Ernest Rutherford | Accomplishments, Atomic Theory, & Facts | Britannica

Ernest Rutherford

British physicist
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Also known as: Lord Rutherford
Quick Facts
In full:
Ernest, Baron Rutherford of Nelson
Born:
August 30, 1871, Spring Grove, New Zealand
Died:
October 19, 1937, Cambridge, Cambridgeshire, England (aged 66)
Awards And Honors:
Copley Medal (1922)
Nobel Prize (1908)
Subjects Of Study:
Rutherford model
atom
radioactivity
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Ernest Rutherford (born August 30, 1871, Spring Grove, New Zealand—died October 19, 1937, Cambridge, Cambridgeshire, England) was a New Zealand-born British physicist considered the greatest experimentalist since Michael Faraday (1791–1867). Rutherford was the central figure in the study of radioactivity, and with his concept of the nuclear atom he led the exploration of nuclear physics. He won the Nobel Prize for Chemistry in 1908, was president of the Royal Society (1925–30) and the British Association for the Advancement of Science (1923), was conferred the Order of Merit in 1925, and was raised to the peerage as Lord Rutherford of Nelson in 1931.

Early life and education

Rutherford’s father, James Rutherford, moved from Scotland to New Zealand as a child in the mid-19th century and farmed in that agrarian society, which had only recently been settled by Europeans. Rutherford’s mother, Martha Thompson, came from England, also as a youngster, and worked as a schoolteacher before marrying and raising a dozen children, of whom Ernest was the fourth child and second son.

Ernest Rutherford attended the free state schools through 1886, when he won a scholarship to attend Nelson Collegiate School, a private secondary school. He excelled in nearly every subject, but especially in mathematics and science.

Another scholarship took Rutherford in 1890 to Canterbury College in Christchurch, one of the four campuses of the University of New Zealand. It was a small school, with a faculty of eight and fewer than 300 students. Rutherford was fortunate to have excellent professors, who ignited in him a fascination for scientific investigation tempered with the need for solid proof.

Italian-born physicist Dr. Enrico Fermi draws a diagram at a blackboard with mathematical equations. circa 1950.
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On conclusion of the school’s three-year course, Rutherford received a bachelor of arts (B.A.) degree and won a scholarship for a postgraduate year of study at Canterbury. He completed this at the end of 1893, earning a master of arts (M.A.) degree with first-class honours in physical science, mathematics, and mathematical physics. He was encouraged to remain yet another year in Christchurch to conduct independent research. Rutherford’s investigation of the ability of a high-frequency electrical discharge, such as that from a capacitor, to magnetize iron earned him a bachelor of science (B.S.) degree at the end of 1894. During this period he fell in love with Mary Newton, the daughter of the woman in whose house he boarded. They married in 1900.

In 1895 Rutherford won a scholarship that had been created with profits from the famous Great Exhibition of 1851 in London. He chose to continue his study at the Cavendish Laboratory of the University of Cambridge, which J.J. Thomson, Europe’s leading expert on electromagnetic radiation, had taken over in 1884.

University of Cambridge

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In recognition of the increasing importance of science, the University of Cambridge had recently changed its rules to allow graduates of other institutions to earn a Cambridge degree after two years of study and completion of an acceptable research project. Rutherford became the school’s first research student. Besides showing that an oscillatory discharge would magnetize iron, which happened already to be known, Rutherford determined that a magnetized needle lost some of its magnetization in a magnetic field produced by an alternating current. This made the needle a detector of electromagnetic waves, a phenomenon that had only recently been discovered. In 1864 the Scottish physicist James Clerk Maxwell had predicted the existence of such waves, and between 1885 and 1889 the German physicist Heinrich Hertz had detected them in experiments in his laboratory. Rutherford’s apparatus for detecting electromagnetic waves, or radio waves, was simpler and had commercial potential. He spent the next year in the Cavendish Laboratory increasing the range and sensitivity of his device, which could receive signals from half a mile away. However, Rutherford lacked the intercontinental vision and entrepreneurial skills of the Italian inventor Guglielmo Marconi, who invented the wireless telegraph in 1896.

X-rays were discovered in Germany by physicist Wilhelm Conrad Röntgen only a few months after Rutherford arrived at the Cavendish. For their ability to take silhouette photographs of the bones in a living hand, X-rays were fascinating to scientists and laypeople alike. In particular, scientists wished to learn their properties and what they were. Rutherford could not decline the honour of Thomson’s invitation to collaborate on an investigation of the way in which X-rays changed the conductivity of gases. This yielded a classic paper on ionization—the breaking of atoms or molecules into positive and negative parts (ions)—and the charged particles’ attraction to electrodes of the opposite polarity.

Thomson then studied the charge-to-mass ratio of the most common ion, which later was called the electron, while Rutherford pursued other radiations that produced ions. Rutherford first looked at ultraviolet radiation and then at radiation emitted by uranium. (Uranium radiation was first detected in 1896 by the French physicist Henri Becquerel.) Placement of uranium near thin foils revealed to Rutherford that the radiation was more complex than previously thought: one type was easily absorbed or blocked by a very thin foil, but another type often penetrated the same thin foils. He named these radiation types alpha and beta, respectively, for simplicity. (It was later determined that the alpha particle is the same as the nucleus of an ordinary helium atom—consisting of two protons and two neutrons—and the beta particle is the same as an electron or its positive version, a positron.) For the next several years these radiations were of primary interest; later the radioactive elements, or radioelements, which were emitting radiation, enjoyed most of the scientific attention.