British Science Association

The British Science Association is a charity and learned society founded in 1831 to aid in the promotion and development of science. Until 2009 it was known as the British Association for the Advancement of Science. The current Chief Executive is Hannah Russell. The BSA's mission is to get more people engaged in the field of science by coordinating, delivering, and overseeing different projects that are suited to achieve these goals. The BSA "envisions a society in which a diverse group of people can learn and apply the sciences in which they learn." and is managed by a professional staff located at their Head Office in the Wellcome Wolfson Building. The BSA offers a wide variety of activities and events that both recognise and encourage people to be involved in science. These include the British Science Festival, British Science Week, the CREST Awards, For Thought, The Ideas Fund, along with regional and local events.

History

Foundation

The Association was founded in 1831 and modelled on the German Gesellschaft Deutscher Naturforscher und Ärzte. It was founded during post-war reconstruction after the Peninsula war to improve the advancement of science in England. The prime mover was Reverend William Vernon Harcourt, following a suggestion by Sir David Brewster, who was disillusioned with the elitist and conservative attitude of the Royal Society. Charles Babbage, William Whewell and J. F. W. Johnston are also considered to be founding members. The first meeting was held in York on Tuesday 27 September 1831 with various scientific papers being presented on the following days. It was chaired by Viscount Milton, president of the Yorkshire Philosophical Society, and "upwards of 300 gentlemen" attended the meeting. The Preston Mercury recorded that those gathered consisted of "persons of distinction from various parts of the kingdom, together with several of the gentry of Yorkshire and the members of philosopher societies in this country". The newspaper published the names of over a hundred of those attending and these included, amongst others, eighteen clergymen, eleven doctors, four knights, two Viscounts and one Lord.
From that date onwards a meeting was held annually at a place chosen at a previous meeting. In 1832, for example, the meeting was held in Oxford, chaired by Reverend Dr William Buckland. By this stage the Association had four sections: Physics, Chemistry, Geology and Natural History.
During this second meeting, the first objects and rules of the Association were published. Objects included systematically directing the acquisition of scientific knowledge, spreading this knowledge as well as discussion between scientists across the world, and to focus on furthering science by removing obstacles to progress. The rules established included what constituted a member of the Association, the fee to remain a member, and the process for future meetings. They also include dividing the members into different committees. These committees separated members into their preferred subject matter, and were to recommend investigations into areas of interest, then report on these findings, as well as progress in their science at the annual meetings.
Additional sections were added throughout the years by either splitting off part of an original section, like making Geography and Ethnology its own section apart from Geology in 1851, or by defining a new subject area of discussion, such as Anthropology in 1869.
A very important decision in the Association's history was made in 1842 when it was resolved to create a "physical observatory". A building that became well known as the Kew Observatory was taken on for the purpose and Francis Ronalds was chosen as the inaugural Honorary Director. Kew Observatory quickly became one of the most renowned meteorological and geomagnetic observatories in the world. The Association relinquished control of the Kew Observatory in 1871 to the management of the Royal Society, after a large donation to grant the observatory its independence.
In 1872, the Association purchased its first central office in London, acquiring four rooms at 22 Albemarle Street. This office was intended to be a resource for members of the Association.
One of the most famous events linked to the Association Meeting was an exchange between Thomas Henry Huxley and Bishop Samuel Wilberforce in 1860. Although it is often described as a "debate", the exchange occurred after the presentation of a paper by Prof Draper of New York, on the intellectual development of Europe with relation to Darwin's theory and the subsequent discussion involved a number of other participants. Although a number of newspapers made passing references to the exchange, it was not until later that it was accorded greater significance in the evolution debate.

Electrical standards

One of the most important contributions of the British Association was the establishment of standards for electrical usage: the ohm as the unit of electrical resistance, the volt as the unit of electrical potential, and the ampere as the unit of electrical current. A need for standards arose with the submarine telegraph industry. Practitioners came to use their own standards established by wire coils: "By the late 1850s, Clark, Varley, Bright, Smith and other leading British cable engineers were using calibrated resistance coils on a regular basis and were beginning to use calibrated condensers as well."
The undertaking was suggested to the BA by William Thomson, and its success was due to the use of Thomson's mirror galvanometer. Josiah Latimer Clark and Fleeming Jenkin made preparations. Thomson, with his students, found that impure copper, contaminated with arsenic, introduced significant extra resistance. The chemist Augustus Matthiessen contributed an appendix to the final 1873 report that showed temperature-dependence of alloys.
The unit system was "absolute" since it agreed with previously accepted units of work, or energy:

Committee on Mechanical Nomenclature

In 1888, at a meeting of the British Association in Bath, the Committee on Mechanical Nomenclature suggested three new units: the kine for velocity, equal to 1 centimeter per second; the bole for momentum, equal to 1 gram times 1 kine; and the barad for pressure, equal to 1 dyne per square centimeter. The London Electrical Review called the new units "an abomination, and wholly unnecessary" and attributed their creation to a "craze" for naming new units. William Henry Preece noted in 1891 that he had only seen one instance of use of the new units. By 1913, the units had fallen entirely out of use.

Other

The Association was parodied by English novelist Charles Dickens as 'The Mudfog Society for the Advancement of Everything' in The Mudfog Papers.
In 1878 a committee of the Association recommended against constructing Charles Babbage's analytical engine, due to concerns about the current state of the machine's lack of complete working drawings, the machine's potential cost to produce, the machine's durability during repeated use, how and what the machine will actually be utilized for, and that more work would need to be done to bring the design up to a standard at which it is guaranteed to work.
The Association introduced the British Association screw threads, a series of screw thread standards in sizes from 0.25 mm up to 6 mm, in 1882. The standards were based on the metric system, although they had to be re-defined in imperial terms for use by UK industry. The standard was modified in 1884 to restrict significant figures for the metric counterpart of diameter and pitch of the screw in the published table, as well as not designating screws by their number of threads per inch, and instead giving an approximation due to considerable actual differences in manufactured screws.
In 1889, a member of the Rational Dress Society, Charlotte Carmichael Stopes, stunned the proceedings of a meeting of the Association in Newcastle upon Tyne by organizing an impromptu session where she introduced rational dress to a wide audience, her speech being noted in newspapers across Britain.
In 1903, microscopist and astronomer Washington Teasdale died whilst attending the annual meeting.

Perception of science in the UK

The Association's main aim is to make science more relevant, representative and connected to society.
At the beginning of the Great Depression, the Association's focus began to shift their purpose to account for not only scientific progress, but the social aspects of such progress. In the Association's 1931 meeting, the president General Jan Christiaan Smuts ended his address by the proposal of linking science and ethics together but provided no means to actuate his ideas. In the following years, debate began as to whom the responsibilities of scientists fell upon. The Association adopted a resolution in 1934 that dedicated efforts to better balance scientific advancement with social progress.
J.D. Bernal, a member of the Royal Society and the British Association, wrote The Social Function of Science in 1939, describing a need to correctly utilize science for society and the importance of its public perception. The idea of the public perception of science was furthered in 1985 when the Royal Society published a report titled The Public Understanding of Science.
In the report, a committee of the Royal Society determined that it was scientists' duty to communicate to and educate the public. Lord George Porter, then president of the Royal Society, British Association, and director of the Royal Institution, created the Committee on the Public Understanding of Science, or COPUS, to promote public understanding of science.
Professor Sir George Porter became the president in September 1985. He won the Nobel Prize in Chemistry 1967 along with Manfred Eigen, and Ronald George Wreyford Norrish. When asked about the scientific literacy of Britain, he stated that Britain was the least educated country compared to all the other advanced countries. His idea to solve this problem would be to start scientific education for children at the age of 4. He says his reason for such an early age is because that is the age when children are the most curious, and implementing science at that age will help them gain curiosity towards all disciplines of science. When asked why public ignorance to science matters, his response was

It matters because among those who are scientifically illiterate are some of those who are in power, people who lead us in politics, in civil service, in the media, in the church, often in industry and sometimes even in education. Think, for example, about the enormous influence of scientific knowledge on one's whole philosophy of life, even one's religion. It is no more permissible for the archbishops of today, who advise their flocks on how to interpret the Scriptures, to ignore the findings of Watson and Crick, than it was right for clerics of the last century to ignore the work of Darwin. Science today is all-pervasive. Without some scientific and technical education, it is becoming impossible even to vote responsibly on matters of health, energy, defense or education. So unless things change, we shall soon live in a country that is backward not only in its technology and standard of living but in its cultural vitality too. It is wrong to suppose that by foregoing technological and scientific education we shall somehow become a nation of artists, writers or philosophers instead. These two aspects of culture have never been divorced from each other throughout our history. Every renaissance, every period that showed a flowering of civilization, advanced simultaneously in the arts and sciences, and in technology too.

Sir Kenneth Durham, former director of research at Unilever, on becoming president in August 1987 followed on from Sir George Porter saying that science teachers needed extra pay to overcome the scarcity of mathematics and physics teachers in secondary schools, and that "unless we deal with this as matter of urgency, the outlook for our manufacturing future is bleak". He regretted that headmasters and careers masters had for many years followed 'the cult of Oxbridge' because "it carried more prestige to read classics at Oxbridge and go into the Civil Service or banking, than to read engineering at, say, Salford, and go into manufacturing industry". He said that reporting of sciences gave good coverage to medical science, but that "nevertheless, editors ought to be sensitive to developments in areas such as solid state physics, astro-physics, colloid science, molecular biology, transmission of stimuli along nerve fibres, and so on, and that newspaper editors were in danger of waiting for disasters before the scientific factors involved in the incidents were explained.
In September 2001 Sir William Stewart, as outgoing president, warned that universities faced "dumbing down" and that

we can deliver social inclusiveness, and the best universities, but not both from a limited amount of money. We run the risk of doing neither well. Universities are underfunded, and must not be seen simply as a substitute for National Service to keep youngsters off the dole queue... scientists have to be careful and consider the full implications of what they are seeking to achieve. The problem with some clever people is that they find cleverer ways of being stupid.

In the year 2000, Sir Peter Williams had put together a panel to discuss the shortage of physics majors. A physicist called Derek Raine had stated that he has had multiple firms call him up asking for physics majors. The report they made stated that it is critical that they increase the number of physics teachers, or it will have a detrimental effect on the number of future engineers and scientists.

British Science Festival

The Association's major emphasis in recent decades has been on public engagement in science. Its annual meeting, now called the British Science Festival, is the largest public showcase for science in the UK and attracts a great deal of media attention. It is held at UK universities in early September for one week, with visits to science-related local cultural attractions.
The 2010 Festival, held in Birmingham with Aston University as lead University partner, featured a prank event: the unveiling of Dulcis foetidus, a fictional plant purported to emit a pungent odour. An experiment in herd mentality, some audience members were induced into believing they could smell it.
The Festival has also been the home to protest and debate. In 1970 there were protestors over the use of science for weapons.

Science Communication Conference

The Association organised and held the annual for over ten years. It was the largest conference of its kind in the UK, and addressed the key issues facing science communicators. In 2015, the BSA introduced a new series of smaller events for science communicators, designed to address the same issues as the Science Communication Conference but for a more targeted audience.

British Science Week

In addition to the British Science Festival, the British Science Association organises the British Science Week, an opportunity for people of all ages to get involved in science, engineering, technology and maths activities, originating as the National Week of Science, Engineering and Technology.
The Association also has a young people's programme, the CREST Awards which seeks to involve school students in science beyond the school curriculum, and to encourage them to consider higher education and careers in science.
Huxley Summit
Named after Thomas Huxley, the Huxley Summit is a leadership event run by the British Science Association, where 250 of the most influential people in the UK are brought together to discuss scientific and social challenges that the UK faces in the 21st century and to develop a link between scientists and non-scientists to ensure that science can be understood by society as a whole. On 8 November 2016, the British Science Association held the very first Huxley Summit at BAFTA, London. The theme of the summit was "Trust in the 21st Century" and how that would affect the future of science, innovation, and business.
Media Fellowship Schemes
The British Science Association's Media Fellowship provides the opportunity for practicing scientists, clinicians, and engineers to spend a period of time working at media outlets such as the Guardian, BBC Breakfast or The Londonist. After their time with the media placement, the fellows attend the British Science Festival which will offer these practitioners valuable working experience with a range of media organizations along with learning from a wide range of public engagement activities and be able to network with academics, journalists and science communicators.

CREST Awards

CREST Awards is the British Science Association's scheme to encourage students aged 5–19 to get involved with STEM projects and encourage scientific thinking. Awards range from Star Awards to Gold Awards. Overall, 30,000 awards are undertaken annually. Many students who do CREST Awards, especially Silver and Gold Awards which require 30 and 70 hours of work respectively, enter competitions like the UK Big Bang Fair.

Patrons and Presidents of the British Science Association

Traditionally the president is elected at the meeting usually held in August/September for a one-year term and gives a presidential address upon retiring. The honour of the presidency is traditionally bestowed only once per individual. Written sources that give the year of presidency as a single year generally mean the year in which the presidential address is given. In 1926/1927 the association's patron was King George V and the president was his son Edward, Prince of Wales. The vice-presidents for the Leeds meeting at this time included City of Leeds Alderman Charles Lupton and his brother, The Rt. Hon. the Lord Mayor of Leeds Hugh Lupton. The husband of the brothers' first cousin once removed - Lord Airedale of Gledhow - was also a vice-president at the Leeds meeting.

1831: Charles Wentworth-Fitzwilliam, 5th Earl Fitzwilliam, statistician.
1832: Rev. William Buckland, palaeontologist
1833: Rev. Adam Sedgwick, geologist
1834: Sir Thomas Makdougall Brisbane, astronomer
1835: Rev. Humphrey Lloyd, physicist
1836: Henry Petty-Fitzmaurice, 3rd Marquess of Lansdowne, statistician
1837: William Cavendish, 2nd Earl of Burlington, Chancellor of the University of London
1838: Algernon Percy, 4th Duke of Northumberland, Naval officer
1839: Canon William Vernon Harcourt, FRS
1840: John Campbell, 2nd Marquess of Breadalbane, F.R.S.
1841: Rev. William Whewell, polymath and philosopher of science
1842: Lord Francis Egerton
1843: William Parsons, 3rd Earl of Rosse, astronomer
1844: Rev. George Peacock, mathematician
1845: Sir John F. W. Herschel, astronomer & polymath
1846: Sir Roderick Impey Murchison, geologist
1847: Sir Robert Harry Inglis
1848: Spencer Compton, 2nd Marquess of Northampton, geologist
1849: Rev. Thomas Romney Robinson, astronomer
1850: Sir David Brewster, physicist
1851: Sir George Biddell Airy, Astronomer Royal
1852: Colonel Edward Sabine, Vice-president of the Royal Society
1853: William Hopkins FGS, mathematician and geologist
1854: Dudley Ryder, 2nd Earl of Harrowby FRS
1855: George Campbell, 8th Duke of Argyll FRS, FRSE, FGS
1856: Charles D. B. Daubeny MD, FRS, botanist
1857: Rev. Humphrey Lloyd FRS, FRSE, physicist
1858: Sir Richard Owen MD, FLS, FGS, naturalist
1859: Albert, Prince Consort
1860: John Wrottesley, 2nd Baron Wrottesley FRAS, astronomer
1861: Sir William Fairbairn, civil engineer
1862: Rev. Robert Willis FRS, civil engineer
1863: William Armstrong, engineer and inventor
1864: Sir Charles Lyell, geologist
1865: John Phillips FRS, geologist
1866: William Robert Grove FRS
1867: Walter Montagu Douglas Scott, 5th Duke of Buccleuch FRS
1868: Joseph Dalton Hooker MD, FRS, botanist
1869: Sir George Stokes, 1st Baronet FRS, mathematical physicist
1870: Thomas Henry Huxley FRS, biologist
1871: Sir William Thomson FRS, FRSE, physicist
1872: William Benjamin Carpenter MD, FRS
1873: Alexander William Williamson FRS, chemist
1874: John Tyndall FRS, physicist
1875: Sir John Hawkshaw FRS, civil engineer
1876: Thomas Andrews MD, FRS, chemist
1877: Allen Thomson MD, FRS, FRSE
1878: William Spottiswoode FRS, mathematician
1879: George James Allman FRS, naturalist
1880: Sir Andrew Crombie Ramsay FRS, geologist
1881: John Lubbock, 1st Baron Avebury MP, FRS
1882: C. W. Siemens FRS, FRSA, engineer
1883: Arthur Cayley, mathematician
1884: John William Strutt, 3rd Baron Rayleigh FRS, FRAS, FGS, physicist
1885: Lyon Playfair, 1st Baron Playfair MP, FRS, FRSE
1886: Sir John William Dawson CMG, geologist
1887: Sir Henry Enfield Roscoe, chemist
1888: Sir Frederick Bramwell, civil engineer
1889: Sir William Henry Flower CB, anatomist
1890: Sir William Huggins FRS, FRAS, FBAS, astronomer
1891: Sir Frederick August Abel FRS
1892: Sir Archibald Geikie, geologist
1893: Sir John Scott Burdon-Sanderson, medical doctor
1894: Robert Gascoyne-Cecil, 3rd Marquess of Salisbury FRS
1895: Captain Sir Douglas Strutt Galton FRS, civil engineer
1896: Joseph Lister, 1st Baron Lister
1897: John Evans, archaeologist
1898: Sir William Crookes FRS, chemist and physicist
1899: Sir Michael Foster, physiologist
1900: Sir William Turner, anatomist and vice-chancellor from 1903 to 1916 of the University of Edinburgh
1901: Arthur William Rücker FRS, physicist
1902: Sir James Dewar FRS, chemist and physicist
1903: Sir Norman Lockyer FRS, astronomer and physicist
1904: Arthur James Balfour MP, FRS
1905: Sir George Darwin, older brother of Francis
1906: Sir Ray Lankester, zoologist
1907: Sir David Gill CB, astronomer
1908: Sir Francis Darwin, son of Charles
1909: Sir J. J. Thomson, physicist
1910: Rev. Professor Thomas George Bonney, geologist
1911: Sir William Ramsay, chemist
1912: Edward Albert Schäfer, physiologist
1913: Sir Oliver Lodge, physicist
1914: William Bateson, geneticist
1915: Sir Arthur Schuster, physicist
1916–1919: Sir Charles Algernon Parsons, engineer
1916: Sir Arthur Evans, archaeologist
1920: William Abbott Herdman, oceanographer
1921: Sir T. Edward Thorpe, chemist
1922: Professor Sir Charles Scott Sherrington, neuroscientist
1923: Professor Sir Ernest Rutherford, physicist
1924: Major-General Sir David Bruce, microbiologist
1925: Sir Horace Lamb, physicist
1926: Edward, Prince of Wales
1927: Prof Sir Arthur Keith, anatomist and anthropologist
1928: Sir William Henry Bragg, physicist
1929: Sir Thomas Henry Holland, geologist
1930: Frederick Orpen Bower, botanist
1931: General Jan Christiaan Smuts FRS
1932: Sir James Alfred Ewing, physicist and vice-chancellor from 1916 to 1929 of the University of Edinburgh
1933: Sir Frederick Gowland Hopkins, Nobel Prize winning biochemist who discovered vitamins
1934: Sir James Hopwood Jeans, astronomer
1935: William Whitehead Watts, geologist
1936: Josiah Stamp, 1st Baron Stamp, statistician
1937: Sir Edward Bagnall Poulton, evolutionary biologist
1938: Robert Strutt, 4th Baron Rayleigh, physicist and son of Nobel Prize–winning John William Strutt, 3rd Baron Rayleigh
1939–1946: Sir Albert Seward, geologist
1946–1947: Sir Henry Dale, physiologist
1947–48: Sir Henry Tizard, chemist and inventor
1948–49: Sir E. John Russell, agriculturalist
1949–50: Sir Harold Hartley, physical chemist
1950–51: Prince Philip, Duke of Edinburgh
1951–52: Archibald Vivian Hill, physiologist
1952–53: Sir Edward Victor Appleton, Nobel Prize winning physicist
1953–54: Edgar Adrian, 1st Baron Adrian, neuroscientist
1954–55: Sir Robert Robinson, chemist
1955–56: Sir Raymond Priestley, geologist and vice-chancellor from 1938 to 1952 of the University of Birmingham
1956–57: Patrick Blackett, Baron Blackett, physicist
1957–58: Alexander Fleck, 1st Baron Fleck, industrial chemist
1958–59: Sir James Gray, zoologist
1959–60: Sir George Paget Thomson, physicist
1960–61: Sir Wilfrid Le Gros Clark, primatologist and palaeoanthropologist
1961–62: Sir John Cockcroft CBE, Nobel Prize winning physicist
1962–63: Eric Ashby, Baron Ashby, llVice-chancellor from 1950 to 1959 of Queen's University Belfast
1963–64: Russell Brain, 1st Baron Brain, neurologist
1964–65: Sir Cyril Norman Hinshelwood, Nobel Prize winning chemist
1965–66: Sir Joseph Hutchinson, biologist
1966–67: Willis Jackson, Baron Jackson of Burnley, technologist and electrical engineer
1967–68: Dame Kathleen Lonsdale, physicist who discovered the cyclic nature of benzene in 1929
1968–69: Sir Peter Medawar, zoologist and immunologist
1969–70: Alexander R. Todd, Baron Todd, Nobel Prize winning biochemist known for nucleotides and coenzymes
1970–71: Sir Alexander Cairncross, economist
1971–72: Sir Vivian Fuchs FRS, explorer
1972–73: Sir Kingsley Charles Dunham, geologist and mineralogist
1973–74: Sir John Kendrew CBE, Nobel Prize winning biochemist who discovered the structure of myoglobin
1974–75: Sir Bernard Lovell, astronomer
1975–76: John Baker, Baron Baker OBE, structural engineer known for limit state design
1976–77: Sir Andrew Huxley, Nobel Prize winning physiologist, known for discovering nerve action potentials
1977–78: Prof Dorothy Hodgkin, Nobel Prize winning chemist
1978–79: Frank Kearton, Baron Kearton OBE,
1979–80: Frederick Dainton, Baron Dainton
1980–81: HRH the Duke of Kent
1981–82: Prof Sir Charles Frederick Carter, economist
1982–83: Sir Basil John Mason CB, general from 1965 to 1983 of the Met Office
1983–84: Sir Alastair Pilkington, inventor
1984–85: Prof Sir Hans Kornberg, biochemist
1985–86: Prof George Porter, Baron Porter of Luddenham, Nobel Prize winning chemist
1986–87 Sir Kenneth Durham, Chairman from 1982 to 1986 of Unilever
1987–88: Sir Walter Bodmer, geneticist
1988–89: Sir Samuel Edwards, physicist
1989–90: Claus Moser, Baron Moser, director from 1967 to 1978 of the Central Statistical Office
1990–91: Sir Denis Rooke
1991–92 Sir David Attenborough
1992–93: Sir David Weatherall, haemotologist
1993–94: Dame Anne McLaren, IVF biologist
1994–95: Sir Martin Rees, Baron Rees of Ludlow FRS, astrophysicist
1995–96: Ronald Oxburgh, Baron Oxburgh, geologist and Rector of Imperial College London from 1993 to 2000
1996–97: Sir Derek Roberts CBE, electronics engineer, and Provost of UCL from 1989 to 1999
1997–98 Prof Colin Blakemore, neuroscientist
1998–99: Sir Richard Sykes, biochemist and chief executive from 1993 to 1997 of Glaxo
1999–2000: Anne, Princess Royal
2000–01: Sir William Stewart, Government Chief Scientific Adviser from 1990 to 1995
2001–02: Sir Howard Newby, sociologist
2002–03: Sir Peter Williams CBE, physicist
2003–04: Dame Julia Higgins
2004–05: Prof Robert Winston, Lord Winston of Hammersmith
2005–06: Frances Cairncross CBE, economist
2006–07: John Browne, Lord Browne of Madingley
2007–08: Sir David King, Government Chief Scientific Adviser from 2000 to 2008
2009–10: Robert May, Baron May of Oxford
2010–11: David Sainsbury, Lord Sainsbury of Turville
2011–12: Professor Dame Jocelyn Bell Burnell FRS, FRSE
2012–13: John Krebs, Baron Krebs FRS
2013–14: Lisa Jardine CBE, historian
2014–15: Sir Paul Nurse FRS, President from 2010 to 2015 of the Royal Society, and joint winner of the 2001 Nobel Prize in Physiology or Medicine
2015–16 Dame Athene Donald FRS, physicist and master since 2014 of Churchill College, Cambridge
2016–17: Dame Nancy Rothwell DBE DL FRS FMedSci FBPhS, physiologist and president and vice-chancellor of the University of Manchester
2017–18: Dame Uta Frith FRS, developmental psychologist
2018–19: Professor Jim Al-Khalili FRS, physicist and broadcaster
2019–20: Professor Alice Roberts anatomist and broadcaster
2020–21: Ara Darzi, Baron Darzi of Denham
2021–22: Maggie Aderin-Pocock
2022–23: Anne-Marie Imafidon
2023–24: Professor Dame Jane Francis
2024–25: Professor Kevin Fenton
List of annual meetings
1831 York, England.
1832 Oxford, England.
1833 Cambridge, England.
1834 Edinburgh, Scotland.
1835 Dublin, Ireland.
1836 Bristol, England.
1837 Liverpool, England.
1838 Newcastle upon Tyne, England.
1839 Birmingham, England.
1840 Glasgow, Scotland.
1841 Plymouth, England.
1842 Manchester.
1843 Cork, Ireland.
1844 York, England.
1845 Cambridge, England.
1846 Southampton, England.
1847 Oxford, England.
1848 Swansea, Wales.
1849 Birmingham, England.
1850 Edinburgh, Scotland.
1851 Ipswich, England.
1852 Belfast, Northern Ireland.
1853 Hull, England.
1854 Liverpool, England.
1855 Glasgow, Scotland.
1856 Cheltenham, England.
1857 Dublin, Ireland.
1858 Leeds, England.
1859 Aberdeen, Scotland.
1860 Oxford, England.
1861 Manchester, England.
1862 Cambridge, England.
1863 Newcastle upon Tyne, England.
1864 Bath, England.
1865 Birmingham, England.
1866 Nottingham, England.
1867 Dundee, Scotland.
1868 Norwich, England.
1869 Exeter, England.
1870 Liverpool, England.
1871 Edinburgh, Scotland.
1872 Brighton, England.
1873 Bradford, England.
1874 Belfast, Northern Ireland.
1875 Bristol, England.
1876 Glasgow, Scotland.
1877 Plymouth, England.
1878 Dublin, Ireland.
1879 Sheffield, England.
1880 Swansea, Wales.
1881 York, England.
1882 Southampton, England.
1883 Southport, England.
1884 Montreal, Quebec, Canada.
1885 Aberdeen, Scotland.
1886 Birmingham, England.
1887 Manchester, England.
1888 Bath, England.
1889 Newcastle upon Tyne, England.
1890 Leeds, England.
1891 Cardiff, Wales.
1892 Edinburgh, Scotland.
1893 Nottingham, England.
1894 Oxford, England.
1895 Ipswich, England.
1896 Liverpool, England.
1897 Toronto, Ontario, Canada.
1898 Bristol, England.
1899 Dover, England.
1900 Bradford, England.
1901 Glasgow, Scotland.
1902 Belfast, Northern Ireland.
1903 Southport, England.
1904 Cambridge, England.
1905 Various, South Africa.
1906 York, England.
1907 Leicester, England.
1908 Dublin, Ireland.
1909 Winnipeg, Manitoba, Canada.
1910 Sheffield, England.
1911 Portsmouth, England.
1912 Dundee, Scotland.
1913 Birmingham, England.
1914 Various, Australia.
1915 Manchester, England.
1916 Newcastle upon Tyne, England.
1917 No meeting
1918 No meeting
1919 Bournemouth, England.
1920 Cardiff, Wales.
1921 Edinburgh, Scotland.
1922 Hull, England.
1923 Liverpool, England.
1924 Toronto, Ontario, Canada.
1925 Southampton, England.
1926 Oxford, England.
1927 Leeds, England.
1928 Glasgow, Scotland.
1929 Various, South Africa.
1930 Bristol, England.
1931 London, England.
1932 York, England.
1933 Leicester, England.
1934 Aberdeen, Scotland.
1935 Norwich, England.
1936 Blackpool, England.
1937 Nottingham, England.
1938 Cambridge, England.
1939 Dundee, Scotland.
1940 No meeting
1941 No meeting
1942 No meeting
1943 No meeting
1944 No meeting
1945 No meeting
1946 No full meeting
1947 Dundee, Scotland.
1948 Brighton, England.
1949 Newcastle upon Tyne, England.
1950 Birmingham, England.
1951 Edinburgh, Scotland.
1952 Belfast, Northern Ireland.
1953 Liverpool, England.
1954 Oxford, England.
1955 Bristol, England.
1956 Sheffield, England.
1957 Dublin, Ireland.
1958 Glasgow, Scotland.
1959 York, England.
1960 Cardiff, England.
1961 Norwich, England.
1962 Manchester, England.
1963 Aberdeen, Scotland.
1964 Southampton, England.
1965 Cambridge, England.
1966 Nottingham, England.
1967 Leeds, England.
1968 Dundee, Scotland.
1969 Exeter, England.
1970 Durham, England.
1971 Swansea, Wales.
1972 Leicester, England.
1973 Canterbury, England.
1974 Stirling, Scotland.
1975 Guildford, England.
1976 Lancaster, England.
1977 Birmingham, England.
1978 Bath, England.
1979 Edinburgh, Scotland.
1980 Salford, England.
1981 York, England.
1982 Liverpool, England.
1983 Brighton, England.
1984 Norwich, England.
1985 Glasgow, Scotland.
1986 Bristol, England.
1987 Belfast, Northern Ireland.
1988 Oxford, England.
1989 Sheffield, England.
1990 Swansea, Wales.
1991 Plymouth, England.
1992 Southampton, England.
1993 Keele, England.
1994 Loughborough, England.
1995 Newcastle upon Tyne, England.
1996 Birmingham, England.
1997 Leeds, England.
1998 Cardiff, Wales.
1999 Sheffield, England.
2000 London, England.
2001 Glasgow, Scotland.
2002 Leicester, England.
2003 Salford, England.
2004 Exeter, England.
2005 Dublin, Ireland.
2006 Norwich, England.
2007 York, England.
2008 Liverpool, England.
2009 Guildford, England.
2010 Birmingham, England.
2011 Bradford, England.
2012 Aberdeen, Scotland.
2013 Newcastle upon Tyne, England.
2014 Birmingham, England.
2015 Bradford, England
2016 Swansea, Wales
2017 Brighton, England
2018 Hull, England
2019 Coventry, England
2020 No meeting due to the COVID pandemic
2021 Chelmsford, Essex, England
2022 Leicester, England
2023 Exeter, England
2024 East London, England
2025 Liverpool, England
''2026 Southampton, England''
Structure

The organisation is administered from the Wellcome Wolfson Building at the Science Museum, London in South Kensington in Kensington and Chelsea, within a few feet of the northern boundary with the City of Westminster.

Video clips

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Category:1831 establishments in the United Kingdom
Category:Royal Borough of Kensington and Chelsea
Category:Science advocacy organizations
Category:Science and technology in London
Category:Science education in the United Kingdom
Category:Science policy in the United Kingdom
Category:Scientific societies based in the United Kingdom
Category:Scientific organizations established in 1831