelberg.     

The struve dynasty in the history of astronomy in Ukraine

The impact of the Struve astronomical dynasty on the development of astronomy in Ukraine in the 19th–20th centuries is studied. First of all, the role of F.G.W. Struve and O.V. Struve in the formation of astronomical research programs at the observatories at the Kharkiv, Kyiv, Odesa, and Mykolayiv, in equipping the observatories with instruments, in practical training of astronomers as well as in the organization of astronomy-geodetic expeditions (19th century). Particular attention is paid to the activity of L.O. Struve as a director of the Astronomical observatory of Kharkiv University and his works conducted together with G.A. Shajn and B.P. Gerasimovich (20th century) as well as to the impact of his scientific and public activity, including one he made as a President of IAC, on the development of astronomy in the Soviet Union and Ukraine. A range of important documents from the archives of Russian Academy of Sciences, Institute of astronomy and State Archive of Ukraine are cited. The article was translated by the authors.     

Karl Knorre,the first astronomer of Nikolaev Observatory (on the occasion of his bicentenary)

Karl Friedrich Knorre (1801–1883) was the son of Ernst Knorre, an astronomy professor at Dorpat university. During his education at Dorpat university, he became acquainted with Wilhelm Struve, the future director of Pulkovo observatory. Because of Knorre's passion for astronomy, Struve recommended him to the post of director of the planned naval observatory in Nikolaev. From its foundation in 1821, Karl Knorre was director of the Nikolaev Naval (and later Astronomical) Observatory. He carried out star position observations with the meridian circle, worked as an astronomy instructor for sea navigators, compiled the fifth section of the star charts of the Berlin Academy of Sciences and lead all hydrographic determinations on the Azov and Black seas. In 1871, Karl Nikolaev Observatory, and moved to Berlin.     

第24届IAU大会决议和天体测量的前沿课题

阐明了IAU决议对天文学发展的作用，并扼要地介绍了第24届IAU大会通过的三项决议，简要评述了2000－2003年基本天体测量的前沿课题，并对我国基本天体测量未来的优先发展领域提出了几点建议。     

Reminiscences of a Japanese Contemporary

It was in 1936 when a young Czech student of age 22 came to Japan through Siberia for participating in the solar eclipse expedition. Since then, he had visited us 13 times until 1993 (when he passed away). At each visit his lectures were vivid for us and had strong impact on the audience. Needless to say, it was the late Professor Zdeněk Kopal. In this brief presentation first I reveal my reminiscences of our common time in Manchester and Japan as a contemporary, and second I make some remarks on my activities for the Japanese Official Development Assistance (ODA) for astronomy in developing countries, in a similar way like Professor Kopal contributed in later years to the development of astronomy mainly in middle-east countries.     

Photometry: New techniques,an introduction

In most fields of observational astronomy, the new techniques we have now and are developing offer great potentials for more and better data, and thus to increased understanding of the universe about us. Photometry, as perhaps the most fundamental of all the observational tools, is no exception. The next years will be most exciting, but we must always be aware of the potential pitfalls involved with new technology. In fact, the new technologies must be handled with great care in order to insure that our data is really first class. New generation small telescopes can be a great asset, offering great complementarity to the new large telescopes and to space astronomy.Operated by AURA, Inc. under cooperative agreement with the National Science Foundation, Washington D.C.     

VLT‐CRIRES: “Good Vibrations” Rotational‐vibrational molecular spectroscopy in astronomy

Near‐Infrared high spectral and spatial resolution spectroscopy offers new and innovative observing opportunities for astronomy. The “traditional” benefits of IR‐astronomy – strongly reduced extinction and availability of adaptive optics – more than offset for many applications the compared to CCD‐based astronomy strongly reduced sensitivity. Especially in high resolution spectroscopy interferences by telluric lines can be minimized. Moreover for abundance studies many important atomic lines can be accessed in the NIR. A novel spectral feature available for quantitative spectroscopy are the molecular rotational‐vibrational transitions which allow for fundamentally new studies of condensed objects and atmospheres. This is also an important complement to radio‐astronomy, especially with ALMA, where molecules are generally only observed in the vibrational ground state. Rot‐vib transitions also allow high precision abundance measurements – including isotopic ratios – fundamental to understand the thermo‐nuclear processes in stars beyond the main sequence. Quantitative modeling of atmospheres has progressed such that the unambiguous interpretation of IR‐spectra is now well established. In combination with adaptive optics spectro‐astrometry is even more powerful and with VLT‐CRIRES a spatial resolution of better than one milli‐arcsecond has been demonstrated. Some highlights and recent results will be presented: our solar system, extrasolar planets, star‐ and planet formation, stellar evolution and the formation of galactic bulges (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Venus 1882 and Jean‐Charles Houzeau

This paper focuses on one particular type of telescope – the heliometer – designed for solving one specific basic problem in astronomy: the scale factor of the solar system. One very special instrument of this type was the “heliometer with unequal focal lengths” designed by the Belgian astronomer Jean‐Charles Houzeau for the 1882 transit of Venus. We also draw attention to the most interesting personality of Houzeau, and to his social engagement that went much beyond his work as a scientist (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

From cosmic ray physics to cosmic ray astronomy: Bruno Rossi and the opening of new windows on the universe

Bruno Rossi is considered one of the fathers of modern physics, being also a pioneer in virtually every aspect of what is today called high-energy astrophysics. At the beginning of 1930s he was the pioneer of cosmic ray research in Italy, and, as one of the leading actors in the study of the nature and behavior of the cosmic radiation, he witnessed the birth of particle physics and was one of the main investigators in this fields for many years. While cosmic ray physics moved more and more towards astrophysics, Rossi continued to be one of the inspirers of this line of research. When outer space became a reality, he did not hesitate to leap into this new scientific dimension. Rossi’s intuition on the importance of exploiting new technological windows to look at the universe with new eyes, is a fundamental key to understand the profound unity which guided his scientific research path up to its culminating moments at the beginning of 1960s, when his group at MIT performed the first in situ measurements of the density, speed and direction of the solar wind at the boundary of Earth’s magnetosphere, and when he promoted the search for extra-solar sources of X rays. A visionary idea which eventually led to the breakthrough experiment which discovered Scorpius X-1 in 1962, and inaugurated X-ray astronomy.     

The contribution of astrolabes to the establishment of reference systems

At present there are several types of modern astrolabes being able to observe objects from fundamental and other stars to the brightest object of the solar system, the sun itself. The paper reviews the programs, the sujects of investigation, the adjustement of the reference system, the rôle of the IAU and the place of the astrolabes. As in many other fields, an intensive cooperation is needed.George Teleki invited me to write this review paper in a letter which was to be the last one he wrote to me. I dedicate it to the memory of this man whose life was devoted to astrometry, the fundamental science which is the basis of all astronomy.     

The beginnings of decameter radio astronomy: pioneering works of Semen Ya. Braude and his followers in Ukraine

S.Ya. Braude (1911–2003) was the well‐known radio astronomer, one of the founders of low‐frequency astronomical research in the world, in particular in the former Soviet Union. He began to work in this field of science in 1957, in Kharkiv city (Ukraine), from the design and manufacturing small decameter interferometer ID‐1 and ID‐2. Since that time Braude and his team have developed more sophisticated radio decameter telescopes as UTR‐1 and UTR‐2 (the largest in the world till now) as well as the first decameter VLBI network URAN. They have obtained some important pioneering results about low‐frequency radio emission of objects in our Solar system, Galaxy and Metagalaxy by means of these telescopes. In this paper the key events of early history of decameter radio astronomy research in the former USSR are mentioned with emphasizing the role of S. Braude. For the period of 1957–1962, the quotations of Braude's Personal Diary (2003) are first laying open to the public. The most important results obtained by S.Ya. Braude and his followers as well as perspectives of decameter radio astronomy in Ukraine and in the world are highlighted briefly. (© 2007 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Space-based aperture array for ultra-long wavelength radio astronomy

The past decade has seen the advent of various radio astronomy arrays, particularly for low-frequency observations below 100 MHz. These developments have been primarily driven by interesting and fundamental scientific questions, such as studying the dark ages and epoch of re-ionization, by detecting the highly red-shifted 21 cm line emission. However, Earth-based radio astronomy observations at frequencies below 30 MHz are severely restricted due to man-made interference, ionospheric distortion and almost complete non-transparency of the ionosphere below 10 MHz. Therefore, this narrow spectral band remains possibly the last unexplored frequency range in radio astronomy. A straightforward solution to study the universe at these frequencies is to deploy a space-based antenna array far away from Earths’ ionosphere. In the past, such space-based radio astronomy studies were principally limited by technology and computing resources, however current processing and communication trends indicate otherwise. Furthermore, successful space-based missions which mapped the sky in this frequency regime, such as the lunar orbiter RAE-2, were restricted by very poor spatial resolution. Recently concluded studies, such as DARIS (Disturbuted Aperture Array for Radio Astronomy In Space) have shown the ready feasibility of a 9 satellite constellation using off the shelf components. The aim of this article is to discuss the current trends and technologies towards the feasibility of a space-based aperture array for astronomical observations in the Ultra-Long Wavelength (ULW) regime of greater than 10 m i.e., below 30 MHz. We briefly present the achievable science cases, and discuss the system design for selected scenarios such as extra-galactic surveys. An extensive discussion is presented on various sub-systems of the potential satellite array, such as radio astronomical antenna design, the on-board signal processing, communication architectures and joint space-time estimation of the satellite network. In light of a scalable array and to avert single point of failure, we propose both centralized and distributed solutions for the ULW space-based array. We highlight the benefits of various deployment locations and summarize the technological challenges for future space-based radio arrays.     

Fundamental coordinate ties using laser ranging data

One of the main goals of fundamental astronomy is to allow us to locate ourselves accurately in space and time. Each observational technique cannot supply all of the answers all of the time, and the joining of results from different techniques requires a true understanding of the particular reference frame which underlies each one. In this paper we try to state the present situation in our attempts to tie artificial satellite and lunar laser ranging data through the construction of stations designed to make both kinds of observations. This type of development strengthens both data types and eases their combination with other data types.     

Richard Christopher Carrington: Briefly Among the Great Scientists of His Time

We recount the life and career of Richard Christopher Carrington (1826??C?1875) and explore his pivotal relationship with Astronomer Royal George Biddell Airy. Carrington was the pre-eminent solar astronomer of the 19th century. During a ten year span, he determined the position of the Sun??s rotation axis and made the following discoveries: i)?the latitude variation of sunspots over the solar cycle, ii)?the Sun??s differential rotation, and iii)?the first solar flare (with Hodgson). Due to the combined effects of family responsibilities, failure to secure a funded position in astronomy (reflecting Airy??s influence), and ill health, Carrington??s productive period ended when he was at the peak of his powers.     

Novae as Thermonuclear Laboratories

Fred Hoyle undertook a study of observational consequences of the thermonuclear paradigm for the nova event in the years following his 1972 resignation from Cambridge University. The most fruitful of these have been in the areas of gamma-ray astronomy, by which one attempts to measure the level of radioactivity in the nova envelope, and of presolar grain studies in laboratories, by which one measures anomalous isotopic ratios that fingerprint condensation in the thermonuclear event. This work summarizes progress with these two astronomical measures of the novae. This revised version was published online in August 2006 with corrections to the Cover Date.     

中外大学天文学教材评述

大学天文学是高校天文学专业最重要的专业基础课程, 主要 讲授天文学的基础知识和发展全貌, 具有覆盖面广、知识点多的特点. 教材的质量对于帮助学生理解天文学的基本原理和方法、提高学术水平和科学素养起到关键作用. 对于非天文学专业的学生和天文爱好者, 天文学教材也是拓展科学知识和认知宇宙的重要途径. 我国的大学天文学教材建设与欧美发达国家相比在数量和质量上还有不小差距. 梳理了国内外较有代表性的大学天文学教材, 评述其特色、优势和有待改进之处, 比较中外教材在内容和写法上的异同. 通过分析国外优秀教材的编著理念、方法和技巧, 为我国未来天文学教材建设提供参考建议.     

中外大学天文学教材评述

大学天文学是高校天文学专业最重要的专业基础课程, 主要 讲授天文学的基础知识和发展全貌, 具有覆盖面广、知识点多的特点. 教材的质量对于帮助学生理解天文学的基本原理和方法、提高学术水平和科学素养起到关键作用. 对于非天文学专业的学生和天文爱好者, 天文学教材也是拓展科学知识和认知宇宙的重要途径. 我国的大学天文学教材建设与欧美发达国家相比在数量和质量上还有不小差距. 梳理了国内外较有代表性的大学天文学教材, 评述其特色、优势和有待改进之处, 比较中外教材在内容和写法上的异同. 通过分析国外优秀教材的编著理念、方法和技巧, 为我国未来天文学教材建设提供参考建议.     

行星天文学的重要地位及其热点

对1995年至2001年《Natue》和《Science》上发表的天文学论文的统计表明，行星天文学领域的论文数量明显超过天文学的其它分支学科，占天文学总论文数的1/3左右。从这个角度来看，行星天文学是天文学最活跃和重要的分支学科之一。对这些论文具体内容的分析可以给出当前行星天文学领域的若干热点问题。相比之下，我国对这一重要领域的关注和投入还远远不够。     

Frederick C. Leonard: A history and personal recollections

As a child Frederick C. Leonard displayed such a precocious aptitude for astronomy that he became known as “Chicago's Boy Astronomer.” But within a decade after receiving his Ph.D., his interests had turned to meteorites. He persuaded Harvey Nininger to help him found the Society for Research on Meteorites, later renamed The Meteoritical Society, in 1933—a time when the study of meteorites was not considered a worthy pursuit of serious scientists. He nurtured the Society and held it together through the Great Depression, World War II, a destructive feud, and a significant personal and family crisis. He obtained legitimacy and affiliation for the Society with mainstream scientific organizations. He was its first President, and he was Editor of its publications from the Society's founding until a year before his death in 1960. Through it all he was a persistent advocate for the importance of the study of meteorites and the legitimacy of meteoritics as a valuable field of science.     

Fred Hoyle and the Anglo-Australian telescope

The 150-inch telescope on Siding Spring mountain in New South Wales, Australia, stands as a reminder of Fred Hoyle's genius in aspects of astronomy that surprise those who know him only as a theoretician, as one who did not himself use the telescopes that produced the all-important data for his theoretical work. This article shows another side of Fred's abilities – that he could immerse himself in the techniques of telescope building, from mount to mirror, and overcome the many hurdles that had to be faced. This revised version was published online in August 2006 with corrections to the Cover Date.