Ronald Sydney Nyholm
Sir Ronald Sydney Nyholm was an Australian chemist who was a leading figure in inorganic chemistry in the 1950s and 1960s.
Education
Born on 29 January 1917 as the fourth in a family of six children. Nyholm’s father, Eric Edward Nyholm was a railway guard. Nyholm's paternal grandfather, Erik Nyholm was a coppersmith born in Nykarleby in the Swedish-speaking part of Finland, who migrated to Adelaide in 1873. Ronald Nyholm valued his Finnish roots and was particularly proud in his election in 1959 as Corresponding Member of the Finnish Chemical Society.Hailing from the small mining town of Broken Hill, New South Wales, he was early exposed to the role of inorganic chemistry. He attended Burke Ward Public School and Broken Hill High School. Nyholm married Maureen Richardson of Epping, a suburb of Sydney, NSW, at St Mary Abbotts Parish Church, Kensington, London on 6 August 1948.
After graduating from Broken Hill High School, he attended the University of Sydney and then University College London. On graduation Nyholm became a High School teacher – a contractual requirement of his scholarship to university.
Independent career
He then joined the Eveready Battery Co as a chemist where he was frustrated that his work to make longer lasting batteries was not well received by the marketing department. He then returned to teaching but now in tertiary education. During World War II he was a Gas Officer as the civil defence forces were very concerned that the likely Japanese invasion would include gas attacks. He was lecturer, then senior lecturer in Chemistry at Sydney Technical College from 1940 to 1951, although on leave in London from 1947. From 1952 to 1954 he was associate professor of Inorganic Chemistry at the New South Wales University of Technology. In 1954 he was elected President of the Royal Society of New South Wales. In 1955, Nyholm returned to England as Professor of Chemistry at University College London, where he worked until his death on 4 December 1971 as a result of a motorcar accident on the outskirts of Cambridge, England.Research in inorganic chemistry
Nyholm's research in inorganic chemistry was primarily concerned with the preparation of transition metal compounds, particularly those involving organo-arsenic ligands. His interest in organoarsenic chemistry was fostered at the University of Sydney by George Joseph Burrows. Using the strong chelating ligand diars, Nyholm demonstrated a range of oxidation states and coordination numbers for several of the transition metals. Nyholm noted that the term ‘unusual valence state’ had an ‘historical, but not chemical significance.’ ‘The definition of usual oxidation state refers to oxidation states that are stable in environments made up of those chemical species that were common in classical inorganic compounds, e.g. oxides, water and other simple oxygen donors, the halogens, excluding fluorine, and sulphur. Nowadays, however, such species constitute only a minority of the vast number of donor atoms and ligands that can be attached to metal.’After joining Sydney Technology college in 1940 Nyholm formed a close personal friendship with Francis Dwyer and they collaborated in their research. Despite heavy teaching loads, between 1942 and 1947 they reported complexes of rhodium, iridium, and osmium in seventeen papers in the Journal and Proceedings of the Royal Society of New South Wales.
One of Nyholm’s early successes was the preparation of an octahedral complex of trivalent nickel Cl, by aerial oxidation of the red salt of bivalent nickel Cl2. He also described stable complexes of quadrivalent nickel such as the deep blue 2, by nitric acid oxidation of the trivalent complex. This stabilisation of higher oxidation states became significant in the Nyholm-Rail reaction where the ditertiary arsine, diars undergoes a condensation reaction to a tritertiary arsine, triars. Nyholm prepared examples of divalent octahedral complexes of the type M2X2, where X is Cl, Br or I, and M is Cr, Mn, Fe, Co, Ni, Mo, Tc, Ru, Pd, W, Re, Os, and Pt.
Many of these divalent complexes are sensitive to aerial oxidation. The chromium complex is oxidized by water. Indeed, previous attempts to prepare Cr2X2 had failed. The chromium compounds were eventually synthesized by his co-worker Anthony Nicholl Rail only a month before Nyholm’s death, using rigorous air-free techniques.
Together with Professor Ronald Gillespie, Nyholm developed the VSEPR concept, which emphasized classical pictures of bonding, adapted to include features of quantum theory, but focusing on electron clouds of varying density within a probability envelope.
Teaching philosophy
In his inaugural lecture as professor of chemistry at University College London, Nyholm spoke of his concern for the teaching of chemistry. In 1957 Nyholm organized the first of an annual series of Summer Schools at University College on new aspects of chemical knowledge and theory, and demonstrations of new equipment. In the early sixties, the Nuffield Foundation, at least partly as a result of Nyholm’s influence, established the Science Teaching project, of which Nyholm was the first Chairman of the Chemistry Consultative Committee. This program led to the development of experiential GCE courses that emphasized the process of chemistry, rather than the recall of chemical facts, and explored the role of chemistry in society. In 1971 Nyholm published an article entitled 'Education for Change' in which he differentiated between education and training as it applies to chemistry. He defined education as ‘a process in which a person receives a training for a full life in a rapidly changing modern society, carried out in such a manner as will ensure the maximum development of the individual personality'. He was not a person who placed too much emphasis on fact-burdened and fact-tested learning such as in the National Curriculum developments in England in the nineteen-nineties.Nyholm defined training for a full life as including:
- Recognition of oneself as an individual with the development of some kind of ethical standards. This may take place via training in religion of one kind or other; whether these beliefs are rejected later or not, they form at least a basis against which future behaviour can be measured.
- Man is a social being and needs to be made familiar with the nature of, and the reason for, the development of the society in which he is living
- Man needs to be able to communicate both by the spoken word and the written word
- Man must be numerate. It is essential that he receive an understanding of the process of quantitative thinking appropriate to his intellectual ability.
Industrial consulting
Honours and awards
- 1950. Awarded the Corday-Morgan medal and Prize of the Chemical Society.
- 1955. Awarded the H G Smith Medal of the Royal Australian Chemical Institute.
- 1959. Elected Fellow of the Royal Society.
- 1959. Awarded the Royal Medal of the Royal Society of New South Wales.
- 1959. Elected Corresponding Member of the Finnish Chemical Society.
- 1961. Appointed Tilden Lecturer of the Chemical Society.
- 1967. Appointed Liversidge Lecturer of the Chemical Society.
- 1967. Created Knight Bachelor for services to science.
- 1968. Awarded the Gold Medal of the Italian Chemical Society.
- 1968. Honorary Doctor of Science, University of East Anglia.
- 1968. Honorary Doctor of Science, City University, London.
- 1969. Awarded the Sigillum Magnum Medal, University of Bologna.
- 1969. Honorary Doctor of Science, University of New South Wales.
- 1971. Elected Honorary Member of the Accademia Peloritana
The mineral Nyholmite is named after Nyholm. It was discovered in Broken Hill in 2009 and its structure was elucidated by Elliot et al.