The book consists of short accounts describing 102 representative publications that had a significant impact during NBS/NIST's first century. These 102 were chosen, out of tens of thousands that have appeared in print, to illustrate the range of activities covered by the publication program. Many others are equally deserving of mention and, in fact, some of these are listed in the bibliographies accompanying each account. The final selection was made by a committee of representatives of the major units in the current NIST organizational structure plus the Standards Alumni Association, which looked especially at candidate publications from the early days of NBS. This committee considered over 400 nominations from NIST staff and alumni in arriving at the final 102. An effort was made to cover the most significant NIST/NBS programs, including those in which formal publications are not the dominant communication mechanism. The selected publications are arranged in the book by time periods. Those from the first half of the century are grouped into two periods, 1901-1930 and 1931-1950. The publications from the second half are listed by decade. Within each decade certain papers on related topics have been grouped together. An index of subjects and individuals appears at the end. Certain important works were not considered for this book, even though they had significant input from staff members, because they were not, strictly speaking, NBS/NIST publications. Among these is the International Critical Tables [3], a seven-volume series prepared in the 1920s whose contributors included hundreds of scientists from all parts of the world, in addition to many NBS staff members. The Editor-inChief was E. W. Washburn, Chief of the NBS Chemistry Division, and the Editorial Board included G. K. Burgess, Director of NBS. The preface, written on behalf of the National Research Council (the official publisher), gives special acknowledgment to NBS for its leadership. The International Critical Tables was the definitive source for accurate data for the next 30 to 40 years, used at every level of science and technology, from undergraduate teaching to engineering design. It remained in print until about 1980, and it is still found (and still used as a reference) in every major library of the physical and engineering sciences. Also in this category are countless standards documents in which NBS/NIST staff played a major role but which were published by ASTM, ANSI, ASHRAE, and other national standards organizations as well as by international groups such as ISO, CODATA, IUPAC, and the various committees of the International Bureau of Weights and Measures (BIPM). Such documents tend to be anonymous in the sense of bibliographic citations, but Bureau representatives are frequently among the prime movers in the committees that prepare them. As a particular example, NBS/NIST has made strong input to the Consultative Committee on Units (CCU), the group responsible for promulgation of the International System of Units (SI), the “modern metric system" [4]. Special mention should also be given to the Fundamental Physical Constants, a continuing project in which Barry N. Taylor and other NIST physicists have played the dominant role over the last quarter of the century. Their set of CODATA Recommended Values of the Fundamental Physical Constants [5] has been universally adopted for worldwide use. For those interested in the full history of NIST, several publications are available. The 1905 paper by Rosa [2], which summarizes the work during the first few years, has already been mentioned. Three official histories have been written. Measures for Progress, by Rexmond Cochrane, covers the first 50 years [6]. Elio Passaglia's A Unique Institution follows with coverage of the 1950-1969 period [7]. James Schooley rounded out the history of the first century with Responding to National Needs: The National Bureau of Standards Becomes the National Institute of Standards and Technology (1969-1993) [8]. These books give extensive administrative, financial, and personnel details, as well as summaries of the technical work during each period. The contributions of NBS during the two world wars, which could not be published at the time the work was done, is very well documented in two reports which make fascinating reading. The book War Work of the Bureau of Standards [9] describes about 200 projects undertaken during World War I; these range from studies of shoe leather and metal for military identification tags to utilization of the Bureau's expertise in spectroscopy to improve methods of aerial photography. Bureau metallurgists were particularly active in helping the military develop specifications and testing methods for items ranging from armor plate and steel helmets to horseshoe nails. The story for the second world war is given in NBS War Research. The National Bureau of Standards in World War II [10], edited by former Director Lyman J. Briggs. While the best known NBS contribution was the proximity fuze (described in more detail in one of the accounts in this book), almost every part of the organization became involved in war work of some kind. Director Briggs was appointed by President Roosevelt in 1939 as chairman of the first committee to investigate the feasibility of building an atomic bomb; ultimately, about 60 NBS staff members worked on the bomb project. NBS made a major contribution in developing methods to purify uranium and graphite, which was used as a moderator in the reactors that produced plutonium, and the first experiments on separating uranium isotopes by thermal diffusion were done in a Bureau laboratory. The publications described in this book appeared in a variety of media, which is characteristic of NBS/NIST publications as a whole. Many appeared in scholarly journals of scientific and engineering societies; a few came out as books through commercial publishers. The rest appeared in one or another of the Bureau's own publication series. It may be useful to describe these briefly. The Journal of Research of the National Institute of Standards and Technology, which traces its origin to 1928, publishes research papers by staff members in all fields covered by NIST. Larger works of long term-interest have appeared in the Monograph and Handbook series, and the Special Publication series is available for works that do not conveniently fit into other categories. Interim or transient reports appear as Technical Notes or NISTIRS (where "I" can mean either Internal or Interagency). Some NIST programs have their own series, e.g., the Building Science Series, the National Standard Reference Data Series (NSRDS-NBS), the Applied Mathematics Series (AMS), and the Federal Information Processing Standards (FIPS). The Bureau has also joined outside organizations in certain publication series, for example, the Journal of Physical and Chemical Reference Data, started in 1972 as a joint endeavor of NBS, the American Institute of Physics, and the American Chemical Society. This journal has published almost 600 critically evaluated data compilations, submitted both by NIST scientists and outside authors, as well as 21 supplementary hard-cover monographs. The classic documents described in this book are traditional publications on paper. The last decade of NBS/NIST's first century saw the start of a major revolution in communications with the emergence of electronic publishing. NIST scientists are already making heavy use of this medium, and the bibliographies in this book show many references to Internet sites. A number of NIST Laboratories and Programs have established World Wide Web sites which receive heavy use by the scientific community. This form of publication is developing too fast to give a comprehensive list of sites, but the following examples convey the flavor of NIST's current efforts: · Physical Reference Data <http://physics.nist.gov/PhysRefData/fundamental constants, atomic and molecular spectra, x-ray attenuation, and radiation dosimetry data. • Chemistry WebBook <http://webbook.nist.gov evaluated data on thermal properties and spectra of thousands of chemical compounds, including the heavily used NIST/EPA/NIH Mass Spectral Library. • Digital Library of Mathematical Functions <http://dlmf.nist.gov>under development as a modern version of the 1964 classic Handbook of Mathematical Functions. • Fire Research Information Services <http://fris.nist.gov>provides access to fire test data, publications, and fire modeling programs. • MSEL Data on the Web <http://www.msel.nist.gov/dataontheweb.html>mechanical, thermal, and chemical properties of ceramics, metals, and polymers. Protein Data Bank <http://nist.rcsb.org/pdb>-3-D crystal structure of proteins. These and other NIST web sites are already accessed thousands of times each day, and use of the sites is growing rapidly. As it enters its second century, we can expect the National Institute of Standards and Technology to take full advantage of the new opportunities for disseminating the results of its work. David R. Lide Bibliography [1] Sir William Thomson (Lord Kelvin), Lecture to the Institution of Civil Engineers (May 3, 1883), in Popular Lectures and Addresses Vol. 1, p. 80, Macmillan and Co., London & New York, (1891). [2] Edward B. Rosa, The National Bureau of Standards and its Relation to Scientific and Technical Laboratories, Science 21, 161-174 (1905). [3] Edward W. Washburn (ed.), International Critical Tables of Numerical Data of Physics, Chemistry, and Technology; published for National Research Council by McGraw-Hill Book Company, New York (1926/1932). [4] Le Système International d'Unités (SI), 5o Édition, Bureau International des Poids et Mesures, Sevres, France (1985) [includes English translation]; see also Barry N. Taylor, Guide for the Use of the International System of Units (SI), NIST Special Publication 811, National Institute of Standards and Technology, Gaithersburg, MD (1995). [5] Peter J. Mohr and Barry N. Taylor, CODATA Recommended Values of the Fundamental Physical Constants: 1998, J. Phys. Chem. Ref. Data 28, 1713-1852 (1999). [6] Rexmond C. Cochrane, Measures for Progress. A History of the National Bureau of Standards, NBS Special Publication 275, U.S. Government Printing Office, Washington, DC (1966). [7] Elio Passaglia, A Unique Institution. The National Bureau of Standards, 1950-1969, NIST Special Publication 925, U.S. Government Printing Office, Washington, DC (1999). [8] James Schooley, Responding to National Needs: The National Bureau of Standards Becomes the National Institute of Standards and Technology (1969-1993), NIST Special Publication 955, U.S. Government Printing Office, Washington, DC (2000). [9] War Work of the Bureau of Standards, Miscellaneous Publications of the Bureau of Standards, No. 46, U.S. Government Printing Office, Washington, DC (1921). [10] Lyman J. Briggs (ed.), NBS War Research. The National Bureau of Standards in World War II, U.S. Department of Commerce (1949). The Absolute Measurement of Inductance This paper [1] represents the first Bureau of Standards scientific contribution of Edward B. Rosa, Chief Physicist and first Division Chief (Electricity Division) of NBS. Rosa was an outstanding and prolific physicist and writer, having provided the basis for the century-long international pre-eminence of NBS/NIST in electrical metrology. He authored or co-authored some 75 NBS papers ranging in topic from fundamental electrical measurements through practical papers on electromagnetic calculations and applied measurement techniques to descriptions of basic work in electrolysis and photometrics. As an example of his breadth of interest, Rosa invented an ingenious respiration calorimeter with Wilbur O. Atwater that was to prove highly useful in subsequent pioneer investigations of food values and problems of nutrition in this country. Towards the end of his career he carried out an exhaustive study of government research and its relation to the federal budget, which had an influence on the establishment of the Bureau of the Budget, the predecessor of the present Office of Management and Budget. His name is pronounced "Ro-zay," with emphasis on the second syllable. The first Director of the Bureau, Samuel Wesley Stratton, found that the most urgent task of this new appointment was to find an outstanding individual to plan and direct the electrical research program that had dominated the arguments for the creation of the Bureau. His attention was drawn to Edward Bennett Rosa. Rosa (1861-1921), of Dutch ancestry, had taught physics and chemistry after getting his B.S. degree at Wesleyan University in Connecticut and then entered the Johns Hopkins University as a graduate student in physics under Henry A. Rowland. Receiving his doctorate in 1891, he returned to Wesleyan as associate professor of physics, becoming full professor the next year. Stratton hired him as a physicist at $3,500, and a decade later, with his electrical group firmly established as the premier division of the Bureau, he was made chief physicist. The paper [1] reflects an early commitment to outstanding work in the electrical metrology field by a fledgling organization. This was in response to overwhelming needs in U.S. industry for a single, consistent basis for measurements of power, current, impedance, and voltage to support the electrical power industry, the transition of manufacturing from mechanical to electrical power, and the burgeoning electrical instruments industry, as well as the growing position of the U.S. in world trade and science. At the 1908 International Conference on Electrical Units and Standards in London, it was recommended that representatives of the National Measurement Institutes (i.e., counterparts to NBS/NIST) should meet and agree on new values of international units as defined by the mercury ohm and silver voltameter. In April and May 1910, the International Technical Committee met in Washington at NBS. Scientists from Germany, France, and Great Britain brought standard resistors and standard cells that had been carefully evaluated in terms of their national units. As Chief of the Electricity Division, Rosa headed this committee. Comparisons made at the meeting showed that the resistance unit represented by the German standards was only 1 × 10-5 larger than that of the British. Results of work then in progress under Rosa were in reasonable agreement, and the committee recommended that all countries use, as the international ohm, the mean of the values found by Germany and Great Britain [2,3]. The present NIST impedance calibration laboratory (ICL) promotes the use of the SI units farad and henry through capacitance and inductance calibrations for customers, both inside and outside NIST. The ICL provides calibrations of nominal-valued capacitors in the range from 0.001 pF to 1 μF in the frequency range from 100 Hz to 10 kHz. Customers include aerospace companies, instrumentation companies, the U.S. armed forces, secondary calibration laboratories, and other U.S. and foreign national laboratories. The ICL also provides capacitance calibrations at 1 kHz that are used by the high-frequency calibration laboratories at NIST for their calibrations at frequencies above 1 MHz. The SI impedance unit, the henry, is obtained from the capacitance and resistance units, the farad and ohm. The ICL provides calibrations of inductors in the range 50 mHz to 10 Hz in the frequency range from 65 Hz to 10 kHz. The inductance value is found using the Maxwell-Wien bridge [4], which derives the value of the inductor by comparison against two resistors and a capacitor. Prepared by A-M. Jeffrey, N. B. Belecki, and J. F. Mayo-Wells, based on The Ampere and Electrical Units [5], authored by members of the Electricity Division. Bibliography [1] Edward B. Rosa and Frederick W. Grover, The Absolute Measurement of Inductance, Bull. Bur. Stand. 1, 125-152 (1905). [2] F. B. Silsbee, Establishment and maintenance of the electrical units, NBS Circular 475, National Bureau of Standards, Washington, DC (1949). [3] Report to the International Committee on Electrical Units and Standards, NBS Miscellaneous Publications 16, National Bureau of Standards, Washington, DC (1912). [4] Thomas L. Zapf, Calibration of inductance standards in the Maxwell-Wien bridge circuit, J. Res. Natl. Bur. Stand. 65C, 183-188 (1961). [5] R. E. Elmquist, M. E. Cage, Y-H. Tang, A-M. Jeffery, J. R. Kinard, R. F. Dziuba, N. M. Oldham, and E. R. Williams, The Ampere and Electrical Units, J. Res. Natl. Inst. Stand. Technol., January-February (2001). |