Outline of academic disciplines
An academic discipline or field of study is a branch of knowledge and researched as part of higher education. A scholar's discipline is defined by the university faculties and learned societies to which she or he belongs and the academic journals in which she or he publishes research. Disciplines vary between well-established ones that exist in all universities and have well-defined rosters of journals and conferences and nascent ones supported by only a few universities and publications. A discipline may have branches, these are called sub-disciplines. There is no consensus on how some academic disciplines should be classified, for example whether anthropology and linguistics are disciplines of the social sciences or of the humanities; the following outline is provided as topical guide to academic disciplines. Biblical studies Religious studies Biblical Hebrew, Biblical Greek, Aramaic Buddhist theology Christian theology Anglican theology Baptist theology Catholic theology Eastern Orthodox theology Protestant theology Hindu theology Jewish theology Muslim theology Biological anthropology Linguistic anthropology Cultural anthropology Social anthropology Archaeology Accounting Business management Finance Marketing Operations management Edaphology Environmental chemistry Environmental science Gemology Geochemistry Geodesy Physical geography Atmospheric science / Meteorology Biogeography / Phytogeography Climatology / Paleoclimatology / Palaeogeography Coastal geography / Oceanography Edaphology / Pedology or Soil science Geobiology Geology Geostatistics Glaciology Hydrology / Limnology / Hydrogeology Landscape ecology Quaternary science Geophysics Paleontology Paleobiology Paleoecology Astrobiology Astronomy Observational astronomy Gamma ray astronomy Infrared astronomy Microwave astronomy Optical astronomy Radio astronomy UV astronomy X-ray astronomy Astrophysics Gravitational astronomy Black holes Interstellar medium Numerical simulations Astrophysical plasma Galaxy formation and evolution High-energy astrophysics Hydrodynamics Magnetohydrodynamics Star formation Physical cosmology Stellar astrophysics Helioseismology Stellar evolution Stellar nucleosynthesis Planetary science Also a branch of electrical engineering Pure mathematics Applied mathematics Astrostatistics Biostatistics Academia Academic genealogy Curriculum Multidisciplinary approach Interdisciplinarity Transdisciplinarity Professions Classification of Instructional Programs Joint Academic Coding System List of fields of doctoral studies in the United States List of academic fields Abbott, Andrew.
Chaos of Disciplines. University of Chicago Press. ISBN 978-0-226-00101-2. Oleson, Alexandra; the Organization of knowledge in modern America, 1860-1920. ISBN 0-8018-2108-8. US Department of Education Institute of Education Sciences. Classification of Instructional Programs. National Center for Education Statistics. Classification of Instructional Programs: Developed by the U. S. Department of Education's National Center for Education Statistics to provide a taxonomic scheme that will support the accurate tracking and reporting of fields of study and program completions activity. Complete JACS from Higher Education Statistics Agency in the United Kingdom Australian and New Zealand Standard Research Classification Chapter 3 and Appendix 1: Fields of research classification. Fields of Knowledge, a zoomable map allowing the academic disciplines and sub-disciplines in this article be visualised. Sandoz, R. Interactive Historical Atlas of the Disciplines, University of Geneva
Chemistry is the scientific discipline involved with elements and compounds composed of atoms and ions: their composition, properties and the changes they undergo during a reaction with other substances. In the scope of its subject, chemistry occupies an intermediate position between physics and biology, it is sometimes called the central science because it provides a foundation for understanding both basic and applied scientific disciplines at a fundamental level. For example, chemistry explains aspects of plant chemistry, the formation of igneous rocks, how atmospheric ozone is formed and how environmental pollutants are degraded, the properties of the soil on the moon, how medications work, how to collect DNA evidence at a crime scene. Chemistry addresses topics such as how atoms and molecules interact via chemical bonds to form new chemical compounds. There are four types of chemical bonds: covalent bonds, in which compounds share one or more electron; the word chemistry comes from alchemy, which referred to an earlier set of practices that encompassed elements of chemistry, philosophy, astronomy and medicine.
It is seen as linked to the quest to turn lead or another common starting material into gold, though in ancient times the study encompassed many of the questions of modern chemistry being defined as the study of the composition of waters, growth, disembodying, drawing the spirits from bodies and bonding the spirits within bodies by the early 4th century Greek-Egyptian alchemist Zosimos. An alchemist was called a'chemist' in popular speech, the suffix "-ry" was added to this to describe the art of the chemist as "chemistry"; the modern word alchemy in turn is derived from the Arabic word al-kīmīā. In origin, the term is borrowed from the Greek χημία or χημεία; this may have Egyptian origins since al-kīmīā is derived from the Greek χημία, in turn derived from the word Kemet, the ancient name of Egypt in the Egyptian language. Alternately, al-kīmīā may derive from χημεία, meaning "cast together"; the current model of atomic structure is the quantum mechanical model. Traditional chemistry starts with the study of elementary particles, molecules, metals and other aggregates of matter.
This matter can be studied in isolation or in combination. The interactions and transformations that are studied in chemistry are the result of interactions between atoms, leading to rearrangements of the chemical bonds which hold atoms together; such behaviors are studied in a chemistry laboratory. The chemistry laboratory stereotypically uses various forms of laboratory glassware; however glassware is not central to chemistry, a great deal of experimental chemistry is done without it. A chemical reaction is a transformation of some substances into one or more different substances; the basis of such a chemical transformation is the rearrangement of electrons in the chemical bonds between atoms. It can be symbolically depicted through a chemical equation, which involves atoms as subjects; the number of atoms on the left and the right in the equation for a chemical transformation is equal. The type of chemical reactions a substance may undergo and the energy changes that may accompany it are constrained by certain basic rules, known as chemical laws.
Energy and entropy considerations are invariably important in all chemical studies. Chemical substances are classified in terms of their structure, phase, as well as their chemical compositions, they can be analyzed using the tools of e.g. spectroscopy and chromatography. Scientists engaged in chemical research are known as chemists. Most chemists specialize in one or more sub-disciplines. Several concepts are essential for the study of chemistry; the particles that make up matter have rest mass as well – not all particles have rest mass, such as the photon. Matter can be a mixture of substances; the atom is the basic unit of chemistry. It consists of a dense core called the atomic nucleus surrounded by a space occupied by an electron cloud; the nucleus is made up of positively charged protons and uncharged neutrons, while the electron cloud consists of negatively charged electrons which orbit the nucleus. In a neutral atom, the negatively charged electrons balance out the positive charge of the protons.
The nucleus is dense. The atom is the smallest entity that can be envisaged to retain the chemical properties of the element, such as electronegativity, ionization potential, preferred oxidation state, coordination number, preferred types of bonds to form. A chemical element is a pure substance, composed of a single type of atom, characterized by its particular number of protons in the nuclei of its atoms, known as the atomic number and represented by the symbol Z; the mass number is the sum of the number of neutrons in a nucleus. Although all the nuclei of all atoms belonging to one element will have the same
Andrew Ian Cooper
Andrew Ian Cooper FRS is Professor of Chemistry in the Department of Chemistry at the University of Liverpool. Cooper was educated at the University of Nottingham where he was awarded a PhD for research supervised by Martyn Poliakoff. After his PhD, Cooper held a number of postdoctoral research positions, he is an 1851 Research Fellowship and a Royal Society NATO Research Fellowship at the University of North Carolina at Chapel Hill where he worked with Joseph DeSimone. He held a Ramsay Memorial Research Fellowship at the Melville Laboratory for Polymer Synthesis at the University of Cambridge, working with Andrew Bruce Holmes, he moved to the University of Liverpool in 1999 where he has worked since. Cooper was elected a Fellow of the Royal Society in 2015, his nomination reads
The Corday–Morgan Medal and Prize is awarded by the Royal Society of Chemistry for the most meritorious contributions to experimental chemistry, including computer simulation. The prize was established by chemist Gilbert Morgan, who named it after his father Thomas Morgan and his mother Mary-Louise Corday. From the award's inception in 1949 until 1980 it was awarded by the Chemical Society. Up to three prizes are awarded annually; the Corday–Morgan medallists have included many of the UK's most successful chemists. Since 1949 they have been: Event data as RDF
Web of Science
Web of Science is an online subscription-based scientific citation indexing service produced by the Institute for Scientific Information maintained by Clarivate Analytics, that provides a comprehensive citation search. It gives access to multiple databases that reference cross-disciplinary research, which allows for in-depth exploration of specialized sub-fields within an academic or scientific discipline. A citation index is built on the fact that citations in science serve as linkages between similar research items, lead to matching or related scientific literature, such as journal articles, conference proceedings, etc. In addition, literature which shows the greatest impact in a particular field, or more than one discipline, can be located through a citation index. For example, a paper's influence can be determined by linking to all the papers. In this way, current trends and emerging fields of research can be assessed. Eugene Garfield, the "father of citation indexing of academic literature," who launched the Science Citation Index, which in turn led to the Web of Science, wrote: Citations are the formal, explicit linkages between papers that have particular points in common.
A citation index is built around these linkages. It identifies the sources of the citations. Anyone conducting a literature search can find from one to dozens of additional papers on a subject just by knowing one, cited, and every paper, found provides a list of new citations with which to continue the search. The simplicity of citation indexing is one of its main strengths. Web of Science is described as a unifying research tool which enables the user to acquire and disseminate database information in a timely manner; this is accomplished because of the creation of a common vocabulary, called ontology, for varied search terms and varied data. Moreover, search terms generate related information across categories. Acceptable content for Web of Science is determined by an evaluation and selection process based on the following criteria: impact, timeliness, peer review, geographic representation. Web of Science employs various analysis capabilities. First, citation indexing is employed, enhanced by the capability to search for results across disciplines.
The influence, impact and methodology of an idea can be followed from its first instance, notice, or referral to the present day. This technology points to a deficiency with the keyword-only method of searching. Second, subtle trends and patterns relevant to the literature or research of interest, become apparent. Broad trends indicate significant topics of the day, as well as the history relevant to both the work at hand, particular areas of study. Third, trends can be graphically represented. Expanding the coverage of Web of Science, in November 2009 Thomson Reuters introduced Century of Social Sciences; this service contains files which trace social science research back to the beginning of the 20th century, Web of Science now has indexing coverage from the year 1900 to the present. As of 3 September 2014, the multidisciplinary coverage of the Web of Science encompasses over 50,000 scholarly books, 12,000 journals and 160,000 conference proceedings; the selection is made on the basis of impact evaluations and comprise open-access journals, spanning multiple academic disciplines.
The coverage includes: the sciences, social sciences and humanities, goes across disciplines. However, Web of Science does not index all journals. There is a positive correlation between Impact Factor and CiteScore. However, analysis by Elsevier has identified 216 journals from 70 publishers to be in the top 10 percent of the most-cited journals in their subject category based on the CiteScore while they did not have Impact Factor, it appears that Impact Factor does not provide a comprehensive and an unbiased coverage of high quality journals. Similar results can be observed by comparing Impact Factor with SCImago Journal Rank. Furthermore, as of September 3, 2014 the total file count of the Web of Science was 90 million records, which included over a billion cited references; this citation service on average indexes around 65 million items per year, it is described as the largest accessible citation database. Titles of foreign-language publications are translated into English and so cannot be found by searches in the original language.
The Web of Science Core Collection consists of six online databases: Science Citation Index Expanded covers more than 8,500 notable journals encompassing 150 disciplines. Coverage is from the year 1900 to the present day. Social Sciences Citation Index covers more than 3,000 journals in social science disciplines. Range of coverage is from the year 1900 to the present day. Arts & Humanities Citation Index covers more than 1,700 arts and humanities journals starting from 1975. In addition, 250 major scientific and social sciences journals are covered. Emerging Sources Citation Index covers over 5,000 journals in the sciences, social science, humanities. Book Citation Index covers more than 60,000 editorially selected books starting from 2005. Conference Proceedings Citation Index covers more than 160,000 conference titles in the Sciences starting from 1990 to the present day Since 2008, the Web of Science hosts a number of regional citation indices; the Chinese Science Citation Database, produced in partnership with the Chinese Academy of Sciences, was the first one in a language other than English.
It was followed in 2013 by the SciELO Citation Index, covering Brazil, Portugal, the Cari
Chemical Abstracts Service
Chemical Abstracts Service is a division of the American Chemical Society. It is a source of chemical information. CAS is located in Columbus, United States. Chemical Abstracts is a periodical index that provides numerous tools such as SciFinder as well as tagged keywords, indexes of disclosures and structures of compounds in published scientific documents. 8,000 journals, technical reports, conference proceedings, new books, available in at least 50 different languages, are monitored yearly, as are patent specifications from 27 countries and two international organizations. Chemical Abstracts ceased print publication on January 1, 2010; the two principal databases that support the different products are Registry. CAplus consists of bibliographic information and abstracts for all articles in chemical journals worldwide, chemistry-related articles from all scientific journals and other scientific publications. Registry contains information on more than 130 million organic and inorganic substances, more than 64 million protein and Nucleic acid sequences.
The sequence information comes from GenBank, produced by the National Institutes of Health. The chemical information is produced by CAS, is prepared by the CAS Registry System, which identifies each compound with a specific CAS registry number, index name, graphic representation of its chemical structure; the assignment of chemical names is done according to the chemical nomenclature rules for CA index names, different from the internationally standard IUPAC names, according to the rules of IUPAC. CAS databases are available via two principal database systems, STN, SciFinder. STN International is operated jointly by CAS and FIZ Karlsruhe, is intended for information professionals, using a command language interface. In addition to CAS databases, STN provides access to many other databases, similar to Dialog. SciFinder is a database of chemical and bibliographic information. A client application, a web version was released in 2008, it has a graphics interface, can be searched for chemical structures and reactions as well as literature in chemistry and related disciplines.
The client version is for chemists in commercial organizations. Versions for both the Windows and Macintosh exist. SciFinder Scholar is for other academic institutions. CASSI stands for Chemical Abstracts Service Source Index. Since 2009, this print and CD-ROM compilation is available as a free online resource to look up and confirm publication information; the online CASSI Search Tool provides titles and abbreviations, CODEN, ISSN, date of first issue for a selected journal. Included is its language of text and language of summaries; the range is from 1907 to the present, including both serial and non-serial scientific and technical publications. The database is updated quarterly. Beyond CASSI lists abbreviated journal titles from early chemical literature and other historical reference sources. Chemical Abstracts developed from there; the use of volunteer abstractors was phased out in 1994. Chemical Abstracts has been associated with the American Chemical Society in one way or another since 1907.
For many years, beginning in 1909, the offices of Chemical Abstracts were housed in various places on the campus of Ohio State University in Columbus, Ohio. In 1965, CAS moved to a new 50-acre site on the west bank of the Olentangy River, just north of the Ohio State campus; this campus became well known in the Columbus area and famous as the site of many Columbus Symphony Orchestra pop concerts. In 2009, the campus consisted of three buildings. In 1907, William A. Noyes had enlarged the Review of American Chemical Research, an abstracting publication begun by Arthur Noyes in 1895, the forerunner of Chemical Abstracts; when it became evident that a separate publication containing these abstracts was needed, Noyes became the first editor of the new publication, Chemical Abstracts. E. J. Crane became the first Director of Chemical Abstracts Service when it became an American Chemical Society division in 1956. Crane had been CA editor since 1915, his dedication was a key factor in its long-term success.
Dale B. Baker became the CAS Director upon Crane's retirement in 1958. According to CAS, his visionary view of CAS' potential "led to expansion and the forging of international alliances with other information organizations." CAS was an early leader in the use of computer technology to disseminate information. The CAS Chemical Registry System was introduced in 1965. CAS developed a unique registry number to identify chemical substances. Agencies such as the U. S. Environmental Protection Agency and local fire departments around the world now rely on these numbers for the definite identification of substances. According to the ACS, this is the largest chemical substance database in the world. In 2007 the ACS designated its Chemical Abstracts Service subdivision an ACS National Historic Chemical Landmark in recognition of its significance as a comprehensive repository of research in chemistry and related sciences. Official website
Thomson Reuters Corporation is a Canadian multinational mass media and information firm. The firm was founded in Toronto, Canada, where it is headquartered at 333 Bay Street in Downtown Toronto. Thomson Reuters shares are cross listed on the Toronto Stock Exchange and the New York Stock Exchange. Thomson Reuters was created by the Thomson Corporation's purchase of the British company Reuters Group in April 2008, is majority owned by The Woodbridge Company, a holding company for the Thomson family. Thomson Reuters was ranked as Canada's "leading corporate brand" in the 2010 Interbrand Best Canadian Brands ranking. Thomson Reuters operates in more than 100 countries, has more than 45,000 employees; the company was founded by Roy Thomson in 1934 in Ontario as the publisher of The Timmins Daily Press. In 1953, Thomson moved to Scotland the following year, he consolidated his media position in Scotland in 1957 when he won the franchise for Scottish Television. In 1959, he bought the Kemsley Group, a purchase that gave him control of the Sunday Times.
He separately acquired the Times in 1967. He moved into the airline business in 1965, when he acquired Britannia Airways and into oil and gas exploration in 1971 when he participated in a consortium to exploit reserves in the North Sea. In the 1970s, following the death of Thomson, the company withdrew from national newspapers and broadcast media, selling the Times, the Sunday Times and Scottish Television and instead moved into publishing, buying Sweet & Maxwell in 1988; the company at this time was known as the International Thomson Organisation Ltd. In 1989, ITOL merged with Thomson Newspapers. In 1996, The Thomson Corporation acquired West Publishing, a purveyor of legal research and solutions including Westlaw; the Company was founded by Paul Julius Reuter in 1851 in London as a business transmitting stock market quotations. Reuter set up his "Submarine Telegraph" office in October 1851 and negotiated a contract with the London Stock Exchange to provide stock prices from the continental exchanges in return for access to London prices, which he supplied to stockbrokers in Paris, France.
In 1865, Reuters in London was the first organization to report the assassination of Abraham Lincoln. The company was involved in developing the use of radio in 1923, it was acquired by the British National & Provincial Press in 1941 and first listed on the London Stock Exchange in 1984. Reuters began to grow in the 1980s, widening the range of its business products and expanding its global reporting network for media and economic services: key product launches included Equities 2000, Dealing 2000-2, Business Briefing, Reuters Television for the financial markets, 3000 Series and the Reuters 3000 Xtra service; the Thomson Corporation acquired Reuters Group PLC to form Thomson Reuters on April 17, 2008. Thomson Reuters operated under a dual-listed company structure and had two parent companies, both of which were publicly listed — Thomson Reuters Corporation and Thomson Reuters PLC. In 2009, it unified its dual listed company structure and stopped its listing on the London Stock Exchange and NASDAQ.
It is now listed only as Thomson Reuters Corporation on the New York Stock Exchange and Toronto Stock Exchange. On February 13, 2013, Thomson Reuters announced it would cut 2,500 jobs to cut cost in its Legal and Risk division. On October 29, 2013, Thomson Reuters announced it would cut another 3,000 jobs in those same three divisions; the Thomson-Reuters merger transaction was reviewed by the U. S. Department of Justice and by the European Commission. On February 19, 2008, both the Department of Justice and the Commission cleared the transaction subject to minor divestments; the Department of Justice required the parties to sell copies of the data contained in the following products: Thomson's WorldScope, a global fundamentals product. The proposed settlement further requires the licensing of related intellectual property, access to personnel, transitional support to ensure that the buyer of each set of data can continue to update its database so as to continue to offer users a viable and competitive product.
The European Commission imposed similar divestments: according to the Commission's press release, "the parties committed to divest the databases containing the content sets of such financial information products, together with relevant assets and customer base as appropriate to allow purchasers of the databases and assets to establish themselves as a credible competitive force in the marketplace in competition with the merged entity, re-establishing the pre-merger rivalry in the respective fields."These remedies were viewed as minor given the scope of the transaction. According to the Financial Times, "the remedy proposed by the competition authorities will affect no more than $25m of the new Thomson Reuters group’s $13bn-plus combined revenues."The transaction was cleared by the Canadian Competition Bureau. In November 2009, The European Commission opened formal anti-trust proceedings against Thomson Reuters concerning a potential infringement of the EC Treaty's rules on abuse of a dominant market position.
The Commission investigated Thomson Reuters' practices in the area of real-time market datafeeds, in particular whether customers or competitors were prevented from translating Reuters Instrument Codes to alternative identification codes of other datafeed suppliers to the detriment of competition. In Dec