Plum pudding model explained

The plum pudding model was the first scientific model of the atom with internal structure. It was first proposed by J. J. Thomson in 1904 following his discovery of the electron in 1897, but it was subsequently rendered obsolete by Ernest Rutherford's discovery of the atomic nucleus in 1911. The model tried to account for two properties of atoms then known: that there are electrons and that atoms have no net electric charge. Logically there had to be an equal amount of positive charge to balance out the negative charge of the electrons. As he had no idea of the source of this positive charge, Thomson tentatively proposed that it was everywhere in the atom, the atom being in the shape of a sphere for the sake of mathematical simplicity. Following from this, Thomson imagined that the balance of electrostatic forces in the atom would distribute the electrons more or less evenly throughout this hypothetical sphere.[1]

Thomson attempted without success to develop a complete model that could predict other known properties of the atom, such as emission spectra and valencies. Based on experimental studies of alpha particle scattering, Ernest Rutherford developed an alternative model for the atom featuring a compact nuclear center. This model was taken up by Niels Bohr as the basis of the first quantum atom model.

Thomson's model is popularly referred to as the "plum pudding model" with the notion that the electrons are distributed uniformly, like raisins in a plum pudding. Neither Thomson nor his colleagues ever used this analogy.[2] It seems to have been conceived by popular science writers to make the model accessible to the layman. The analogy is perhaps misleading because Thomson likened the sphere to a liquid rather than a solid, since he thought the electrons moved around in it.[3]

Significance

Thomson's plum-pudding model of the atom is one of a series of atomic models ranging from the philosophical models of the ancient Greeks through John Dalton's chemistry-based atom to the modern quantum atom of atomic physics. Among these models, Thomson's can be considered the first modern model. Thomson's model is distinguished by being the first with internal structure; it was the best available model between 1904 and 1910.[2] Thomson's model introduced the idea that successive elements in the periodic table could be formed by additions of single electrons. His concentric rings of electrons introduced an idea that later became "core" and "valence" electrons. And his model was based on a model of mechanical stability.[4] Being based on experimentally studied subatomic "corpuscles", now known as electrons, Thomson's model was the first model to be subject to direct experimental tests.[5] By 1909 these tests began to reveal new ideas, and in 1911 Ernest Rutherford used experimental scattering data to propose a new atomic model.

Background

See main article: History of atomic theory. Throughout the 19th century evidence from chemistry and statistical mechanics accumulated that matter was composed of atoms. The structure of the atom was discussed, and by the end of the century the leading model was the vortex theory of the atom, proposed by William Thomson (later Lord Kelvin) in 1867.[6] By 1890, J.J. Thomson had his own version called the "nebular atom" hypothesis, in which atoms were composed of immaterial vortices and suggested similarities between the arrangement of vortices and periodic regularity found among the chemical elements.[7]

Thomson's discovery of the electron in 1897 changed his views. Thomson called them "corpuscles" (particles), but they were more commonly called "electrons", the name G. J. Stoney had coined for the "fundamental unit quantity of electricity" in 1891.[8] However even late in 1899, few scientists believed in subatomic particles.[9]

Another emerging scientific theme of the 19th century was the discovery and study of radioactivity. Thomson discovered the electron by studying cathode rays, and in 1900 Henri Becquerel determined that the highly penetrating radiation from uranium, now called beta decay beta particles, had the same charge/mass ratio as cathode rays.[9] These beta particles were believed to be electrons traveling at much high speeds. These beta particles would be used by Thomson to probe atoms to find evidence for his atomic theory. The other form of radiation critical to this era of atomic models was alpha particles. Heavier and slower than beta particles, these would be the key tool used by Rutherford to find evidence against Thomson's model.

In addition to the emerging atomic theory, the electron, and radiation, the last element of history was the many studies of atomic spectra published near the end of the 19th century. Part of the attraction of the vortex model was its possible role in describing the spectral data as vibrational responses to electromagnetic radiation. Neither Thomson's model nor its successor, Rutherford's model, made progress towards understanding atomic spectra. That would have to wait until Niels Bohr built the first quantum-based atom model.

Development

Thomson's model was the first to assign a specific inner structure to an atom, though his earliest descriptions did not include mathematical formulas.[2] From 1897 through 1913, Thomson proposed a series of increasingly detailed polyelectron models for the atom. His first versions were qualitative culminating in his 1906 paper and follow on summaries. Thomson's model changed over the course of its initial publication, finally becoming a model with much more mobility containing electrons revolving in the dense field of positive charge rather than a static structure. Thomson attempted unsuccessfully to reshape his model to account for some of the major spectral lines experimentally known for several elements.

1897 Corpuscles inside atoms

In a paper titled Cathode Rays, Thomson demonstrated that cathode rays are not light but made of negatively charged particles which he called corpuscles. He observed that cathode rays can be deflected by electric and magnetic fields, which does not happen with light rays. In a few paragraphs near the end of this long paper Thomson discusses the possibility that atoms were made of these corpuscles, calling them primordial atoms. Thomson believed that the intense electric field around the cathode caused the surrounding gas molecules to split up into their component corpuscles, thereby generating cathode rays. Thomson thus showed evidence that atoms were in fact divisible, though he did not attempt to describe their structure at this point.

Thomson notes that he was not the first scientist to propose that atoms are actually divisible, making reference to William Prout who in 1815 noted that the atomic weights of various elements were multiples of hydrogen's atomic weight and hypothesized that all atoms were hydrogen atoms fused together.[10] While Prout's hypothesis was dismissed by chemists when it was found by the 1830s that some elements seemed to have a non-integer atomic weight—e.g. chlorine has an atomic weight of about 35.45—the concept continued to have influence. Eventually the discrepancies would be explained with the discovery of isotopes and nuclear structure in the early 20th century.

A few months after Thomson's paper appeared, George FitzGerald suggested that the corpuscle identified by Thomson from cathode rays and proposed as parts of an atom was a "free electron", as described by physicist Joseph Larmor and Hendrik Lorentz. While Thomson did not adopt the terminology, the connection convinced other scientists that cathode rays were particles, an important step in their eventual acceptance of an atomic model based on sub-atomic particles.[11]

In 1899, reiterated his atomic model in a paper that showed that negative electricity created by ultraviolet light landing on a metal (known now as the photoelectric effect) has the same mass-to-charge ratio as cathode rays; then he applied his previous method for determining the charge on ions to the negative electric particles created by ultraviolet light.[12] By this combination he estimated that the electron's mass was 0.0014 times that of the hydrogen ion (as a fraction:).[13] In the conclusion of this paper he writes:[10]

1904 Mechanical model of the atom

Thomson provided his first detailed description of the atom in his 1904 paper On the Structure of the Atom.Thomson starts with a short description of his model

... the atoms of the elements consist of a number of negatively electrified corpuscles enclosed in a sphere of uniform positive electrification, ...
Primarily focused on the corpuscles, Thomson adopted the positive sphere from Kelvin's atom model proposed a year earlier.[14] [15] He then gives a detailed mechanical analysis of such a system, distributing the corpuscles uniformly around a ring. The attraction of the positive electrification is balanced by the mutual repulsion of the corpuscles. His analysis focuses on stability, looking for cases were small changes in position are countered by restoring forces.

After discussing his many formulae for stability he turned to analyzing patterns in the number of electrons in various concentric rings of stable configurations. These regular patterns Thomson argued are analogous to the periodic law of chemistry behind the struture of the periodic table. This concept, that a model based subatomic particles could account for chemical trends, encouraged interest in Thomson's model and influenced future work even if the details Thomson's electron assignments turned out to be incorrect.[16]

Thomson believed that all the mass of the atom was carried by the electrons.[17] This would mean that even a small atom would have to contain thousands of electrons, and the positive electrification the encapsulated them was without mass.[18]

In a lecture delivered to the Royal Institution of Great Britain in 1905,[19] Thomson reviewed his 1904 paper and demonstrated[12] some of its concepts with a practical experiment invented by Alfred M. Mayer in 1878.[20] The demonstration involved magnetized pins pushed into cork disks and set afloat in a basin of water. The magnetized pins were oriented such that they repelled each other. Above the center of the basin was suspended an electromagnet that attracted the pins towards the center. The equilibrium arrangement the pins took informed Thomson on what arrangements the electrons in an atom might take and he provided a brief table.

For instance, he observed that while five pins would arrange themselves in a stable pentagon around the center, six pins could not form a stable hexagon. Instead, one pin would move to the center and the other five would form a pentagon around the center pin, and this arrangement was stable. As he added more pins, they would arrange themselves in concentric rings around the center.

From this, Thomson believed the electrons arranged themselves in concentric shells, and the electrons could move about within these shells but did not move out of them unless electrons were added or subtracted from the atom.

1906 Estimating electrons per atom

Before 1906 Thomson considered the atomic weight to be due to the mass of the electrons (which he continued to call "corpuscles"). Based on his own estimates of the electron mass, an atom would need tens of thousands electrons to account for the mass. In 1906 he used three different methods, X-ray scattering, beta ray absorption, or optical properties of gases, to estimate that "number of corpuscles is not greatly different from the atomic weight".[21] [22] This reduced the number of electrons to tens or at most a couple of hundred and it required that the positive sphere in Thomson's atom model contain most of the mass of the atom. This in turn meant that Thomson's mechanical stability work from 1904 and the comparison to the periodic table were no longer valid. Moreover the alpha particle, so important to the next advance in atomic theory by Rutherford, would no longer be viewed as an atom containing thousands of electrons.[22]

In 1907, Thomson published The Corpuscular Theory of Matter which reviewed his ideas on the atom's structure and proposed further avenues of research.

In Chapter 6, he further elaborates his experiment using magnetized pins in water, providing an expanded table. For instance, if 59 pins were placed in the pool, they would arrange themselves in concentric rings of the order 20-16-13-8-2 (from outermost to innermost).

In Chapter 7, Thomson summarized his 1906 results on the number of electrons in an atom. He included one important correction: he replaced the beta-particle analysis with one based on the cathode ray experiments of August Becker, giving a result in better agreement with other approaches to the problem.[22] Experiments by other scientists in this field had shown that atoms contain far fewer electrons than Thomson previously thought. Thomson now believed the number of electrons in an atom was a small multiple of its atomic weight: "the number of corpuscles in an atom of any element is proportional to the atomic weight of the element — it is a multiple, and not a large one, of the atomic weight of the element."

This would mean that almost all of the atom's mass was carried by the positive sphere. In this book he now estimates that a hydrogen atom is 1,700 times heavier than an electron (the current measurement is 1,837).[23] Thomson still did not know what substance constituted the positive electrification, though he noted that no scientist had yet found a positively-charged particle smaller than a hydrogen ion.

1910 Multiple scattering

Thomson's difficulty with beta scattering in 1906 lead him to renewed interest in the topic. He encouraged J. Arnold Crowther to experiment with beta scattering through thin foils[24] and, in 1910, Thomson produced a new theory of beta scattering.[25] The two innovations in this paper was the introduction of scattering from the positive sphere of the atom and analysis that multiple or compound scattering was critical to the final results.[22] This theory and Crowther's experimental results would be confronted by Rutherford's theory and Geiger and Mardsen new experiments with alpha particles.

Inconsistency of the plum pudding model

Rutherford's new evidence

See main article: Rutherford scattering experiments. Between 1908 and 1913, Ernest Rutherford, Hans Geiger, and Ernest Marsden collaborated on a series of experiments in which they bombarded metal foils with a beam of alpha particles and measured the intensity versus scattering angle of the particles. Gold was their preferred material because gold is very malleable and can therefore be made into an especially thin foil. They found that the gold foil could scatter alpha particles by more than 90 degrees.[26] This should not have been possible according to the Thomson model: the scattering into large angles should have been negligible. The positive charge in the Thomson model is too diffuse to produce an electric field of sufficient strength to cause such scattering and the electrons are too light to alter the course of the alpha particle. Rutherford deduced that the positive charge of the atom, along with most of the atom's mass, was concentrated in a tiny nucleus at the center of the atom. Only such an intense concentration of charge and mass, could have scattered the alpha particle beam so dramatically.

How scattering should work according to the Thomson model

In a 1910 paper, Thomson presented equations that modeled how beta particles scatter in a collision with an atom.[27] [22] On average the positive sphere and the electrons alike provide very little deflection in a single collision.Thomson's model combined many single-scattering events from the atom's electrons and a positive sphere. Each collision may increase or decrease the total scattering angle. Only very rarely would a series of collisions all line up in the same direction. The result is similar to the standard statistical problem called a random walk. If the average deflection angle of the alpha particle in a single collision with an atom is

\bar{\theta}

, then the average deflection after n collisions is

\bar\theta_n = \bar\sqrt

This correction gets applied twice, once for the individual electron collisions inside the atom, and again for the case of multiple atom collisions.

The average deflection caused by the atom's electrons was calculated by matching a hyperbolic orbit to the collision geometry and then multiplied by a factor proportional to

\sqrt{N}

for encounters with

N

electrons:[22]

\bar\theta_2 = \frac \cdot \frac \cdot \frac \cdot \sqrt \approx 0.00007 \text 0.004 \textwhere

The average angle by which an alpha particle should be deflected by the positive sphere of the atom was simply given by Thomson as:

\bar\theta_1 = \frac \cdot \frac \cdot \frac \approx 0.00013 \text

Analysis of Rutherford's notes on Thomson's work suggests this formula is a result of averaging the deflections of a beta particle crossing the sphere, assuming a straight trajectory suitable for a small deflection.[22]

The net deflection for each atom combines the two contributions:

\bar\theta = \sqrt \approx 0.008 \text

and after

n

collisons

\bar\thetan=0.008\sqrt{n}degrees

.

In a 1911 paper, Rutherford developed similar equations for alpha particle scattering and showed that they did not agree with experimental results of Geiger and Marsden when applied to Thomson's atom model.[28] The critical issue was large angle scattering. A gold foil like the one Geiger and Marsden experimented with would be around 10,000 atoms thick.The probability that an alpha particle will be deflected by a total of more than 90° after n deflections is given by:

e^

where e is Euler's number (≈2.71828...). Assuming an average deflection per collision of 0.008°, and therefore an average deflection of 0.8° after 10,000 collisions, the probability of an alpha particle being deflected by more than 90° will be[29]

e^ \approx e^ \approx 10^

While in Thomson's "plum pudding" model it is possible that an alpha particle could be deflected by more than 90° after 10,000 collisions, the probability of such an event is so low as to be undetectable. This extremely small number shows that Thomson's model of 1906 cannot explain the results of the Geiger-Mardsen experiment of 1909.

When Thomson initially proposed the plum pudding model, he believed that all the mass of an atom was carried by its electrons. This would mean that even small atoms would have to contain thousands of electrons. The atomic weight of gold is 197 and an electron is 1,837 times smaller than a hydrogen atom, which means that a gold atom would have to contain 361,889 electrons. An alpha particle passing through a gold foil 10,000 atoms thick would probably experience millions of collisions before emerging, which per the equations above would produce a high probability of a net deflection in excess of 90°. But in 1906, after studying the effects of beta ray scattering, Thomson concluded that the number of electrons in atom was a small multiple of its atomic weight, so a gold atom would perhaps have 200 to 300 electrons. In this case a gold foil could not present enough collisions to produce a large deflection.

Deflection by the positive sphere

In Thomson's model of scattering the average angle by which an alpha particle should be deflected by the positive sphere of the atom is[27] [22]

\bar\theta_1 = \frac \cdot \frac

Neither Thomson nor Rutherford explain how this equation was developed, but here an educated guess is made.[30]

In 1906, Thomson provided an equation which models how a beta particle should be deflected by an atomic electron in a close encounter:[31]

\tan= \frac

Thomson probably arrived at this equation using hyperbolic geometry because Rutherford used hyperbolic geometry to produce a related equation in his 1911 paper[32] (a full explanation is available in the article on the Rutherford scattering experiments). The factor

m'

, the reduced mass equal to

\tfrac{m1m2}{m1+m2}

where m1 and m2 are the masses of the two colliding particles, enters the model when the two-body coordinates are written as the equivalent one-body problem.[33] qe is the elementary charge and b is the impact parameter.

An alpha particle passing by the positive sphere with a radius R equal to that of a gold atom, just close enough to graze its edge, will experience the sphere's electric field at its strongest.[29] This occurs for an impact parameter b equal to the radius R as shown here:

Using Thomson's equation from above to model this collision gives:

\theta_1= 2\arctan \left (\frac \right) \approx 0.02 \text

Unlike Thomson's electron-electron collision, no correction for recoil is needed here because the gold atom is nearly 20 times as heavy as the alpha particle. The equation shows that the maximum deflection caused by the positive sphere will be very small. But what of the average deflection

\bar\theta1

over all possible values of b?

Consider an alpha particle passing through the positive sphere of a gold atom, with its initial trajectory at a lateral distance b from the center.

Inside a sphere of uniformly distributed positive charge the force exerted on the alpha particle at any point along its path through the sphere is[34] [29]

F = \frac \cdot \frac

The lateral component of this force is

F_y = \frac \cdot \frac \cdot \cos\varphi = \frac \cdot b

The lateral change in momentum py is therefore

\Delta p_y = F_y t =\frac \cdot b \cdot \frac

The deflection angle

\theta1

is given by

\tan\theta_1 = \frac = \frac \cdot b \cdot 2L \cdot \frac

where px is the average horizontal momentum, which is first reduced then restored as horizontal force switches direction as the alpha particle goes across the sphere. Since we already know the deflection is very small, we can treat

\tan\theta1

as being equal to

\theta1

.

To find the average deflection angle

\bar\theta1

, we must average b and L across the entire sphere:

\bar\theta_1 = \frac \int_0^R \frac \cdot b \cdot 2\sqrt \cdot \frac \cdot 2\pi b \cdot \mathrmb

= \frac \cdot \frac

This matches Thomson's formula in his 1910 paper.

Contemporary reactions

Rutherford's 1911 paper on alpha particle scattering contained largely the same points as described above and yet in the years immediate following its publication few scientists took note.[12] The scattering model predictions were not considered definitive evidence against Thomson's plum pudding model. Thomson and Rutherford had pioneered scattering as a technique to probe atoms, its reliability and value were unproven. Before Rutherford's paper the alpha particle was considered an atom, not a compact mass. It was not clear why it should be a good probe. Rutherford's paper did not discuss the atomic electrons vital to practical problems like chemistry or atomic spectroscopy.[22] Rutherford's nuclear model would only become widely accepted after the work of Niels Bohr.

Mathematical Thomson problem

The Thomson problem in mathematics seeks the optimal distribution of equal point charges on the surface of a sphere; it is a generalization of the plum pudding model in the absence of its uniform positive background charge.[35] [36]

Origin of the nickname

The first known writer to compare Thomson's model to a plum pudding, a British dessert with whole raisins, was an anonymous reporter who wrote an article for the British pharmaceutical magazine The Chemist and Druggist in August 1906.

The analogy was never used by Thomson nor his colleagues. It seems to have been a conceit of popular science writers to make the model easier to understand for the layman.[2]

Bibliography

Notes and References

  1. "In default of exact knowledge of the nature of the way in which positive electricity occurs in the atom, we shall consider a case in which the positive electricity is distributed in the way most amenable to mathematical calculation, i.e., when it occurs as a sphere of uniform density, throughout which the corpuscles are distributed."
  2. Hon . Giora . Goldstein . Bernard R. . 6 September 2013 . J. J. Thomson's plum-pudding atomic model: The making of a scientific myth . Annalen der Physik . 525 . 8–9 . A129–A133 . 2013AnP...525A.129H . 10.1002/andp.201300732.
  3. Letter from J. J. Thomson to Oliver Lodge dated 11 April 1904, quoted in :
    "With regard to positive electrification I have been in the habit of using the crude analogy of a liquid with a certain amount of cohesion, enough to keep it from flying to bits under its own repulsion. I have however always tried to keep the physical conception of the positive electricity in the background because I have always had hopes (not yet realised) of being able to do without positive electrification as a separate entity and to replace it by some property of the corpuscles."
  4. Heilbron . John L. . 1977-04-01 . J. J. Thomson and the Bohr atom . Physics Today . en . 30 . 4 . 23–30 . 10.1063/1.3037496 . 0031-9228.
  5. Kragh, H. (2012). Niels Bohr and the Quantum Atom: The Bohr Model of Atomic Structure 1913-1925. United Kingdom: OUP Oxford.
  6. Thomson . William . 1869 . On Vortex Atoms . . 6 . 94–105 . 10.1017/S0370164600045430.
  7. Book: Kragh, Helge . Quantum Generations: A History of Physics in the Twentieth Century . 2002 . . 978-0691095523 . Reprint . 43–45.
  8. O'Hara . J. G. . March 1975 . George Johnstone Stoney, F.R.S., and the Concept of the Electron . . 29 . 2 . 265–276 . 10.1098/rsnr.1975.0018 . 531468 . 145353314.
  9. Book: Whittaker, E. T. . A history of the theories of aether & electricity . 1989 . Dover Publications . 978-0-486-26126-3 . New York.
  10. Helge Kragh (Oct. 2010). Before Bohr: Theories of atomic structure 1850-1913. RePoSS: Research Publications on Science Studies 10. Aarhus: Centre for Science Studies, University of Aarhus.
  11. Falconer . Isobel . July 1987 . Corpuscles, Electrons and Cathode Rays: J.J. Thomson and the 'Discovery of the Electron' . The British Journal for the History of Science . en . 20 . 3 . 241–276 . 10.1017/S0007087400023955 . 0007-0874.
  12. Book: Pais, Abraham . Inward bound: of matter and forces in the physical world . 2002 . Clarendon Press [u.a.] . 978-0-19-851997-3 . Reprint . Oxford.
  13. J. J. Thomson . 1899 . On the Masses of the Ions in Gases at Low Pressures. . Philosophical Magazine . 5 . 48 . 547–567 . 295.
    "...the magnitude of this negative charge is about 6 × 10-10 electrostatic units, and is equal to the positive charge carried by the hydrogen atom in the electrolysis of solutions. [...] In gases at low pressures these units of negative electric charge are always associated with carriers of a definite mass. This mass is exceedingly small, being only about 1.4 × 10-3 of that of the hydrogen ion, the smallest mass hitherto recognized as capable of a separate existence. The production of negative electrification thus involves the splitting up of an atom, as from a collection of atoms something is detached whose mass is less than that of a single atom."
  14. Web site: Models of the Atom . Michael . Fowler . University of Virginia .
  15. Book: Kumar, Manjit . Quantum Einstein, Bohr and the Great Debate . 978-0393339888 . 2008.
  16. Kragh . Helge . 2001 . The first subatomic explanations of the periodic system . Foundations of Chemistry . 3 . 2 . 129–143 . 10.1023/A:1011448410646.
  17. "We suppose that the mass of an atom is the sum of the masses of the corpuscles it contains, so that the atomic weight of an element is measured by the number of corpuscles in its atom."

  18. Baily . C. . January 2013 . Early atomic models – from mechanical to quantum (1904–1913) . The European Physical Journal H . en . 38 . 1 . 1–38 . 10.1140/epjh/e2012-30009-7 . 2102-6459.
  19. . Reprinted in
  20. Snelders . H.A.M. . 1976 . A. M. Mayer's experiments with floating magnets and their use in the atomic theories of matter . Annals of Science . en . 33 . 1 . 67–80 . 10.1080/00033797600200141 . 0003-3790.
  21. Thomson . J.J. . June 1906 . LXX. On the number of corpuscles in an atom . The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science . en . 11 . 66 . 769–781 . 10.1080/14786440609463496 . 1941-5982.
  22. Heilbron . John L. . 1968 . The Scattering of α and β Particles and Rutherford's Atom . Archive for History of Exact Sciences . 4 . 4 . 247–307 . 10.1007/BF00411591 . 41133273 . 0003-9519.
  23. "Since the mass of a corpuscle is only about one-seventeen-hundredth part of that of an atom of hydrogen, it follows that if there are only a few corpuscles in the hydrogen atom the mass of the atom must in the main be due to its other constituent — the positive electricity."

  24. 1910-09-15 . On the scattering of Homogeneous β-Rays and the number of Electrons in the Atom . Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character . en . 84 . 570 . 226–247 . 10.1098/rspa.1910.0074 . 0950-1207. free .
  25. Thomson, Joseph J. "On the scattering of rapidly moving electrified particles". Cambridge Philosophical Society, 1910.
  26. Book: Belyaev, Alexander . The Basics of Nuclear and Particle Physics . Ross . Douglas . 2021 . Springer International Publishing . 978-3-030-80115-1 . Undergraduate Texts in Physics . Cham . en . 10.1007/978-3-030-80116-8.
  27. J. J. Thomson . 1910 . On the Scattering of rapidly moving Electrified Particles . Proceedings of the Cambridge Philosophical Society . 15 . 465-471 .
  28. Rutherford (1911). p. 677
  29. Beiser (1969). Perspectives of Modern Physics, p. 109
  30. Heilbron (1968). p. 278
  31. Heilbron (1968). p. 270
  32. Ernest Rutherford . 1911 . The Scattering of α and β Particles by Matter and the Structure of the Atom . . Series 6 . 21 . 125. 669–688 . 10.1080/14786440508637080 . refRutherford1911.
  33. Goldstein, Herbert. Classical Mechanics. United States, Addison-Wesley, 1950.
  34. http://hyperphysics.phy-astr.gsu.edu/hbase/electric/elesph.html
  35. Levin . Y. . Arenzon . J. J. . 2003 . Why charges go to the Surface: A generalized Thomson Problem . Europhys. Lett. . 63 . 3 . 415–418 . cond-mat/0302524 . 2003EL.....63..415L . 10.1209/epl/i2003-00546-1 . 250764497.
  36. Roth . J. . 2007-10-24 . Description of a highly symmetric polytope observed in Thomson's problem of charges on a hypersphere . Physical Review E . en . 76 . 4 . 047702 . 2007PhRvE..76d7702R . 10.1103/PhysRevE.76.047702 . 1539-3755 . 17995142 . Although Thomson's model has been outdated for a long time by quantum mechanics, his problem of placing charges on a sphere is still noteworthy..