Rutherford,
Ernest, 1st Baron
Rutherford
of Nelson and Cambridge
Rutherford, Ernest, 1st Baron Rutherford of Nelson and Cambridge
(1871-1937), British physicist, who became a Nobel laureate for his pioneering
work in nuclear physics and for his theory of the structure of the atom.
Rutherford was born in Nelson, New Zealand, and educated at the
University of New Zealand and the University of Cambridge. He was professor of
physics at McGill University in Montréal, Québec, Canada, from 1898 to 1907 and
at the University of Manchester in England during the following 12 years. After
1919 he was professor of experimental physics and director of the Cavendish
Laboratory at the University of Cambridge and also held a professorship, after
1920, at the Royal Institution of Great Britain in London.
Rutherford was one of the first and most important researchers in
nuclear physics. Soon after the discovery of radioactivity in 1896 by the
French physicist Antoine Henri Becquerel, Rutherford identified the three main
components of radiation and named them alpha, beta, and gamma rays. He also
showed that alpha particles are helium nuclei. His study of radiation led to
his formulation of a theory of atomic structure, which was the first to
describe the atom as a dense nucleus about which electrons circulate in orbits
(see Atom).
In 1919 Rutherford conducted an important experiment in nuclear
physics when he bombarded nitrogen gas with alpha particles and obtained atoms
of an oxygen isotope and protons. This transmutation of nitrogen into oxygen
was the first artificially induced nuclear reaction. It inspired the intensive
research of later scientists on other nuclear transformations and on the nature
and properties of radiation. Rutherford and the British physicist Frederick Soddy
developed the explanation of radioactivity that scientists accept today. The rutherford, a unit of radioactivity, was named in his honor.
Rutherford was elected a fellow of the Royal Society in 1903 and
served as president of that institution from 1925 to 1930. He was awarded the
1908 Nobel Prize in chemistry, was knighted in 1914, and was made a baron in
1931. He died in London on October 19, 1937, and was buried in Westminster
Abbey. His writings include Radioactivity (1904); Radiations from
Radioactive Substances (1930), which he wrote with British physicists Sir
James Chadwick and Charles Drummond Ellis, and which has become a standard
text; and The Newer Alchemy (1937). In 1997 the International Union of
Pure and Applied Chemistry announced that the chemical element with the atomic
number 104 would officially be given the name rutherfordium
(Rf) in Rutherford’s honor.
Microsoft ® Encarta ® Reference Library 2003.
© 1993-2002 Microsoft Corporation. All rights reserved.
Rutherford,
Ernest, Baron Rutherford ...
b. Aug. 30, 1871,
Spring Grove, N.Z.
d. Oct. 19, 1937, Cambridge, Cambridgeshire, Eng.
British physicist who laid the groundwork for the
development of nuclear
physics. He was awarded the Nobel Prize for
Chemistry in 1908.
Rutherford is to
be ranked in fame with Sir Isaac Newton and Michael Faraday. Indeed, just as
Faraday is called the "father of electricity," so a similar
description might be applied to Rutherford in relation to nuclear energy. He
contributed substantially to the understanding of the disintegration and
transmutation of the radioactive elements, discovered and named the particles
expelled from radium,
identified the alpha
particle as a helium atom and with its aid evolved the nuclear theory of
atomic structure, and used that particle to produce the first artificial
disintegration of elements. Rutherford was the principal founder of the field
of atomic
physics. In the universities of McGill, Manchester, and Cambridge he led
and inspired two generations of physicists who--to use his own
words--"turned out the facts of Nature," and in the Cavendish
Laboratory his "boys" discovered the neutron
and artificial disintegration by accelerated particles.
Early life
Rutherford was
the fourth of the 12 children of James, a wheelwright at Brightwater
near Nelson on South Island, New Zealand, and Martha Rutherford. His parents,
who had emigrated from Great Britain, denied themselves many comforts so that
their children might be well educated. In 1887 Ernest won a scholarship to
Nelson College, a secondary school, where he was a popular boy, clever with his
hands, and a keen footballer. He won prizes in history and languages as well as
mathematics. Another scholarship allowed him to enroll
in Canterbury College, Christchurch, from where he graduated with a B.A. in
1892 and an M.A. in 1893 with first-class honours in mathematics and physics.
Financing himself by part-time teaching, he stayed for a fifth year to do
research in physics, studying the properties of iron in high-frequency
alternating magnetic fields. He found that he could detect the electromagnetic
waves--wireless waves--newly discovered by the German physicist Heinrich
Hertz, even after they had passed through brick walls. Two substantial
scientific papers on this work won for him an "1851 Exhibition"
scholarship, which provided for further education in England.
Before leaving
New Zealand he became unofficially engaged to Mary Newton, a daughter of his
landlady in Christchurch. Mary preserved his letters from England, as did his
mother, who lived to age 92. Thus, a wealth of material is available that sheds
much light on the nonscientific aspects of his
fascinating personality.
On his arrival in
Cambridge in 1895, Rutherford began to work under, professor of experimental
physics at the university's Cavendish Laboratory. Continuing his work on the
detection of Hertzian waves over a distance of two
miles, he gave an experimental lecture on his results before the Cambridge
Physical Society and was delighted when his paper was published in the Philosophical
Transactions of the Royal Society of London, a signal honour for so young
an investigator.
Rutherford made a
great impression on colleagues in the Cavendish Laboratory, and Thomson held
him in high esteem. He also aroused jealousies in the more conservative members
of the Cavendish fraternity, as is clear from his letters to Mary. In December
1895, when Röntgen discovered X rays, Thomson asked Rutherford to join him in a study
of the effects of passing a beam of X rays through a gas. They discovered that
the X rays produced large quantities of electrically
charged particles, or carriers of positive and negative electricity, and that
these carriers, or ionized
atoms, recombined to form neutral molecules. Working on his
own, Rutherford then devised a technique for measuring the velocity and
rate of recombination of these positive and negative ions. The published papers
on this subject remain classics to the present day.
In 1896 the
French physicist Henri Becquerel discovered that uranium
emitted rays that could fog a photographic plate as did X
rays. Rutherford soon showed that they also ionized air but that they were
different from X rays, consisting of two distinct
types of radiation. He named them alpha rays, highly powerful in producing
ionization but easily absorbed, and beta
rays, which produced less radiation but had more penetrating ability. He
thought they must be extremely minute particles of matter.
In 1898
Rutherford was appointed to the chair of physics at McGill University in
Montreal. To Mary he wrote, "the salary is only 500 pounds but enough for
you and me to start on." In the summer of 1900 he traveled
to New Zealand to visit his parents and get married. When his daughter Eileen,
their only child, was born the next year, he wrote his mother "it is
suggested that I call her Ione' after my respect for
ions in gases."
Contributions
in physics
Toward the end of
the 19th century many scientists thought that no new advances in physics
remained to be made. Yet within three years Rutherford succeeded in marking out
an entirely new branch of physics called radioactivity.
He soon discovered that thorium
or its compounds disintegrated into a gas that in turn disintegrated into an
unknown "active deposit," likewise radioactive. Rutherford and a
young chemist, , then investigated three groups of
radioactive elements--radium, thorium, and actinium. They concluded in 1902
that radioactivity was a process in which atoms of one element spontaneously
disintegrated into atoms of an entirely different element, which also remained
radioactive. This interpretation was opposed by many chemists who held firmly
to the concept of the indestructibility of matter; the suggestion that some
atoms could tear themselves apart to form entirely different kinds of matter
was to them a remnant of medieval alchemy.
Nevertheless,
Rutherford's outstanding work won him recognition by the Royal Society, which
elected him a fellow in 1903 and awarded him the Rumford medal in 1904. In his
book Radio-activity
(1904) he summarized the results of research in that subject. The evidence he marshaled for radioactivity was that it is unaffected by
external conditions, such as temperature and chemical change; that more heat is
produced than in an ordinary chemical reaction; that new types of matter are produced
at a rate in equilibrium with the rate of decay; and that the new products
possess distinct chemical properties.
Rutherford, a
prodigious worker with tremendous powers of concentration, continued to make a succession
of brilliant discoveries--and with remarkably simple apparatus. For example, he
showed (1903) that alpha rays can be deflected by electric and magnetic fields,
the direction of the deflection proving that the rays are particles of positive
charge; he determined their velocity and the ratio of their charge (E) to their
mass (M). These results were obtained by passing such particles between thin,
matchbox-sized metal plates stacked closely together, each plate charged
oppositely to its neighbour in one experiment and in another experiment putting
the assembly in a strong magnetic field; in each experiment he measured the
strengths of the fields which just sufficed to prevent the particles from
emerging from the stack.
Rutherford wrote
80 scientific papers during his seven years at McGill, made many public
appearances, among them the Silliman Memorial
Lectures at Yale University in 1905, and received offers of chairs at other
universities. In 1907 he returned to England to accept a chair at the University
of Manchester, where he continued his research on the alpha particle. With the
ingenious apparatus that he and his research assistant, Hans
Geiger, had invented, they counted the particles as they were emitted one
by one from a known amount of radium; and they also measured the total charge
collected, from which the charge on each particle could be detected. Combining
this result with the rate of production of helium from radium, determined by
Rutherford and the American chemist Bertram Borden Boltwood,
Rutherford was able to deduce Avogadro's
number (the constant number of molecules in the molecular weight in grams
of any substance) in the most direct manner conceivable. With his student
Thomas D. Royds he proved in 1908 that the alpha
particle really is a helium atom, by allowing alpha particles to escape through
the thin glass wall of a containing vessel into an evacuated outer glass tube
and showing that the spectrum of the collected gas was that of helium. Almost
immediately, in 1908, came the Nobel Prize--but for chemistry, for his
investigations concerning the disintegration of elements.
In 1911
Rutherford made his greatest contribution to science with his nuclear theory of
the atom.
He had observed in Montreal that fast-moving alpha particles on passing through
thin plates of mica produced diffuse images on photographic plates, whereas a
sharp image was produced when there was no obstruction to the passage of the
rays. He considered that the particles must be deflected through small angles
as they passed close to atoms of the mica, but calculation showed that an
electric field of 100,000,000 volts per centimetre was necessary to deflect
such particles traveling at 20,000 kilometres per
second, a most astonishing conclusion. This phenomenon of scattering
was found in the counting experiments with Geiger; Rutherford suggested to
Geiger and a student, Ernest Marsden, that it would
be of interest to examine whether any particles were scattered backward--i.e.,
deflected through an angle of more than 90 degrees. To their astonishment, a
few particles in every 10,000 were indeed so scattered, emerging from the same
side of a gold foil as that on which they had entered. After a number of
calculations, Rutherford came to the conclusion that the intense electric field
required to cause such a large deflection could occur only if all the positive
charge in the atom, and therefore almost all the mass, were concentrated on a
very small central nucleus
some 10,000 times smaller in diameter than that of the entire atom. The
positive charge on the nucleus would therefore be balanced by an equal charge
on all the electrons distributed somehow around the nucleus. This theory of
atomic structure is known as the Rutherford
atomic model.
Although in 1904 Hantaro Nagaoka, a Japanese
physicist, had proposed an atomic model with electrons rotating in rings about a
central nucleus, it was not taken seriously, because, according to classical
electrodynamics, electrons in orbit would have a centripetal acceleration
toward the centre of rotation and would thus radiate away their energy, falling
into the central nucleus almost immediately. This idea is in marked contrast
with the view developed by J.J. Thomson in 1910; he envisaged all the electrons
distributed inside a uniformly charged positive sphere of atomic diameter, in
which the negative "corpuscles" (electrons) are imbedded. It was not
until 1913 that Niels Bohr, a Danish physicist, postulated that
electrons, contrary to classical electrodynamics, do not radiate energy during
rotation and do indeed move in orbits about a central nucleus, thus upholding
the convictions of Nagaoka and Rutherford. A
knighthood conferred in 1914 further marked the public recognition of
Rutherford's services to science.
Later
years
During World War I
he worked on the practical problem of submarine detection by underwater
acoustics. He produced the first artificial
disintegration of an element in 1919, when he found that on collision with
an alpha particle an atom of nitrogen was converted into an atom of oxygen and
an atom of hydrogen. The same year he succeeded Thomson as Cavendish professor.
Although his experimental contributions henceforth were not as numerous as in
earlier years, his influence on research students was enormous. In the second Bakerian lecture he gave to the Royal Society in 1920, he
speculated upon the existence of the neutron and of isotopes of hydrogen and
helium; three of them were eventually discovered by workers in the Cavendish
Laboratory.
His service as
president of the Royal Society (1925-30) and as chairman of the Academic
Assistance Council, which helped almost 1,000 university refugees from Germany,
increased the claims upon his time. But whenever possible he worked in the
Cavendish Laboratory, where he encouraged students, probed for the facts, and
always sought an explanation in simple terms. When in 1934 Enrico Fermi in Rome successfully disintegrated many
different elements with neutrons, Rutherford wrote to congratulate him
"for escaping from theoretical physics."
Rutherford read
widely and enjoyed good health, the game of golf, his home life, and hard work.
He could listen to the views of others, his judgments were fair, and from his
many students he earned affection and esteem. In 1931 he was made a peer, but
any gratification this honour may have brought was marred by the death of his
daughter. He died in Cambridge following a short illness and was buried in
Westminster Abbey.
Rutherford atomic model
description of the structure
of atoms proposed (1911) by the British physicist Ernest
Rutherford. The model described the atom as a tiny, dense,
positively charged core called a nucleus, in which nearly all the mass is
concentrated, around which the light, negative constituents, called electrons,
circulate at some distance, much like planets revolving around the Sun. The Rutherford
atomic model has been alternatively called the nuclear atom, or the planetary
model of the atom.
The nucleus was
postulated as small and dense to account for the scattering of alpha particles
from thin gold foil, as observed in a series of experiments performed under Rutherford's
direction in 1910-11 (see Figure
Figure: The Rutherford gold-foil
experiment; the inset accounts for the scattering of alpha particles...
). The diagram shows a simplified plan of his gold foil experiment.
A radioactive source capable of emitting alpha
particles (i.e., positively charged particles more than 7,000 times as
massive as electrons) was enclosed within a protective lead shield. The
radiation was focused into a narrow beam after passing through a slit in a lead
screen. A thin section of gold foil was placed in front of the slit, and a
screen coated with zinc sulfide to render it
fluorescent served as a counter to detect alpha particles. As each alpha
particle struck the fluorescent screen, it would produce a burst of light
called a scintillation, which was visible through a
viewing microscope attached to the back of the screen. The screen itself was
movable, allowing Rutherford and his associates to determine whether or
not any alpha particles were being deflected by the gold foil.
Most alpha
particles were observed to pass straight through the gold foil (see inset),
which implied that atoms are composed of large amounts of open space. Some
alpha particles were deflected slightly, suggesting interactions with other
positively charged particles within the atom. Still other alpha particles were
scattered at large angles, while a very few even bounced back toward the
source. Only a positively charged and relatively heavy target particle, such as
the proposed nucleus, could account for such strong repulsion. The negative
electrons that balanced electrically the positive nuclear charge were regarded
as traveling in circular orbits about the nucleus.
The electrostatic force of attraction between electrons and nucleus was likened
to the gravitational force of attraction between the revolving planets and the
Sun. Most of this planetary atom was open space and offered no resistance to
the passage of the alpha particles. The Rutherford model, based wholly
on classical physics, was superseded in a few years by the Bohr
atomic model, which incorporated some early quantum theory.
Bibliography
James Chadwick
(compiler), The Collected Papers of Lord Rutherford of Nelson, 3 vol.
(1962-65), is a useful resource. A.S. Eve, Rutherford (1939), is the
official biography sanctioned by Lady Rutherford. Further studies of his life
and work include E.N. da C. Andrade, Rutherford
and the Nature of the Atom (1964, reprinted 1978), a biographical treatment
that emphasizes the development of Rutherford's ideas; J.B. Birks
(ed.), Rutherford at Manchester (1962), a discussion of his work at the
university there; N. Feather, Lord Rutherford, new ed. (1973), a
discussion of his research work at Cambridge University; Mario Bunge and William R. Shea (eds.),
Rutherford and Physics at the Turn of the Century (1979), a discussion
of developments in physics between 1895 and 1905; Thaddeus J. Trenn, The Self-splitting Atom (1977), an account of
the Rutherford-Soddy collaboration; Lawrence Badash
(ed.), Rutherford and Boltwood (1969),
containing the correspondence between the two scientists concerning the
question of radioactivity; and David Wilson, Rutherford: Simple Genius
(1983), a full account incorporating much new material.