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George Porter

George Porter, Baron Porter of Luddenham (1920–2002), was a British chemist renowned for pioneering the technique of flash photolysis, which enabled the study of extremely fast chemical reactions using short bursts of light energy.^[1]^[2] He shared the 1967 Nobel Prize in Chemistry with Ronald George Wreyford Norrish and Manfred Eigen for their groundbreaking work on disturbing chemical equilibria with very short pulses of energy to observe rapid reaction kinetics.^[1] This innovation revolutionized photochemistry and physical chemistry by allowing scientists to capture and analyze molecular behaviors on microsecond timescales, previously inaccessible.^[3] Born on 6 December 1920 in Stainforth, Yorkshire, England, Porter grew up in a modest mining community and attended Thorne Grammar School before earning a BSc in chemistry from the University of Leeds in 1941 as an Ackroyd scholar.^[2]^[3] During World War II, he served as a radar officer in the Royal Navy from 1941 to 1945, gaining expertise in electronics that later informed his experimental techniques.^[2] After the war, he pursued postgraduate studies at the University of Cambridge under Norrish, where in the late 1940s they co-developed flash photolysis—a method combining high-intensity flash lamps with spectroscopic detection to initiate and monitor photochemical reactions in real time.^[1]^[2] Porter remained at Cambridge as a demonstrator and assistant director of research until 1954, earning a fellowship at Emmanuel College from 1952 to 1954.^[3] In 1955, Porter was appointed professor of physical chemistry at the University of Sheffield, where he expanded his research on fast reactions.^[3] He joined the Royal Institution in London in 1963 as professor of chemistry, becoming director in 1966—a position he held until 1986, during which he also served as Fullerian Professor of Chemistry until 1988.^[3] Under his leadership, the institution advanced public engagement with science; he delivered the Royal Institution Christmas Lectures in 1969 and 1976 and advocated for the importance of fundamental research.^[3] Later, he chaired the Centre for Photomolecular Sciences at Imperial College London from 1987 and was elected president of the Royal Society from 1985 to 1990.^[2] Knighted in 1972 and created a life peer in 1990, Porter died on 31 August 2002 in Canterbury, Kent, leaving a legacy of over 300 publications and influence on generations of chemists.^[2]^[1]

Early Life and Education

Childhood and Early Influences

George Porter was born on December 6, 1920, in Ash House, a modest dwelling in Stainforth, a village in the West Riding of Yorkshire, England. He was the only child of John Smith Porter, a local builder who had limited formal education until age 13 and served as a lay Methodist preacher, and Alice Ann Roebuck, in a working-class family shaped by the rural industrial landscape of coal mining and railways. One of his grandfathers worked as a coal miner, underscoring the family's ties to Yorkshire's industrial heritage, while the household environment fostered a sense of determination influenced by his father's regrets over his own curtailed schooling.^[4]^[5] Porter's early education began at the local village junior school from 1925 to 1931, where he first displayed curiosity about the natural world. At around age eight or nine, his father ignited a lifelong passion for chemistry by gifting him a chemistry set, allowing him to conduct simple experiments at home. This early exposure, combined with the self-directed play in the modest family setting, highlighted his innate inquisitiveness amid the constraints of a working-class upbringing in an area blending rural tranquility with industrial activity.^[6]^[7] In 1931, Porter won a county scholarship to Thorne Grammar School near Doncaster, where he received a more structured introduction to science through dedicated teachers. His chemistry and physics instructor, Mr. Moore, and English teacher, Mr. Todd, provided key inspiration, encouraging his enthusiasm for scientific inquiry and experimentation. To accommodate his growing interest, his father repurposed an old bus as a private laboratory, enabling Porter to explore chemical reactions safely away from the house and nurturing his determination to pursue science despite limited resources. These formative experiences in the industrial Yorkshire countryside laid the groundwork for his later academic path.^[7]^[6]

Formal Education and Wartime Service

In 1938, George Porter enrolled at the University of Leeds as an Ackroyd Scholar to study chemistry.^[5] There, he developed a strong interest in physical chemistry and chemical kinetics, largely inspired by the teaching of M. G. Evans, who emphasized the dynamic aspects of molecular reactions.^[5]^[8] During his final honors year, Porter also took a specialized course in radio physics, which provided foundational knowledge in electronics and pulse techniques that would later influence his scientific work.^[5] Porter's studies were interrupted by the outbreak of World War II, and in 1941, he joined the Royal Naval Volunteer Reserve as an ordinary seaman, soon being commissioned as an officer in the Special Branch.^[5] From 1942 to 1944, he served as a radar group officer in the Western Approaches and Mediterranean commands, where he maintained and troubleshot radar equipment on destroyers during anti-submarine warfare operations, including the detection and sinking of U-boats and support for the Allied invasion of North Africa (Operation Torch).^[8] Later, from 1943 to 1945, he worked as an instruction officer at a radar training school in Belfast and was assigned to Force X for potential operations against Japan, though he was demobilized following Japan's surrender.^[5]^[8]^[2] Following his demobilization in 1945, Porter returned to the University of Leeds and completed his Bachelor of Science degree in chemistry that year. He then moved to the University of Cambridge as a postgraduate research student under Professor R. G. W. Norrish, where he began his PhD studies on free radicals in gaseous photochemical reactions using flow techniques.^[5] This period marked Porter's first significant exposure to photochemistry concepts, as preparatory work on transient species and light-induced reactions laid the groundwork for his later innovations, culminating in the completion of his PhD in 1949.^[5]^[8]

Professional Career

Early Research and Academic Positions

Following his completion of a PhD under Ronald Norrish at the University of Cambridge in 1949, George Porter was appointed as a demonstrator in physical chemistry, continuing his close collaboration with Norrish on photochemical research.^[5] In 1952, he advanced to the role of assistant director of research in physical chemistry, a position he held until 1954 while contributing to studies of transient chemical species.^[6] In 1954, Porter took a one-year appointment as assistant director at the British Rayon Research Association in Manchester, where he investigated photochemical fading of dyes.^[6] He then transitioned in 1955 to the University of Sheffield as Professor of Physical Chemistry, the institution's first such chair, and promptly established a specialized laboratory for photochemical investigations.^[5]^[7] At Sheffield, Porter assumed significant administrative responsibilities, including serving as head of the chemistry department and Firth Professor from 1963 onward, roles that extended until his departure in 1966.^[6] He developed a dedicated research group centered on transient species in chemical reactions, navigating postwar constraints such as scarce funding in Britain and challenges in attracting students to kinetics-focused studies.^[6]

Leadership in Scientific Institutions

In 1966, George Porter was appointed Director of the Royal Institution and Fullerian Professor of Chemistry, succeeding Sir Lawrence Bragg, a position he held until 1986.^[5]^[3] During his tenure, he led significant modernization efforts, including securing funds through the Faraday Centenary Appeal in 1967 and a subsequent 1976 appeal that supported infrastructure upgrades, such as the construction of the Bernard Sunley Theatre, and expanded educational programs like Schools Lectures.^[9] He also reformed the institution's governance by merging the Committees of Managers and Visitors into a single executive Council, enhancing administrative efficiency and promoting interdisciplinary initiatives in areas like photobiology.^[9] Porter's leadership extended to other key roles that influenced British scientific organizations. In 1970, he served as President of the Chemical Society for two years, during which he guided early discussions on amalgamating it with other bodies to form a unified chemical sciences entity.^[5]^[7] In 1966, he became Honorary Professor of Physical Chemistry at the University of Kent, and in 1967, he was appointed Visiting Professor at University College London, roles that allowed him to foster academic collaborations while maintaining his institutional oversight.^[5]^[9] From 1985 to 1990, Porter served as President of the Royal Society, succeeding Sir Andrew Huxley and leveraging the position to advocate for increased government funding for science amid economic pressures in the 1980s.^[6]^[9] He emphasized international collaborations, including efforts to support global scientific exchanges and human rights for scientists, such as in the case of Andrei Sakharov, while chairing the Committee on the Public Understanding of Science (COPUS) to bridge institutional science with public engagement.^[9] These initiatives strengthened the Royal Society's role in fostering worldwide partnerships during a period of fiscal constraint.^[7] Following his Royal Society presidency, Porter served as Chancellor of the University of Leicester from 1986 to 1995 and chaired the Centre for Photomolecular Sciences at Imperial College London from 1990 until his death.^[9]^[7]

Scientific Research

Invention of Flash Photolysis

In 1947, while working under Ronald George Wreyford Norrish at the University of Cambridge, George Porter conceptualized the flash photolysis technique as a means to study fast chemical reactions by generating transient species with intense, short bursts of light.^[10] This idea drew inspiration from Porter's wartime service developing radar systems, where he encountered high-intensity flash tubes used in aerial photography.^[10] The method aimed to produce and detect short-lived intermediates, such as free radicals, in the gas phase, overcoming the limitations of continuous illumination techniques that failed to capture rapid kinetics.^[11] The technical setup of flash photolysis involved discharging a bank of capacitors through a quartz flash lamp filled with inert gas to create a high-energy photolyzing pulse, typically around 2 milliseconds initially, which initiated reactions in a sample vessel.^[12] This was followed by a delayed spectroscopic flash from a similar lamp to probe the resulting transients via absorption spectroscopy, with the timing controlled by a rotating sector disk for early implementations.^[10] The system achieved microsecond temporal resolution by the early 1950s, allowing real-time observation of species with lifetimes as short as 10 microseconds, using a magnesium oxide-coated reflector to enhance light efficiency and a vacuum line for sample preparation.^[13] The method was first described in a 1949 publication, with early experiments demonstrating its application to gaseous systems, such as the flash photolysis of NO₂ to study the kinetics of the H-O explosion or chlorine-oxygen mixtures to observe the ClO radical.^[14] These demonstrated the technique's ability to detect free radicals directly via transient absorption spectra in the near-ultraviolet region, confirming intermediates' identity and enabling kinetic measurements. Later, in 1953, the technique was applied to the photolysis of acetone vapor, observing the transient absorption spectra of methyl radicals (CH₃•).^[15] The basic process for acetone can be represented by the equation:

\text{CH}_3\text{COCH}_3 + h\nu \rightarrow 2 \text{CH}_3^\bullet + \text{CO}

This simplified photodecomposition equation illustrates the primary dissociation pathway under ultraviolet irradiation, though actual yields depend on wavelength and energy input; derivation involves quantum yield considerations from bond dissociation energies (e.g., C-C bond in acetone at ~335 kJ/mol), but limitations include secondary reactions causing temperature rises that complicate radical recombination rates.^[16] Over the subsequent years, the technique evolved through refinements in light sources and detection systems, transitioning from mechanical timing to electronic triggers for precise delays as short as 20 microseconds.^[13] Shorter flash lamps (e.g., 20-50 cm) and smaller, higher-voltage capacitors (10-30 μF at 8-10 kV) reduced pulse durations to 35-50 microseconds, minimizing heating effects and enabling the study of reaction mechanisms in real time by resolving sequential steps in radical formation and decay.^[10] These improvements, detailed in early 1950s publications, expanded the method's precision for spectroscopic analysis of transient species without altering their natural kinetics.^[17]

Applications to Chemical Kinetics and Photosynthesis

Flash photolysis enabled the direct observation of transient intermediate species in rapid chemical reactions, particularly free radical chain reactions, by providing time-resolved spectroscopic data with initial resolutions on the microsecond scale. In early applications, Porter studied the ClO radical formed in the flash photolysis of chlorine-oxygen mixtures, identifying its absorption spectrum and measuring its decay kinetics, which revealed second-order recombination rates influenced by wall effects and third-body molecules.^[10] By the 1960s, advancements with laser excitation improved time resolution to nanoseconds, allowing quantification of lifetimes for short-lived radicals, such as approximately 10^{-9} seconds for certain aromatic free radicals like benzyl and phenoxyl species observed in gas-phase photolysis.^[10] These studies extended to atmospheric chemistry, where ClO kinetics informed models of ozone depletion mechanisms, and to combustion processes, providing rate constants for radical recombination essential for understanding chain propagation.^[10] A seminal example in chemical kinetics involved the recombination of iodine atoms following flash photolysis of iodine vapor, confirming a third-order mechanism with rate constants on the order of 10^{-32} cm^6 molecule^{-2} s^{-1} at room temperature, exhibiting negative activation energies due to chaperon effects from inert gases like argon.^[10] This work demonstrated how flash photolysis could resolve elementary steps in chain reactions, yielding quantitative data on bimolecular and termolecular rate constants that were previously inaccessible. In photosynthesis research, Porter applied flash photolysis in the 1960s to identify short-lived chlorophyll intermediates. Later, collaborating with biologists such as James Barber, he bridged photochemistry and biological systems. Using microbeam flash photolysis on concentrated chlorophyll solutions and plant tissues, he detected the triplet state of chlorophyll a and b, with lifetimes around 3 ms for chlorophyll b triplets in solid matrices like cholesterol, independent of concentration below quenching thresholds.^[18] Quantum yields for triplet formation were measured as 0.64 for chlorophyll a and 0.88 for chlorophyll b in ether solutions at 23°C, highlighting intersystem crossing efficiency but revealing lower yields in dry hydrocarbons due to excited-state dissociation.^[19] No triplets were observed in intact or etiolated plant leaves, but detergent treatment yielded up to 15% triplet formation, suggesting quenching by biological quenchers and implications for electron transfer steps in photosystems.^[18] These findings elucidated energy conversion in photosynthesis, with triplet states facilitating energy transfer but risking reactive oxygen species if not quenched efficiently. In vitro models developed by Porter mimicked charge separation, such as photolysis of dyes or chlorophyll-quinone systems to study electron transfer rates on picosecond scales, informing artificial photosynthesis for solar energy. For instance, flash-induced electron transfer from excited chlorophyll to quinone demonstrated kinetics relevant to photosystem II water oxidation, though full water splitting remained partial in these setups. Such experiments provided rate constants for steps like radical anion formation, e.g., e^- + O_2 \to O_2^-, underscoring inefficiencies in biological energy transduction.

Awards and Honors

Nobel Prize and Major Scientific Awards

In 1967, George Porter was awarded the Nobel Prize in Chemistry, sharing the honor with Manfred Eigen, who received half the prize, and Ronald George Wreyford Norrish, with whom Porter jointly received the other half, for their pioneering studies of extremely fast chemical reactions. Porter's specific contribution was recognized for developing flash photolysis, a technique that enabled the observation of short-lived intermediates in photochemical processes.^[20]^[1] On December 11, 1967, during the Nobel ceremonies in Stockholm, Porter presented his lecture titled "Flash Photolysis and Some of Its Applications," where he elaborated on the method's role in detecting and analyzing transient species, such as free radicals and excited states, that occur on microsecond timescales in chemical reactions. This work underscored the technique's broad applicability to understanding reaction mechanisms in photochemistry.^[21] Porter's innovations garnered further recognition during the peak of photochemical research in the 1960s and beyond. In 1971, he received the Davy Medal from the Royal Society for his distinguished contributions to the understanding of chemical reactions through spectroscopic methods. Earlier, in 1955, the Chemical Society awarded him the Corday-Morgan Medal for his research on fast reactions. He also earned the Longstaff Medal from the Chemical Society in 1981, honoring his advancements in physical chemistry. In 1976, he received the Kalinga Prize from UNESCO for the popularization of science. In 1978, he was awarded the Rumford Medal from the Royal Society for his work on fast chemical reactions. Additionally, Porter was conferred numerous honorary doctorates from various universities, reflecting his global impact on the field.^[5]^[22]^[23]^[24]^[25]

National Honors and Peerage

Porter's contributions to science were recognized early in his career through his election as a Fellow of the Royal Society (FRS) in 1960, a distinction that highlighted his emerging influence in physical chemistry.^[5] This honor, conferred by one of Britain's most prestigious scientific bodies, marked him as a leading figure among the nation's scholars.^[9] In 1972, Porter was knighted as Sir George Porter in the New Year Honours, specifically for his services to chemistry, reflecting the broader impact of his research on national scientific advancement.^[26] This title underscored his growing stature beyond academia, positioning him as a key ambassador for British science. Porter received further acclaim in 1989 with his appointment to the Order of Merit (OM), a rare personal honor bestowed by the Sovereign and limited to just 24 living members at any time, acknowledging exceptional distinction in their field.^[27] The following year, in 1990, he was created a life peer as Baron Porter of Luddenham, of Luddenham in the County of Kent, granting him a seat in the House of Lords where he contributed to debates on science and education until his death.^[28] During his presidency of the Royal Society from 1985 to 1990, Porter played a central role in the institution's honors processes, personally presenting medals such as the Copley Medal and overseeing committees that advised on awards for scientific excellence and policy-related recognitions.^[29] This involvement extended his influence into shaping how scientific achievements were honored at a national level.

Personal Life

Family

George Porter married Stella Jean Brooke on August 25, 1949, shortly after completing his PhD at the University of Cambridge, where they had met three years earlier at a dance held at the London College of Dance.^[5] The couple shared a close partnership, with Stella providing steadfast support throughout Porter's career, including accompanying him on international travels and contributing to their social life as a family. The Porters had two sons: John Brooke Porter, born on September 22, 1952, who became a professor of haematology at University College London, and Andrew Christopher George Porter (1955–2023), born on August 17, 1955, in Knutsford, Sheffield, who was a scientist and lecturer specializing in DNA replication at Royal Holloway, University of London.^[5]^[30]^[31]^[32] Family life during the early years was centered in Cambridge, where the couple settled after their marriage, before relocating to Sheffield in 1955 when Porter accepted a professorship there; the family later moved to London in 1966 upon his appointment as Director of the Royal Institution. These transitions were managed with the family's active involvement, as Stella helped maintain stability amid Porter's demanding professional commitments. Porter often balanced his intense laboratory work—frequently extending into late hours—with family responsibilities, drawing on Stella's role in creating a welcoming home environment that facilitated both personal relaxation and professional networking. In Sheffield and later at the Royal Institution's London residence, the family hosted numerous gatherings for scientists and colleagues, where Stella served as a gracious hostess, fostering an atmosphere that blended domestic warmth with intellectual exchange; such events highlighted their shared enthusiasm for sociability, occasionally featuring lighthearted moments like Porter's playful demonstrations of physics tricks using household items.

Interests and Science Communication

George Porter's personal interests extended beyond his scientific pursuits, reflecting a balanced life that intertwined recreation with family. His primary hobby was sailing, which he shared with his wife Stella and their children aboard their boat Annobelle, fostering family bonding during outings on the Kentish coast near their home in Luddenham.^[8] He also enjoyed music, participating in choral groups like the Emmanuel Singers and performances of Gilbert and Sullivan operettas during his time in Cambridge, activities that highlighted his sociable nature and integrated into social gatherings with colleagues and family.^[8] Porter was a pioneering figure in science communication, dedicated to bridging the gap between specialists and the public. In the 1950s and 1960s, he contributed to early BBC television programs, including an appearance on the 1959 series Eye on Research and a 1964 episode of Horizon demonstrating how everyday materials like nylon and polythene derive from simple compounds such as candles, making complex photochemistry accessible to lay audiences.^[33]^[34] His efforts expanded in the 1970s with the BBC-broadcast Royal Institution Christmas Lectures, such as the 1976 series The Natural History of a Sunbeam, where he explained the role of light in chemistry and life through engaging demonstrations.^[8] Additionally, the 1965–1966 BBC series The Laws of Disorder, based on his Royal Institution discourse on thermodynamics, further popularized concepts of chemical change.^[8]^[7] At the Royal Institution, Porter revitalized public engagement through lectures and live demonstrations. As director from 1966, he reinvigorated the historic Friday Evening Discourses tradition—dating back to 1825—by delivering dozens of talks with simple, visually striking experiments, such as his 1960 discourse on "Very Fast Chemical Reactions," which used everyday items like matchboxes to illustrate flash photolysis.^[7]^[35] He also presented school lectures and the Royal Institution Christmas Lectures in 1969 ("Time Machines") and 1976 ("The Natural History of a Sunbeam"), emphasizing photochemistry's wonders to inspire young audiences.^[8] In public talks, Porter often shared motivational anecdotes from his career to humanize scientific discovery. He frequently recounted the thrill of first observing transient absorption spectra during early flash photolysis experiments in the 1950s, describing how the spectra of short-lived substances gradually emerged under the safelight of a darkroom as "one of the most rewarding experiences of his life," a story that underscored the excitement of unveiling hidden chemical worlds.^[5]

Legacy

Publications and Writings

George Porter's scholarly contributions were extensive, encompassing over 300 scientific papers primarily focused on photochemistry, fast reaction kinetics, and related fields. His publications appeared in prestigious journals such as the Proceedings of the Royal Society and the Transactions of the Faraday Society, reflecting his pioneering role in advancing spectroscopic techniques for transient species. Later in his career, Porter also produced works on science education, emphasizing the accessibility of chemical concepts to broader audiences. A cornerstone of Porter's oeuvre is his collaborative work with Ronald G. W. Norrish on flash photolysis. In a seminal 1949 paper published in Nature, they described chemical reactions produced by very high light intensities, laying the groundwork for observing short-lived intermediates. This was elaborated in Porter's 1950 article in the Proceedings of the Royal Society, titled "Flash photolysis and spectroscopy: a new method for the study of free radical reactions," which detailed the technique's application to gaseous free radicals and established its utility for kinetic studies.^[36] Throughout the 1950s, Porter published numerous papers on the lifetimes of free radicals, often in the Journal of the Chemical Society and related periodicals. These works, including series on transient absorption spectra and radical decay rates in solution, provided quantitative insights into ultrafast photochemical processes, such as triplet state dynamics in organic molecules. Representative examples include investigations of radical recombination and energy transfer, which built directly on flash photolysis data to quantify lifetimes on microsecond scales. Porter's books further exemplified his commitment to disseminating research beyond academia. In 1962, he authored Chemistry for the Modern World, a concise introduction to chemical kinetics and its societal implications, to engage general readers with concepts like reaction rates and energy barriers. His 1996 volume, Chemistry in Microtime: Selected Writings on Flash Photolysis, Free Radicals, and the Excited State, compiled key papers from the 1940s to the 1990s, offering reflections on the evolution of ultrafast spectroscopy and its impact on understanding molecular dynamics.^[37]^[38] These writings played a pivotal role in bridging academic research and public understanding, making complex photochemical principles accessible while influencing subsequent generations of scientists. Porter's 1967 Nobel lecture, "Flash photolysis and some of its applications," published in the official Nobel series, synthesized his contributions to rapid reaction studies and highlighted applications in biology, such as photosynthesis. Through such publications, he not only documented his discoveries but also advocated for the integration of kinetics into mainstream chemical education.

Influence on Science Policy and Public Engagement

Following his retirement from formal leadership roles, George Porter, elevated to the peerage as Baron Porter of Luddenham in 1990, actively campaigned in the House of Lords until 2002 for enhanced public funding of basic research. In his maiden speech in May 1991 and subsequent interventions, he emphasized the need for sustained support for "blue-skies" research through bodies like the research councils, arguing that such funding was essential for long-term scientific breakthroughs. Porter frequently criticized the prevalence of short-term grants, which he viewed as detrimental to innovative, curiosity-driven science, warning that they prioritized immediate applicability over foundational discoveries. Porter's advocacy extended to human rights in science and environmental policy, where he championed ethical practices and international collaboration. He supported dissident scientists, including efforts on behalf of Andrei Sakharov, and used his platform to address global challenges like sustainable energy derived from photochemistry. In speeches, he highlighted photochemistry's potential for harnessing solar energy, noting inefficiencies in natural processes while advocating for policy frameworks to promote renewable technologies. Porter's legacy in public engagement continues to inspire modern science communicators through his eloquent promotion of chemistry's societal relevance. The European Photochemical Association established the Porter Medal in his honor in 1988, first awarded to Porter himself, to recognize outstanding contributions to photochemistry. He died on August 31, 2002, in Canterbury, England, with tributes underscoring his pivotal role in elevating chemistry's public profile and fostering broader appreciation for science. His pioneering work in flash photolysis laid the groundwork for advancements in ultrafast spectroscopy, techniques now integral to femtochemistry studies of molecular dynamics on atomic timescales.^[39]

References

[1]
George Porter – Facts - NobelPrize.org
George Porter, Nobel Prize in Chemistry 1967. Born: 6 December 1920, Stainforth, United Kingdom. Died: 31 August 2002, Canterbury, United Kingdom.
[2]
Lord Porter of Luddenham | Education | The Guardian
Sep 3, 2002 · Lord Porter of Luddenham, who has died aged 81, shared the 1967 Nobel Chemistry Prize for his pioneering work with Ronald Norrish at Cambridge on high-speed, ...
[3]
Baron George Porter of Luddenham (1920-2002) - Royal Institution
In 1967 he won the Nobel Prize for his work on chemical reactions triggered by light, and for photographing the behaviour of molecules during fast reactions.
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BBC NEWS | Science/Nature | Obituary: Lord Porter
Sep 2, 2002 · George, Lord Porter, who has died at the age of 81, was a Nobel Prize-winning scientist and a former President of the Royal Society.<|control11|><|separator|>
[5]
George Porter – Biographical - NobelPrize.org
George Porter was born in the West Riding of Yorkshire on the 6th December 1920. He married Stella Jean Brooke on the 25th August 1949 and they have two sons, ...Missing: Stainforth | Show results with:Stainforth
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George Porter - Physics Today
Porter was born in Stainforth, Yorkshire, on 6 December 1920 and attended Thorne Grammar School, where his interest in science began. His father bought him an ...Missing: influences | Show results with:influences
[7]
George Porter: a peer among scientists - ScienceDirect
He was educated at the village junior school, and then at Thorne Grammar School, Doncaster. He was encouraged in his early enthusiasm for chemistry by his ...
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George Porter KT OM, Lord Porter of Luddenham. 6 December 1920
Dec 1, 2004 · Lord Porter of Luddenham was the creator of flash photolysis and a ... George Porter KT OM, Lord Porter of Luddenham. 6 December 1920 ...
[9]
None
### Summary of George Porter's Childhood, Family Background, Early Education, and Initial Interests in Science
[10]
[PDF] The genesis of flash photolysis† - Chemistry
Mar 25, 2003 · A brief account is given of the construction of the first flash photolysis apparatuses at Cambridge and their application to gas phase systems.
[11]
[PDF] George Porter - Nobel Lecture
My original conception of the flash photolysis technique was as follows: the transient intermediates, which were, in the first place, to be gaseous free.
[12]
https://www.chemistry.as.miami.edu/_assets/pdf/murthy-group/porter-1.pdf
[13]
None
### Summary of Microsecond Flash Photolysis Development in George Porter’s Lab at Cambridge (Early 1950s)
[14]
https://doi.org/10.1038/164658a0
[15]
https://doi.org/10.1098/rspa.1953.0045
[16]
https://doi.org/10.1098/rspa.1950.0049
[17]
https://doi.org/10.1039/b300213f
[18]
https://doi.org/10.1098/rspa.1966.0222
[19]
The Nobel Prize in Chemistry 1967 - NobelPrize.org
The Nobel Prize in Chemistry 1967 was divided, one half awarded to Manfred Eigen, the other half jointly to Ronald George Wreyford Norrish and George Porter.
[20]
George Porter – Nobel Lecture - NobelPrize.org
Speech, Nobel Lecture, December 11, 1967, Flash Photolysis and Some of Its Applications, Read the Nobel Lecture Pdf 579 kB.
[21]
George Porter - The Pontifical Academy of Sciences
His father was a local builder, who in his spare time served as a lay Methodist preacher and school governor; one of his grandfathers was a coal miner. Most of ...Missing: childhood family background
[22]
SUPPLEMENT TO THE LONDON GAZETTE, IST JANUARY 1972
George PORTER, F.R.S , Fullenan Professor of. Chemistry ... For services to medicine and the community. CENTRAL CHANCERY OF. THE ORDERS OF KNIGHTHOOD.
[23]
https://www.rsc.org/prizes-funding/prizes/find-a-prize/longstaff-prize/previous-winners/
[24]
Lord Porter Of Luddenham - Hansard - UK Parliament
Sir George Porter, Knight, O.M., having been created Baron Porter of Luddenham, of Luddenham in the County of Kent, for life—Was, in his robes, ...
[25]
The award of medals by the President, Sir George Porter ... - Journals
Apr 9, 1990 · The Copley Medal is awarded to Dr C. Milstein, F. R. S., in recognition of his outstanding contributions to immunology, in particular to the ...Missing: committee | Show results with:committee
[26]
Hon. John Brooke Porter - Person Page
John Brooke Porter was born on 22 September 1952. ... He is the son of George Porter, Baron Porter of Luddenham and Stella Jean Brooke. ... He married Suzanne ...Missing: career | Show results with:career
[27]
John PORTER | Professor of Haematology | MA MD FRCP FRCPath
John Brooke Porter. MA MD FRCP FRCPath; Professor at University College London.
[28]
the Royal Institution, George Porter and the two cultures, 1959–64
Mar 11, 2015 · This paper examines the cultural reasons why in 1964 the Royal Institution (RI) selected George Porter, who became the only person so far to have been Director ...Missing: challenges | Show results with:challenges
[29]
Horizon at 60 - BBC
Professor George Porter demonstrates how nylon, polythene and rocket fuel have all stemmed from candles in June 1964. The televising of science. It's ...<|separator|>
[30]
[PDF] Obituary - Chemistry
George Porter (Figure 1) made funda- mental contributions to our understand- ing of fast reactions between atoms and molecules. His promotion of the public.
[31]
Flash photolysis and spectroscopy. A new method for the study of ...
A new technique of flash photolysis and spectroscopy has been developed, using gas-filled flash discharge tubes of very high power.
[32]
Chemistry for the Modern World. George Porter. Barnes and Noble ...
Chemistry Popularization: Chemistry for the Modern World. George Porter. Barnes and Noble, New York, 1962. ix + 116 pp. Illus. $2. · Formats available · (0) ...<|control11|><|separator|>
[33]
https://royalsocietypublishing.org/doi/10.1098/rsnr.2014.0041
[34]
George Porter (1920–2002) | Nature
Oct 10, 2002 · Porter, a Yorkshireman, displayed a passion for science as a schoolboy and obtained his BSc in chemistry at the University of Leeds. At ...