Mahima Chaudhary | Updated: Aug 30, 2022 19:20 IST
Nobel Laureates In Chemistry 2022: The Royal Swedish Academy of Sciences bestows the Nobel Prize in Chemistry on scientists working in various fields of chemistry each year. The Nobel Prize in Chemistry is one of five Nobel Prizes established by Alfred Nobel’s will in 1895 and awarded for outstanding contributions to chemistry. Here you will find the 2022 Nobel Laureate in Chemistry as well as a list of all previous winners, including the first Nobel Laureate in Chemistry. The List of Nobel Laureates in Chemistry PDF can be downloaded from the link provided in this article.
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Continue reading this article to learn about all of the Nobel Prize winners in Chemistry up to this point, including the Nobel Laureates in Chemistry 2022.
The Nobel Laureates in Chemistry 2022 have not yet been awarded. It will be made public on Wednesday, October 5, at 11:45 a.m. CEST. Once it is announced, we will post an update here.
Jacobus Henricus van ‘t Hoff of the Netherlands received the first Nobel Prize in Chemistry in 1901 for “discovery of the laws of chemical dynamics and osmotic pressure in solutions.” His groundbreaking work aided in the development of modern theories of chemical affinity, chemical equilibrium, chemical kinetics, and chemical thermodynamics. Van ‘t Hoff’s 1874 pamphlet formulated the theory of the tetrahedral carbon atom and laid the groundwork for stereochemistry.
The table below lists the recipients of the Nobel Prize in Chemistry.
List Of Nobel Laureates In Chemistry | |||
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Year | Name | Country | Achievement |
1901 | Jacobus Henricus van ‘t Hoff | Netherlands | Laws of chemical dynamics and osmotic pressure |
1902 | Emil Fischer | Germany | Work on sugar and purine syntheses |
1903 | Svante Arrhenius | Sweden | Theory of electrolytic dissociation |
1904 | Sir William Ramsay | U.K. | Discovery of inert gas elements and their places in the periodic system |
1905 | Adolf von Baeyer | Germany | Work on organic dyes, hydroaromatic compounds |
1906 | Henri Moissan | France | Isolation of fluorine; introduction of Moissan furnace |
1907 | Eduard Buchner | Germany | Discovery of noncellular fermentation |
1908 | Ernest Rutherford | U.K. | Investigations into the disintegration of elements and the chemistry of radioactive substances |
1909 | Wilhelm Ostwald | Germany | Pioneer Work on catalysis, chemical equilibrium, and reaction velocities |
1910 | Otto Wallach | Germany | Pioneer Work in alicyclic combinations |
1911 | Marie Curie | France | Discovery of radium and polonium; Isolation of radium |
1912 | Victor Grignard | France | Discovery of the Grignard reagents |
Paul Sabatier | France | Method of hydrogenating organic compounds | |
1913 | Alfred Werner | Switzerland | Work on the linkage of atoms in molecules |
1914 | Theodore William Richards | U.S. | accurate determination of the atomic weights of numerous elements |
1915 | Richard Willstätter | Germany | Pioneer researches in plant pigments, especially chlorophyll |
1918 | Fritz Haber | Germany | synthesis of ammonia |
1920 | Walther Hermann Nernst | Germany | Work in thermochemistry |
1921 | Frederick Soddy | U.K. | chemistry of radioactive substances; occurrence and nature of isotopes |
1922 | Francis William Aston | U.K. | Work with mass spectrograph; whole-number rule |
1923 | Fritz Pregl | Austria | Method of microanalysis of organic substances |
1925 | Richard Zsigmondy | Austria | elucidation of the heterogeneous nature of colloidal solutions |
1926 | Theodor H.E. Svedberg | Sweden | Work on disperse systems |
1927 | Heinrich Otto Wieland | Germany | researches into the constitution of bile acids |
1928 | Adolf Windaus | Germany | constitution of sterols and their connection with vitamins |
1929 | Hans von Euler-Chelpin | Sweden | Investigations in the fermentation of sugars and the enzyme action involved |
Sir Arthur Harden | U.K. | Investigations in the fermentation of sugars and the enzyme action involved | |
1930 | Hans Fischer | Germany | hemin, chlorophyll research; synthesis of hemin |
1931 | Friedrich Bergius | Germany | Invention and Development of chemical high-pressure Method s |
Carl Bosch | Germany | Invention and Development of chemical high-pressure Method s | |
1932 | Irving Langmuir | U.S. | discoveries and Investigations in surface chemistry |
1934 | Harold C. Urey | U.S. | Discovery of heavy hydrogen |
1935 | Frédéric and Irène Joliot-Curie | France | synthesis of new radioactive elements |
1936 | Peter Debye | Netherlands | Work on dipole moments and diffraction of X-rays and electrons in gases |
1937 | Sir Norman Haworth | U.K. | research on carbohydrates and vitamin C |
Paul Karrer | Switzerland | research on carotenoids, flavins, and vitamins | |
1938 | Richard Kuhn (declined) | Germany | carotenoid and vitamin research |
1939 | Adolf Butenandt (declined) | Germany | Work on sexual hormones |
Leopold Ruzicka | Switzerland | Work on polymethylenes and higher terpenes | |
1943 | Georg Charles von Hevesy | Hungary | use of isotopes as tracers in chemical research |
1944 | Otto Hahn | Germany | Discovery of the fission of heavy nuclei |
1945 | Artturi Ilmari Virtanen | Finland | Invention of a fodder-preservation Method |
1946 | John Howard Northrop | U.S. | preparation of enzymes and virus proteins in pure form |
Wendell Meredith Stanley | U.S. | preparation of enzymes and virus proteins in pure form | |
James Batcheller Sumner | U.S. | Discovery of enzyme crystallization | |
1947 | Sir Robert Robinson | U.K. | investigation of alkaloids and other plant products |
1948 | Arne Tiselius | Sweden | researches in electrophoresis and adsorption analysis; serum proteins |
1949 | William Francis Giauque | U.S. | behaviour of substances at extremely low temperatures |
1950 | Kurt Alder | West Germany | Discovery and Development of diene synthesis |
Otto Paul Hermann Diels | West Germany | Discovery and Development of diene synthesis | |
1951 | Edwin Mattison McMillan | U.S. | Discovery of and research on transuranium elements |
Glenn T. Seaborg | U.S. | Discovery of and research on transuranium elements | |
1952 | A.J.P. Martin | U.K. | Development of partition chromatography |
R.L.M. Synge | U.K. | Development of partition chromatography | |
1953 | Hermann Staudinger | West Germany | Work on macromolecules |
1954 | Linus Pauling | U.S. | study of the nature of the chemical bond |
1955 | Vincent du Vigneaud | U.S. | first synthesis of a polypeptide hormone |
1956 | Sir Cyril Norman Hinshelwood | U.K. | Work on the kinetics of chemical reactions |
Nikolay Nikolayevich Semyonov | U.S.S.R. | Work on the kinetics of chemical reactions | |
1957 | Alexander Robertus Todd, Baron Todd | U.K. | Work on nucleotides and nucleotide coenzymes |
1958 | Frederick Sanger | U.K. | determination of the structure of the insulin molecule |
1959 | Jaroslav Heyrovský | Czech. | Discovery and Development of polarography |
1960 | Willard Frank Libby | U.S. | Development of radiocarbon dating |
1961 | Melvin Calvin | U.S. | study of chemical steps that take place during photosynthesis |
1962 | Sir John Cowdery Kendrew | U.K. | determination of the structure of hemoproteins |
Max Ferdinand Perutz | U.K. | determination of the structure of hemoproteins | |
1963 | Giulio Natta | Italy | structure and synthesis of polymers in the field of plastics |
Karl Ziegler | West Germany | structure and synthesis of polymers in the field of plastics | |
1964 | Dorothy Mary Crowfoot Hodgkin | U.K. | determining the structure of biochemical compounds essential in combating pernicious anemia |
1965 | Robert Burns Woodward | U.S. | synthesis of sterols, chlorophyll, and other substances |
1966 | Robert Sanderson Mulliken | U.S. | Work concerning chemical bonds and the electronic structure of molecules |
1967 | Manfred Eigen | West Germany | studies of extremely fast chemical reactions |
Ronald George Wreyford Norrish | U.K. | studies of extremely fast chemical reactions | |
Sir George Porter | U.K. | studies of extremely fast chemical reactions | |
1968 | Lars Onsager | U.S. | Work on the Theory of thermodynamics of irreversible processes |
1969 | Sir Derek H.R. Barton | U.K. | Work in determining actual three-dimensional shapes of molecules |
Odd Hassel | Norway | Work in determining actual three-dimensional shapes of molecules | |
1970 | Luis Federico Leloir | Argentina | Discovery of sugar nucleotides and their role in the biosynthesis of carbohydrates |
1971 | Gerhard Herzberg | Canada | research in the structure of molecules |
1972 | Christian B. Anfinsen | U.S. | fundamental contributions to enzyme chemistry |
Stanford Moore | U.S. | fundamental contributions to enzyme chemistry | |
William H. Stein | U.S. | fundamental contributions to enzyme chemistry | |
1973 | Ernst Otto Fischer | West Germany | organometallic chemistry |
Sir Geoffrey Wilkinson | U.K. | organometallic chemistry | |
1974 | Paul J. Flory | U.S. | studies of long-chain molecules |
1975 | Sir John Warcup Cornforth | U.K. | Work in stereochemistry |
Vladimir Prelog | Switzerland | Work in stereochemistry | |
1976 | William Nunn Lipscomb, Jr. | U.S. | structure of boranes |
1977 | Ilya Prigogine | Belgium | widening the scope of thermodynamics |
1978 | Peter Dennis Mitchell | U.K. | formulation of a Theory of energy-transfer processes in biological systems |
1979 | Herbert Charles Brown | U.S. | introduction of compounds of boron and phosphorus in the synthesis of organic substances |
Georg Wittig | West Germany | introduction of compounds of boron and phosphorus in the synthesis of organic substances | |
1980 | Paul Berg | U.S. | first preparation of a hybrid DNA |
Walter Gilbert | U.S. | Development of chemical and biological analyses of DNA structure | |
Frederick Sanger | U.K. | Development of chemical and biological analyses of DNA structure | |
1981 | Fukui Kenichi | Japan | orbital symmetry interpretation of chemical reactions |
Roald Hoffmann | U.S. | orbital symmetry interpretation of chemical reactions | |
1982 | Aaron Klug | U.K. | determination of the structure of biological substances |
1983 | Henry Taube | U.S. | study of electron-transfer reactions |
1984 | Bruce Merrifield | U.S. | Development of a Method of polypeptide synthesis |
1985 | Herbert A. Hauptman | U.S. | Development of a way to map the chemical structures of small molecules |
Jerome Karle | U.S. | Development of a way to map the chemical structures of small molecules | |
1986 | Dudley R. Herschbach | U.S. | Development of methods for analyzing basic chemical reactions |
Yuan T. Lee | U.S. | Development of methods for analyzing basic chemical reactions | |
John C. Polanyi | Canada | Development of methods for analyzing basic chemical reactions | |
1987 | Donald J. Cram | U.S. | Development of molecules that can link with other molecules |
Jean-Marie Lehn | France | Development of molecules that can link with other molecules | |
Charles J. Pedersen | U.S. | Development of molecules that can link with other molecules | |
1988 | Johann Deisenhofer | West Germany | Discovery of the structure of proteins needed in photosynthesis |
Robert Huber | West Germany | Discovery of the structure of proteins needed in photosynthesis | |
Hartmut Michel | West Germany | Discovery of the structure of proteins needed in photosynthesis | |
1989 | Sidney Altman | U.S. | Discovery of certain basic properties of RNA |
Thomas Robert Cech | U.S. | Discovery of certain basic properties of RNA | |
1990 | Elias James Corey | U.S. | Development of retrosynthetic analysis for synthesis of complex molecules |
1991 | Richard R. Ernst | Switzerland | Improvements in nuclear magnetic resonance spectroscopy |
1992 | Rudolph A. Marcus | U.S. | Explanation of how electrons transfer between molecules |
1993 | Kary B. Mullis | U.S. | Invention of techniques for gene study and manipulation |
Michael Smith | Canada | Invention of techniques for gene study and manipulation | |
1994 | George A. Olah | U.S. | Development of techniques to study hydrocarbon molecules |
1995 | Paul Crutzen | Netherlands | Explanation of processes that deplete Earth’s ozone layer |
Mario Molina | U.S. | Explanation of processes that deplete Earth’s ozone layer | |
F. Sherwood Rowland | U.S. | Explanation of processes that deplete Earth’s ozone layer | |
1996 | Robert F. Curl, Jr. | U.S. | Discovery of new carbon compounds called fullerenes |
Sir Harold W. Kroto | U.K. | Discovery of new carbon compounds called fullerenes | |
Richard E. Smalley | U.S. | Discovery of new carbon compounds called fullerenes | |
1997 | Paul D. Boyer | U.S. | Explanation of the enzymatic conversion of adenosine triphosphate |
Jens C. Skou | Denmark | Discovery of sodium-potassium-activated adenosine triphosphatase | |
John E. Walker | U.K. | Explanation of the enzymatic conversion of adenosine triphosphate | |
1998 | Walter Kohn | U.S. | Development of the density-functional Theory |
John A. Pople | U.K. | Development of computational Method s in quantum chemistry | |
1999 | Ahmed H. Zewail | Egypt/U.S. | Study of the transition states of chemical reactions using femtosecond spectroscopy |
2000 | Alan J. Heeger | U.S. | The discovery of plastics that conduct electricity |
Alan G. MacDiarmid | U.S. | The discovery of plastics that conduct electricity | |
Shirakawa Hideki | Japan | The discovery of plastics that conduct electricity | |
2001 | William S. Knowles | U.S. | Work on chirally catalyzed hydrogenation reactions |
Noyori Ryoji | Japan | Work on chirally catalyzed hydrogenation reactions | |
K. Barry Sharpless | U.S. | Work on chirally catalyzed oxidation reactions | |
2002 | John B. Fenn | U.S. | Development of techniques to identify and analyze proteins and other large molecules |
Tanaka Koichi | Japan | Development of techniques to identify and analyze proteins and other large molecules | |
Kurt Wüthrich | Switzerland | Development of techniques to identify and analyze proteins and other large molecules | |
2003 | Peter Agre | U.S. | Discoveries regarding water channels and ion channels in cells |
Roderick MacKinnon | U.S. | Discoveries regarding water channels and ion channels in cells | |
2004 | Aaron Ciechanover | Israel | Discovery of ubiquitin-mediated protein degradation |
Avram Hershko | Israel | Discovery of ubiquitin-mediated protein degradation | |
Irwin Rose | U.S. | Discovery of ubiquitin-mediated protein degradation | |
2005 | Yves Chauvin | France | Development of the metathesis Method in organic synthesis |
Robert H. Grubbs | U.S. | Development of the metathesis Method in organic synthesis | |
Richard R. Schrock | U.S. | Development of the metathesis Method in organic synthesis | |
2006 | Roger D. Kornberg | U.S. | Work concerning the molecular basis of eukaryotic transcription |
2007 | Gerhard Ertl | Germany | Studies of chemical processes on solid surfaces |
2008 | Martin Chalfie | U.S. | Discovery and Development of the green fluorescent protein, GFP |
Osamu Shimomura | U.S. | Discovery and Development of the green fluorescent protein, GFP | |
Roger Y. Tsien | U.S. | Discovery and Development of the green fluorescent protein, GFP | |
2009 | Venkatraman Ramakrishnan | U.S. | Studies of the structure and function of the ribosome |
Thomas Steitz | U.S. | Studies of the structure and function of the ribosome | |
Ada Yonath | Israel | Studies of the structure and function of the ribosome | |
2010 | Richard F. Heck | U.S. | Development of techniques to synthesize complex carbon molecules |
Negishi Ei-ichi | Japan | Development of techniques to synthesize complex carbon molecules | |
Suzuki Akira | Japan | Development of techniques to synthesize complex carbon molecules | |
2011 | Daniel Shechtman | Israel | Discovery of quasicrystals |
2012 | Brian K. Kobilka | U.S. | Studies of G-protein-coupled receptors |
Robert J. Lefkowitz | U.S. | Studies of G-protein-coupled receptors | |
2013 | Martin Karplus | Austria/U.S. | Development of multiscale models for complex chemical systems |
Michael Levitt | U.K./U.S./Israel | Development of multiscale models for complex chemical systems | |
Arieh Warshel | Israel/U.S. | Development of multiscale models for complex chemical systems | |
2014 | Eric Betzig | U.S. | Development of super-resolved fluorescence microscopy |
Stefan W. Hell | Germany | Development of super-resolved fluorescence microscopy | |
William E. Moerner | U.S. | Development of super-resolved fluorescence microscopy | |
2015 | Tomas Lindahl | Sweden | Mechanistic studies of DNA repair |
Paul Modrich | U.S. | Mechanistic studies of DNA repair | |
Aziz Sancar | Turkey/U.S. | Mechanistic studies of DNA repair | |
2016 | Jean-Pierre Sauvage | France | Design and synthesis of molecular machines |
J. Fraser Stoddart | U.K. | Design and synthesis of molecular machines | |
Bernard Feringa | Netherlands | Design and synthesis of molecular machines | |
2017 | Jacques Dubochet | Switzerland | Development of cryo-electron microscopy for the high-resolution structure determination of biomolecules in solution |
Joachim Frank | Germany/U.S. | Development of cryo-electron microscopy for the high-resolution structure determination of biomolecules in solution | |
Richard Henderson | U.K. | Development of cryo-electron microscopy for the high-resolution structure determination of biomolecules in solution | |
2018 | Frances Arnold | U.S. | First directed evolution of enzymes |
George P. Smith | U.S. | Development of phage display, a Method in which a bacteriophage can be used to evolve new proteins | |
Gregory P. Winter | U.K. | Work using the phage display Method for the directed evolution of antibodies | |
2019 | John B. Goodenough | U.S. | Development of lithium-ion batteries |
M. Stanley Whittingham | U.K./U.S. | Development of lithium-ion batteries | |
Yoshino Akira | Japan | Development of lithium-ion batteries | |
2020 | Emmanuelle Charpentier | France | Development of a Method for genome editing |
Jennifer Doudna | U.S. | Development of a Method for genome editing | |
2021 | Benjamin List | Germany | Development of asymmetric organocatalysis |
David W.C. MacMillan | U.K./U.S. | Development of asymmetric organocatalysis |
Hope you enjoyed reading about the Nobel Laureates in Chemistry 2022.
Between 1901 and 2021, 113 Nobel Prize laureates received the Nobel Prize in Chemistry.
Benjamin List and David MacMillan were awarded the Nobel Prize in Chemistry 2021 for developing organocatalysis, a precise new tool for molecular construction.
The United States has produced more Nobel laureates than any other country.
Jacobus Henricus Van ‘t Hoff received the first Nobel Prize in Chemistry
The Nobel Laureates in Chemistry 2022 has not yet been awarded.