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Atomic theory

January 19, 2024

"Atomic model" redirects here. For the unrelated term in mathematical logic, see atomic model (mathematical logic).
This article is about the historical development of understanding the existence and behavior of atoms. For a history of the study of how atoms combine to form molecules, see history of molecular theory. For the modern view of the atom which developed from atomic theory, see atomic physics.

Atomic theory is the scientific theory that matter is composed of particles called atoms. The concept that matter is composed of discrete particles is an ancient idea, but gained scientific credence in the 18th and 19th centuries when scientists found it could explain the behaviors of gases and how chemical elements reacted with each other. By the end of the 19th century, atomic theory had gained widespread acceptance in the scientific community.

The current theoretical model of the atom involves a dense nucleus surrounded by a probabilistic "cloud" of electrons

The term "atom" comes from the Greek word atomos, which means "uncuttable". John Dalton applied the term to the basic units of mass of the chemical elements under the mistaken belief that chemical atoms are the fundamental particles in nature; it was another century before scientists realized that Dalton's so-called atoms have an underlying structure of their own. Particles which are truly indivisible are now referred to as "elementary particles".

History

Philosophical atomism

Main article: Atomism
See also: Prima materia

The basic idea that matter is made up of tiny indivisible particles is an old idea that appeared in many ancient cultures. The word atom is derived from the ancient Greek word atomos,[a] which means "uncuttable". This ancient idea was based in philosophical reasoning rather than scientific reasoning. Modern atomic theory is not based on these old concepts.[1][2] In the early 19th century, the scientist John Dalton noticed that chemical elements seemed to combine with each other by discrete units of weight, and he decided to use the word "atom" to refer to these units, as he thought these were the fundamental units of matter.[3] About a century later it was discovered that Dalton's atoms are not actually indivisible, but the term stuck.

Dalton's law of multiple proportions

 
From A New System of Chemical Philosophy, 1808.

Near the end of the 18th century, two laws about chemical reactions emerged without referring to the notion of an atomic theory. The first was the law of conservation of mass, closely associated with the work of Antoine Lavoisier, which states that the total mass in a chemical reaction remains constant (that is, the reactants have the same mass as the products).[4] The second was the law of definite proportions. First established by the French chemist Joseph Proust in 1797 this law states that if a compound is broken down into its constituent chemical elements, then the masses of the constituents will always have the same proportions by weight, regardless of the quantity or source of the original substance.[5]

John Dalton studied data gathered by himself and other scientists and noticed a pattern that later came to be known as the law of multiple proportions. In compounds which all contain a particular element, the content of that element will differ across these compounds by ratios of small whole numbers. Dalton concluded from all this that elements react with each other in discrete and consistent units of weight. Borrowing the word from the philosophical tradition, Dalton called these units atoms.

Example 1 — tin oxides: There are two types of tin oxide: one is a grey powder that is 88.1% tin and 11.9% oxygen, and the other is a white powder that is 78.7% tin and 21.3% oxygen. Adjusting these figures, in the grey powder there is about 13.5 g of oxygen for every 100 g of tin, and in the white powder there is about 27 g of oxygen for every 100 g of tin. 13.5 and 27 form a ratio of 1:2. Dalton concluded that in these oxides, for every tin atom there are one or two oxygen atoms respectively (SnO and SnO2).[6][7]

Example 2 — iron oxides: Dalton identified two oxides of iron. There is one type of iron oxide that is a black powder which is 78.1% iron and 21.9% oxygen; and there is another iron oxide that is a red powder which is 70.4% iron and 29.6% oxygen. Adjusting these figures, in the black powder there is about 28 g of oxygen for every 100 g of iron, and in the red powder there is about 42 g of oxygen for every 100 g of iron. 28 and 42 form a ratio of 2:3. Dalton concluded that in these oxides, for every two atoms of iron, there are two or three atoms of oxygen respectively (Fe2O2 and Fe2O3).[b][8][9]

Example 3 — nitrogen oxides: Dalton was aware of three oxides of nitrogen: "nitrous oxide", "nitrous gas", and "nitric acid".[10] These compounds are known today as nitrous oxide, nitric oxide, and nitrogen dioxide respectively. "Nitrous oxide" is 63.3% nitrogen and 36.7% oxygen, which means it has 80 g of oxygen for every 140 g of nitrogen. "Nitrous gas" is 44.05% nitrogen and 55.95% oxygen, which means there are 160 g of oxygen for every 140 g of nitrogen. "Nitric acid" is 29.5% nitrogen and 70.5% oxygen, which means it has 320 g of oxygen for every 140 g of nitrogen. 80 g, 160 g, and 320 g form a ratio of 1:2:4. The formulas for these compounds are N2O, NO, and NO2.[11][12]

Dalton's atomic theory

From the evidence provided by the law of multiple proportions Dalton developed his atomic theory. A central problem for the theory was to determine the relative weights of the atoms of various elements. The atomic weight of an element is the weight an atom of that element is compared to the weights of atoms of the other elements. Dalton and his contemporaries could not measure the absolute weight of atoms—i.e. their weight in grams—because atoms were far too small to be directly measured with the technologies that existed in the 19th century. Instead, they measured how heavy atoms of various elements were relative to atoms of hydrogen, which chemists of Dalton's day knew was the lightest element in nature.

Dalton estimated the atomic weights according to the mass ratios in which they combined, with the weight of the hydrogen atom taken conventionally as unity. However, Dalton did not realize that some elements exist as molecules in their natural pure form—-e.g. pure oxygen exists as O2. He also mistakenly believed that the simplest compound between any two elements is always one atom of each (so he thought water was HO, not H2O).[13] This, in addition to the limitations of his apparatus, flawed his results. For instance, in 1803 he believed that oxygen atoms were 5.5 times heavier than hydrogen atoms, because in water he measured 5.5 grams of oxygen for every 1 gram of hydrogen and believed the formula for water was HO. Adopting better data, in 1806 he concluded that the atomic weight of oxygen must actually be 7 rather than 5.5, and he retained this weight for the rest of his life. Others at this time had already concluded from more precise measurements that the oxygen atom must weigh 8 relative to hydrogen equals 1, if one assumes Dalton's formula for the water molecule (HO), or 16 if one assumes the modern water formula (H2O).[14]

The flaw in Dalton's theory was corrected in principle in 1811 by Amedeo Avogadro. Avogadro had proposed that equal volumes of any two gases, at equal temperature and pressure, contain equal numbers of molecules (in other words, the mass of a gas's particles does not affect the volume that it occupies).[15] Avogadro's hypothesis, now usually called Avogadro's law, provided a method for deducing the relative weights of the molecules of gaseous elements, for if the hypothesis is correct relative gas densities directly indicate the relative weights of the particles that compose the gases. This way of thinking led directly to a second hypothesis: the particles of certain elemental gases were not atoms, but molecules consisting of two atoms each; and when combining chemically these molecules often split in two. For instance, the fact that two liters of hydrogen will react with just one liter of oxygen to produce two liters of water vapor (at constant pressure and temperature) suggested that a single oxygen molecule must split in two in order to form two molecules of water. This also meant that the water molecule must be H2O. Thus, Avogadro was able to offer more accurate estimates of the atomic mass of oxygen and various other elements, and made a distinction between molecules and atoms. What we now call atoms Avogadro called "elementary molecules", and what we now call molecules Avogadro called "compound molecules".[16]

Opposition to atomic theory

Dalton's atomic theory was not immediately accepted by all scientists.

One problem was the lack of uniform nomenclature. The word "atom" implied indivisibility, but Dalton instead defined an atom as being the basic particle of any substance, which meant that "compound atoms" such as carbon dioxide could divided, as opposed to "elementary atoms".[17] Other scientists used their own nomenclature, which only added to the general confusion. For instance, J. J. Berzelius used the term "organic atoms" to refer to particles containing three or more elements, because he thought this only existed in organic compounds.[18]

A second problem was philosophical. Scientists in the 19th century had no way of directly observing atoms. They inferred the existence of atoms through indirect observations, such as Dalton's law of multiple proportions. Some Scientists, notably those who ascribed to the school of positivism, argued that scientists should not attempt to deduce the deeper reality of the universe, but only systemize what patterns they can directly observe. The anti-atomists argued that while atoms might be a useful abstraction for predicting how elements react, they do not reflect concrete reality.

Such scientists were sometimes known as "equivalentists", because they preferred the theory of equivalent weights, which is a generalization of Proust's law of definite proportions. For example, 1 gram of hydrogen will combine with 8 grams of oxygen to form 9 grams of water, therefore the equivalent weight of oxygen is 8 grams. This position was eventually quashed by two important advancements that happened later in the 19th century: the development of the periodic table and the discovery that molecules have an internal architecture that determines their properties.[19]

Dalton's law of multiple proportions was also shown to not be a universal law when it came to organic substances. For instance, in oleic acid there is 34 g of hydrogen for every 216 g of carbon, and in methane there is 72 g of hydrogen for every 216 g of carbon. 34 and 72 form a ratio of 17:36, which is not a ratio of small whole numbers. We know now that carbon-based substances can have very large molecules, larger than any the other elements can form. Oleic acid's formula is C18H34O2 and methane's is CH4.[20]

Isomerism

Scientists discovered some substances have the exact same chemical content but different properties. For instance, in 1827, Friedrich Wöhler discovered that silver fulminate and silver cyanate are both 107 parts silver, 12 parts carbon, 14 parts nitrogen, and 12 parts oxygen (we now know their formulas as both AgCNO). In 1830 Jöns Jacob Berzelius introduced the term isomerism to describe the phenomenon. In 1860, Louis Pasteur hypothesized that the molecules of isomers might have the same set of atoms but in different arrangements.[21]

In 1874, Jacobus Henricus van 't Hoff proposed that the carbon atom bonds to other atoms in a tetrahedral arrangement. Working from this, he explained the structures of organic molecules in such a way that he could predict how many isomers a compound could have. Consider, for example, pentane (C5H12). In van 't Hoff's way of modelling molecules, there are three possible configurations for pentane, and scientists did go on to discover three and only three isomers of pentane.[22][23]

 
n-pentane
 
isopentane
 
neopentane
Jacobus Henricus van 't Hoff's way of modelling molecular structures correctly predicted three possible isomers for pentane (C5H12).

Isomerism was not something that could be fully explained by alternative theories to atomic theory, such as radical theory and the theory of types.[24][25]

Mendeleev's periodic table

Main article: Periodic table

Dmitrii Mendeleev noticed that when he arranged the elements in a row according to their atomic weights, there was a certain periodicity to them.[26]: 117  For instance, the second element, lithium, had similar properties to the ninth element, sodium, and the sixteenth element, potassium — a period of seven. Likewise, beryllium, magnesium, and calcium were similar and all were seven places apart from each other on Mendeleev's table. Using these patterns, Mendeleev predicted the existence and properties of new elements, which were later discovered in nature: scandium, gallium, and germanium.[26]: 118  Moreover, the periodic table could predict how many atoms of other elements that an atom could bond with — e.g., germanium and carbon are in the same group on the table and their atoms both combine with two oxygen atoms each (GeO2 and CO2). Mendeleev found these patterns validated atomic theory because it showed that the elements could be categorized by their atomic weight. Inserting a new element into the middle of a period would break the parallel between that period and the next, and would also violate Dalton's law of multiple proportions.[27]

 
Mendeleev's periodic table from 1871.

In the modern periodic table, the periodicity of the elements mentioned above is eight rather than seven because the noble gases were not known back when Mendeleev devised his table. The rows also now have different lengths (2, 8, 18, and 32) to fit with quantum theory.

Brownian motion

In 1827, the British botanist Robert Brown observed that dust particles inside pollen grains floating in water constantly jiggled about for no apparent reason. In 1905, Albert Einstein theorized that this Brownian motion was caused by the water molecules continuously knocking the grains about, and developed a mathematical model to describe it. This model was validated experimentally in 1908 by French physicist Jean Perrin, who used Einstein's equations to determine the size of atoms.[28]

Kinetic diameters of various simple molecules
Molecule Perrin's measurements[29] Modern measurements
Helium 1.7 × 10−10 m 2.6 × 10−10 m
Argon 2.7 × 10−10 m 3.4 × 10−10 m
Mercury 2.8 × 10−10 m 3 × 10−10 m
Hydrogen 2 × 10−10 m 2.89 × 10−10 m
Oxygen 2.6 × 10−10 m 3.46 × 10−10 m
Nitrogen 2.7 × 10−10 m 3.64 × 10−10 m
Chlorine 4 × 10−10 m 3.20 × 10−10 m

Statistical mechanics

In order to introduce the Ideal gas law and statistical forms of physics, it was necessary to postulate the existence of atoms. In 1738, Swiss physicist and mathematician Daniel Bernoulli postulated that the pressure of gases and heat were both caused by the underlying motion of molecules.

In 1860, James Clerk Maxwell, who was a vocal proponent of atomism, was the first to use statistical mechanics in physics.[30] Ludwig Boltzmann and Rudolf Clausius expanded his work on gases and the laws of Thermodynamics especially the second law relating to entropy. In the 1870s, Josiah Willard Gibbs extended the laws of entropy and thermodynamics and coined the term "statistical mechanics." Einstein later independently reinvented Gibbs' laws, because they had only been printed in an obscure American journal.[31] Einstein later commented that had he known of Gibbs' work, he would "not have published those papers at all, but confined myself to the treatment of some few points [that were distinct]."[32] All of statistical mechanics and the laws of heat, gas, and entropy took the existence of atoms as a necessary postulate.

Discovery of subatomic particles

Main articles: Electron and Plum pudding model
 
 
The cathode rays (blue) were emitted from the cathode, sharpened to a beam by the slits, then deflected as they passed between the two electrified plates.

Atoms were thought to be the smallest possible division of matter until 1897 when J. J. Thomson discovered the electron through his work on cathode rays.[33]

A Crookes tube is a sealed glass container in which two electrodes are separated by a vacuum. When a voltage is applied across the electrodes, cathode rays are generated, creating a glowing patch where they strike the glass at the opposite end of the tube. Through experimentation, Thomson discovered that the rays could be deflected by an electric field (in addition to magnetic fields, which was already known). He concluded that these rays, rather than being a form of light, were composed of very light negatively charged particles. Thomson called these "corpuscles", but other scientists called them electrons, following an 1894 suggestion by George Johnstone Stoney for naming the basic unit of electrical charge.[34] He measured the mass-to-charge ratio and discovered it was 1800 times smaller than that of hydrogen, the smallest atom. These corpuscles were a particle unlike any other previously known.

Thomson suggested that atoms were divisible, and that the corpuscles were their building blocks.[35] To explain the overall neutral charge of the atom, he proposed that the corpuscles were distributed in a uniform sea of positive charge.[36] This became known as the plum pudding model as the electrons were embedded in the positive charge like bits of fruit in a dried-fruit pudding, though Thomson thought the electrons moved about within the atom.[37]

Discovery of the nucleus

Main article: Geiger–Marsden experiments
 
The Geiger–Marsden experiment
Left: Expected results: alpha particles passing through the plum pudding model of the atom with negligible deflection.
Right: Observed results: a small portion of the particles were deflected by the concentrated positive charge of the nucleus.

Thomson's plum pudding model was disproved in 1909 by one of his former students, Ernest Rutherford, who discovered that most of the mass and positive charge of an atom is concentrated in a very small fraction of its volume, which he assumed to be at the very center.

Ernest Rutherford and his colleagues Hans Geiger and Ernest Marsden came to have doubts about the Thomson model after they encountered difficulties when they tried to build an instrument to measure the charge-to-mass ratio of alpha particles (these are positively-charged particles emitted by certain radioactive substances such as radium). The alpha particles were being scattered by the air in the detection chamber, which made the measurements unreliable. Thomson had encountered a similar problem in his work on cathode rays, which he solved by creating a near-perfect vacuum in his instruments. Rutherford didn't think he'd run into this same problem because alpha particles are much heavier than electrons. According to Thomson's model of the atom, the positive charge in the atom is not concentrated enough to produce an electric field strong enough to deflect an alpha particle, and the electrons are so lightweight they should be pushed aside effortlessly by the much heavier alpha particles. Yet there was scattering, so Rutherford and his colleagues decided to investigate this scattering carefully.[38]

Between 1908 and 1913, Rutherford and his colleagues performed a series of experiments in which they bombarded thin foils of metal with alpha particles. They spotted alpha particles being deflected by angles greater than 90°. To explain this, Rutherford proposed that the positive charge of the atom is not distributed throughout the atom's volume as Thomson believed, but is concentrated in a tiny nucleus at the center. Only such an intense concentration of charge could produce an electric field strong enough to deflect the alpha particles as observed.[38] Rutherford's model is sometimes called the "planetary model".[39] However, Hantaro Nagaoka was quoted by Rutherford as the first to suggest a planetary atom in 1904.[40] And planetary models had been suggested as early as 1897 such as the one by Joseph Larmor.[41] Probably the earliest solar system model was found in an unpublished note by Ludwig August Colding in 1854 whose idea was that atoms were analogous to planetary systems that rotate and cause magnetic polarity.[42]

First steps toward a quantum physical model of the atom

Main article: Bohr model

The planetary model of the atom had two significant shortcomings. The first is that, unlike planets orbiting a sun, electrons are charged particles. An accelerating electric charge is known to emit electromagnetic waves according to the Larmor formula in classical electromagnetism. An orbiting charge should steadily lose energy and spiral toward the nucleus, colliding with it in a small fraction of a second. The second problem was that the planetary model could not explain the highly peaked emission and absorption spectra of atoms that were observed.

 
The Bohr model of the atom

Quantum theory revolutionized physics at the beginning of the 20th century, when Max Planck and Albert Einstein postulated that light energy is emitted or absorbed in discrete amounts known as quanta (singular, quantum). This led to a series of quantum atomic models such as the quantum model of Arthur Erich Haas in 1910 and the 1912 John William Nicholson quantum atomic model that quantized angular momentum as h/2π.[43][44] In 1913, Niels Bohr incorporated this idea into his Bohr model of the atom, in which an electron could only orbit the nucleus in particular circular orbits with fixed angular momentum and energy, its distance from the nucleus (i.e., their radii) being proportional to its energy.[45] Under this model an electron could not spiral into the nucleus because it could not lose energy in a continuous manner; instead, it could only make instantaneous "quantum leaps" between the fixed energy levels.[45] When this occurred, light was emitted or absorbed at a frequency proportional to the change in energy (hence the absorption and emission of light in discrete spectra).[45]

Bohr's model was not perfect. It could only predict the spectral lines of hydrogen, not those of multielectron atoms.[46] Worse still, it could not even account for all features of the hydrogen spectrum: as spectrographic technology improved, it was discovered that applying a magnetic field caused spectral lines to multiply in a way that Bohr's model couldn't explain. In 1916, Arnold Sommerfeld added elliptical orbits to the Bohr model to explain the extra emission lines, but this made the model very difficult to use, and it still couldn't explain more complex atoms.[47][48]

Discovery of isotopes

Main article: Isotope

While experimenting with the products of radioactive decay, in 1913 radiochemist Frederick Soddy discovered that there appeared to be more than one variety of some elements.[49] The term isotope was coined by Margaret Todd as a suitable name for these varieties.[50]

That same year, J. J. Thomson conducted an experiment in which he channeled a stream of neon ions through magnetic and electric fields, striking a photographic plate at the other end. He observed two glowing patches on the plate, which suggested two different deflection trajectories. Thomson concluded this was because some of the neon ions had a different mass.[51] The nature of this differing mass would later be explained by the discovery of neutrons in 1932: all atoms of the same element contain the same number of protons, while different isotopes have different numbers of neutrons.[52]

Discovery of nuclear particles

Main articles: Atomic nucleus and Discovery of the neutron

In 1917 Rutherford bombarded nitrogen gas with alpha particles and observed hydrogen nuclei being emitted from the gas (Rutherford recognized these, because he had previously obtained them bombarding hydrogen with alpha particles, and observing hydrogen nuclei in the products). Rutherford concluded that the hydrogen nuclei emerged from the nuclei of the nitrogen atoms themselves (in effect, he had split a nitrogen).[53]

From his own work and the work of his students Bohr and Henry Moseley, Rutherford knew that the positive charge of any atom could always be equated to that of an integer number of hydrogen nuclei. This, coupled with the atomic mass of many elements being roughly equivalent to an integer number of hydrogen atoms - then assumed to be the lightest particles - led him to conclude that hydrogen nuclei were singular particles and a basic constituent of all atomic nuclei. He named such particles protons. Further experimentation by Rutherford found that the nuclear mass of most atoms exceeded that of the protons it possessed; he speculated that this surplus mass was composed of previously-unknown neutrally charged particles, which were tentatively dubbed "neutrons".

In 1928, Walter Bothe observed that beryllium emitted a highly penetrating, electrically neutral radiation when bombarded with alpha particles. It was later discovered that this radiation could knock hydrogen atoms out of paraffin wax. Initially it was thought to be high-energy gamma radiation, since gamma radiation had a similar effect on electrons in metals, but James Chadwick found that the ionization effect was too strong for it to be due to electromagnetic radiation, so long as energy and momentum were conserved in the interaction. In 1932, Chadwick exposed various elements, such as hydrogen and nitrogen, to the mysterious "beryllium radiation", and by measuring the energies of the recoiling charged particles, he deduced that the radiation was actually composed of electrically neutral particles which could not be massless like the gamma ray, but instead were required to have a mass similar to that of a proton. Chadwick now claimed these particles as Rutherford's neutrons.[54] For his discovery of the neutron, Chadwick received the Nobel Prize in 1935.[55]

Quantum physical models of the atom

Main article: Atomic orbital
 
The five filled atomic orbitals of a neon atom separated and arranged in order of increasing energy from left to right, with the last three orbitals being equal in energy. Each orbital holds up to two electrons, which most probably exist in the zones represented by the colored bubbles. Each electron is equally present in both orbital zones, shown here by color only to highlight the different wave phase.

In 1924, Louis de Broglie proposed that all moving particles—particularly subatomic particles such as electrons—exhibit a degree of wave-like behavior. Erwin Schrödinger, fascinated by this idea, explored whether or not the movement of an electron in an atom could be better explained as a wave rather than as a particle. Schrödinger's equation, published in 1926,[56] describes an electron as a wave function instead of as a point particle. This approach elegantly predicted many of the spectral phenomena that Bohr's model failed to explain. Although this concept was mathematically convenient, it was difficult to visualize, and faced opposition.[57] One of its critics, Max Born, proposed instead that Schrödinger's wave function did not describe the physical extent of an electron (like a charge distribution in classical electromagnetism), but rather gave the probability that an electron would, when measured, be found at a particular point.[58] This reconciled the ideas of wave-like and particle-like electrons: the behavior of an electron, or of any other subatomic entity, has both wave-like and particle-like aspects, and whether one aspect or the other is more apparent depends upon the situation.[59]

A consequence of describing electrons as waveforms is that it is mathematically impossible to simultaneously derive the position and momentum of an electron. This became known as the Heisenberg uncertainty principle after the theoretical physicist Werner Heisenberg, who first published a version of it in 1927.[60] (Heisenberg analyzed a thought experiment where one attempts to measure an electron's position and momentum simultaneously. However, Heisenberg did not give precise mathematical definitions of what the "uncertainty" in these measurements meant. The precise mathematical statement of the position-momentum uncertainty principle is due to Earle Hesse Kennard, Wolfgang Pauli, and Hermann Weyl.[61][62]) This invalidated Bohr's model, with its neat, clearly defined circular orbits. The modern model of the atom describes the positions of electrons in an atom in terms of probabilities. An electron can potentially be found at any distance from the nucleus, but, depending on its energy level and angular momentum, exists more frequently in certain regions around the nucleus than others; this pattern is referred to as its atomic orbital. The orbitals come in a variety of shapes—sphere, dumbbell, torus, etc.—with the nucleus in the middle.[63] The shapes of atomic orbitals are found by solving the Schrödinger equation; however, analytic solutions of the Schrödinger equation are known for very few relatively simple model Hamiltonians including the hydrogen atom and the dihydrogen cation. Even the helium atom—which contains just two electrons—has defied all attempts at a fully analytic treatment.[64][65][66]

See also

Footnotes

  1. ^ a combination of the negative term "a-" and "τομή," the term for "cut"
  2. ^ Iron(II) oxide's formula is written here as "Fe2O2" rather than the more conventional "FeO" because this better illustrates the explanation.
  1. ^ Pullman, Bernard (1998). The Atom in the History of Human Thought. Oxford, England: Oxford University Press. pp. 31–33. ISBN 978-0-19-515040-7. from the original on 5 February 2021. Retrieved 25 October 2020.
  2. ^ Melsen (1952). From Atomos to Atom, pp. 18–19
  3. ^ Pullman (1998). The Atom in the History of Human Thought, p. 198: "Dalton reaffirmed that atoms are indivisible and indestructible and are the ultimate constituents of matter."
  4. ^ Weisstein, Eric W. "Lavoisier, Antoine (1743-1794)". scienceworld.wolfram.com. Retrieved 2009-08-01.
  5. ^ "Law of definite proportions | chemistry". Encyclopedia Britannica. Retrieved 2020-09-03.
  6. ^ Dalton (1817). A New System of Chemical Philosophy vol. 2, p. 36
  7. ^ Melsen (1952). From Atomos to Atom, p. 137
  8. ^ Dalton (1817). A New System of Chemical Philosophy vol. 2, p. 28
  9. ^ Millington (1906). John Dalton, p. 113
  10. ^ Dalton (1808). A New System of Chemical Philosophy vol. 1, pp. 316-319
  11. ^ Dalton (1808). A New System of Chemical Philosophy vol. 1, pp. 316–319
  12. ^ Holbrow et al. (2010). Modern Introductory Physics, pp. 65–66
  13. ^ Johnson, Chris. . Archived from the original on 2002-07-10. Retrieved 2009-08-01.
  14. ^ Alan J. Rocke (1984). Chemical Atomism in the Nineteenth Century. Columbus: Ohio State University Press.
  15. ^ Avogadro, Amedeo (1811). "Essay on a Manner of Determining the Relative Masses of the Elementary Molecules of Bodies, and the Proportions in Which They Enter into These Compounds". Journal de Physique. 73: 58–76.
  16. ^ Hinshelwood, Cyril N.; Pauling, Linus (1956-10-19). "Amedeo Avogadro". Science. 124 (3225): 708–713. Bibcode:1956Sci...124..708H. doi:10.1126/science.124.3225.708. ISSN 0036-8075. PMID 17757602.
  17. ^ Pullman (1998). The Atom in the History of Human Thought, p. 201
  18. ^ Pullman (1998). The Atom in the History of Human Thought, p. 202
  19. ^ Pullman (1998). The Atom in the History of Human Thought, p. 226: "The first development is the establishment of the periodic classification of the elements, marking the successful climax of concerted efforts to arrange the chemical properties of elements according to their atomic weight. The second is the emergence of structural chemistry, which ousted what was a simple and primitive verbal description of the elemental composition, be it atomic or equivalentist, of substances and replaced it with a systematic determination of their internal architecture."
  20. ^ Trusted (1999). The Mystery of Matter, p. 73
  21. ^ Pullman (1998). The Atom in the History of Human Thought, p. 230
  22. ^ Melsen (1952). From Atomos to Atom, pp. 147–148
  23. ^ Henry Enfield Roscoe, Carl Schorlemmer (1895). A Treatise on Chemistry, Volume 3, Part 1, pp. 121–122
  24. ^ Henry Enfield Roscoe, Carl Schorlemmer (1895). A Treatise on Chemistry, Volume 3, Part 1, pp. 121: "The radical theory and the theory of types are capable of explaining many cases of isomerism, but it was not until the doctrine of the linking of atoms was established that a clear light was thrown on this subject."
  25. ^ Adolphe Wurtz (1880). The Atomic Theory, p. 291: "It is in this manner that the theory of atomicity predicts, interprets, and limits the number of isomers; it has furnished the elements of one of the greatest advances which science has accomplished in the last twenty years. [...] The theory of atomicity has successfully attacked the problem by introducing into the discussion exact data, which have been in a great number of cases confirmed by experiment."
  26. ^ a b Scerri, Eric R. (2020). The Periodic Table, Its Story and Its Significance (2nd ed.). New York: Oxford University Press. ISBN 978-0-190-91436-3.
  27. ^ Brito, Angmary; Rodríguez, María A.; Niaz, Mansoor (2005). "A Reconstruction of Development of the Periodic Table Based on History and Philosophy of Science and Its Implications for General Chemistry Textbooks". Journal of Research in Science Teaching. 42 (1): 84–111. Bibcode:2005JRScT..42...84B. doi:10.1002/tea.20044.
  28. ^ "The Nobel Prize in Physics 1926". NobelPrize.org. Retrieved 2023-02-08.
  29. ^ Perrin (1909). Brownian Movement and Molecular Reality, p. 50
  30. ^ See:
    • Maxwell, J.C. (1860) "Illustrations of the dynamical theory of gases. Part I. On the motions and collisions of perfectly elastic spheres," Philosophical Magazine, 4th series, 19 : 19–32.
    • Maxwell, J.C. (1860) "Illustrations of the dynamical theory of gases. Part II. On the process of diffusion of two or more kinds of moving particles among one another," Philosophical Magazine, 4th series, 20 : 21–37.
  31. ^ Navarro, Luis. “Gibbs, Einstein and the Foundations of Statistical Mechanics.” Archive for History of Exact Sciences, vol. 53, no. 2, Springer, 1998, pp. 147–80, http://www.jstor.org/stable/41134058.
  32. ^ Stone, A. Douglas, Einstein and the quantum : the quest of the valiant Swabian, Princeton University Press, (2013). ISBN 978-0-691-13968-5 quoted from Folsing, Albert Einstein, 110.
  33. ^ Thomson, J. J. (1897). "Cathode rays" ([facsimile from Stephen Wright, Classical Scientific Papers, Physics (Mills and Boon, 1964)]). Philosophical Magazine. 44 (269): 293. doi:10.1080/14786449708621070.
  34. ^ Olenick, Richard P.; Apostol, Tom M.; Goodstein, David L. (1986-12-26). Beyond the Mechanical Universe: From Electricity to Modern Physics. Cambridge University Press. p. 435. ISBN 978-0-521-30430-6.
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Bibliography

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Further reading

External links

 
Wikiquote has quotations related to Atomic theory.
  • Atomism by S. Mark Cohen.
  • Atomic Theory - detailed information on atomic theory with respect to electrons and electricity.
  • The Feynman Lectures on Physics Vol. I Ch. 1: Atoms in Motion

January 19, 2024
atomic, theory, atomic, model, redirects, here, unrelated, term, mathematical, logic, atomic, model, mathematical, logic, this, article, about, historical, development, understanding, existence, behavior, atoms, history, study, atoms, combine, form, molecules,. Atomic model redirects here For the unrelated term in mathematical logic see atomic model mathematical logic This article is about the historical development of understanding the existence and behavior of atoms For a history of the study of how atoms combine to form molecules see history of molecular theory For the modern view of the atom which developed from atomic theory see atomic physics Atomic theory is the scientific theory that matter is composed of particles called atoms The concept that matter is composed of discrete particles is an ancient idea but gained scientific credence in the 18th and 19th centuries when scientists found it could explain the behaviors of gases and how chemical elements reacted with each other By the end of the 19th century atomic theory had gained widespread acceptance in the scientific community The current theoretical model of the atom involves a dense nucleus surrounded by a probabilistic cloud of electronsThe term atom comes from the Greek word atomos which means uncuttable John Dalton applied the term to the basic units of mass of the chemical elements under the mistaken belief that chemical atoms are the fundamental particles in nature it was another century before scientists realized that Dalton s so called atoms have an underlying structure of their own Particles which are truly indivisible are now referred to as elementary particles Contents 1 History 1 1 Philosophical atomism 1 2 Dalton s law of multiple proportions 1 3 Dalton s atomic theory 1 4 Opposition to atomic theory 1 5 Isomerism 1 6 Mendeleev s periodic table 1 7 Brownian motion 1 8 Statistical mechanics 1 9 Discovery of subatomic particles 1 10 Discovery of the nucleus 1 11 First steps toward a quantum physical model of the atom 1 12 Discovery of isotopes 1 13 Discovery of nuclear particles 1 14 Quantum physical models of the atom 2 See also 3 Footnotes 4 Bibliography 5 Further reading 6 External linksHistoryPhilosophical atomism Main article Atomism See also Prima materia The basic idea that matter is made up of tiny indivisible particles is an old idea that appeared in many ancient cultures The word atom is derived from the ancient Greek word atomos a which means uncuttable This ancient idea was based in philosophical reasoning rather than scientific reasoning Modern atomic theory is not based on these old concepts 1 2 In the early 19th century the scientist John Dalton noticed that chemical elements seemed to combine with each other by discrete units of weight and he decided to use the word atom to refer to these units as he thought these were the fundamental units of matter 3 About a century later it was discovered that Dalton s atoms are not actually indivisible but the term stuck Dalton s law of multiple proportions nbsp From A New System of Chemical Philosophy 1808 Near the end of the 18th century two laws about chemical reactions emerged without referring to the notion of an atomic theory The first was the law of conservation of mass closely associated with the work of Antoine Lavoisier which states that the total mass in a chemical reaction remains constant that is the reactants have the same mass as the products 4 The second was the law of definite proportions First established by the French chemist Joseph Proust in 1797 this law states that if a compound is broken down into its constituent chemical elements then the masses of the constituents will always have the same proportions by weight regardless of the quantity or source of the original substance 5 John Dalton studied data gathered by himself and other scientists and noticed a pattern that later came to be known as the law of multiple proportions In compounds which all contain a particular element the content of that element will differ across these compounds by ratios of small whole numbers Dalton concluded from all this that elements react with each other in discrete and consistent units of weight Borrowing the word from the philosophical tradition Dalton called these units atoms Example 1 tin oxides There are two types of tin oxide one is a grey powder that is 88 1 tin and 11 9 oxygen and the other is a white powder that is 78 7 tin and 21 3 oxygen Adjusting these figures in the grey powder there is about 13 5 g of oxygen for every 100 g of tin and in the white powder there is about 27 g of oxygen for every 100 g of tin 13 5 and 27 form a ratio of 1 2 Dalton concluded that in these oxides for every tin atom there are one or two oxygen atoms respectively SnO and SnO2 6 7 Example 2 iron oxides Dalton identified two oxides of iron There is one type of iron oxide that is a black powder which is 78 1 iron and 21 9 oxygen and there is another iron oxide that is a red powder which is 70 4 iron and 29 6 oxygen Adjusting these figures in the black powder there is about 28 g of oxygen for every 100 g of iron and in the red powder there is about 42 g of oxygen for every 100 g of iron 28 and 42 form a ratio of 2 3 Dalton concluded that in these oxides for every two atoms of iron there are two or three atoms of oxygen respectively Fe2O2 and Fe2O3 b 8 9 Example 3 nitrogen oxides Dalton was aware of three oxides of nitrogen nitrous oxide nitrous gas and nitric acid 10 These compounds are known today as nitrous oxide nitric oxide and nitrogen dioxide respectively Nitrous oxide is 63 3 nitrogen and 36 7 oxygen which means it has 80 g of oxygen for every 140 g of nitrogen Nitrous gas is 44 05 nitrogen and 55 95 oxygen which means there are 160 g of oxygen for every 140 g of nitrogen Nitric acid is 29 5 nitrogen and 70 5 oxygen which means it has 320 g of oxygen for every 140 g of nitrogen 80 g 160 g and 320 g form a ratio of 1 2 4 The formulas for these compounds are N2O NO and NO2 11 12 Dalton s atomic theory From the evidence provided by the law of multiple proportions Dalton developed his atomic theory A central problem for the theory was to determine the relative weights of the atoms of various elements The atomic weight of an element is the weight an atom of that element is compared to the weights of atoms of the other elements Dalton and his contemporaries could not measure the absolute weight of atoms i e their weight in grams because atoms were far too small to be directly measured with the technologies that existed in the 19th century Instead they measured how heavy atoms of various elements were relative to atoms of hydrogen which chemists of Dalton s day knew was the lightest element in nature Dalton estimated the atomic weights according to the mass ratios in which they combined with the weight of the hydrogen atom taken conventionally as unity However Dalton did not realize that some elements exist as molecules in their natural pure form e g pure oxygen exists as O2 He also mistakenly believed that the simplest compound between any two elements is always one atom of each so he thought water was HO not H2O 13 This in addition to the limitations of his apparatus flawed his results For instance in 1803 he believed that oxygen atoms were 5 5 times heavier than hydrogen atoms because in water he measured 5 5 grams of oxygen for every 1 gram of hydrogen and believed the formula for water was HO Adopting better data in 1806 he concluded that the atomic weight of oxygen must actually be 7 rather than 5 5 and he retained this weight for the rest of his life Others at this time had already concluded from more precise measurements that the oxygen atom must weigh 8 relative to hydrogen equals 1 if one assumes Dalton s formula for the water molecule HO or 16 if one assumes the modern water formula H2O 14 The flaw in Dalton s theory was corrected in principle in 1811 by Amedeo Avogadro Avogadro had proposed that equal volumes of any two gases at equal temperature and pressure contain equal numbers of molecules in other words the mass of a gas s particles does not affect the volume that it occupies 15 Avogadro s hypothesis now usually called Avogadro s law provided a method for deducing the relative weights of the molecules of gaseous elements for if the hypothesis is correct relative gas densities directly indicate the relative weights of the particles that compose the gases This way of thinking led directly to a second hypothesis the particles of certain elemental gases were not atoms but molecules consisting of two atoms each and when combining chemically these molecules often split in two For instance the fact that two liters of hydrogen will react with just one liter of oxygen to produce two liters of water vapor at constant pressure and temperature suggested that a single oxygen molecule must split in two in order to form two molecules of water This also meant that the water molecule must be H2O Thus Avogadro was able to offer more accurate estimates of the atomic mass of oxygen and various other elements and made a distinction between molecules and atoms What we now call atoms Avogadro called elementary molecules and what we now call molecules Avogadro called compound molecules 16 Opposition to atomic theory Dalton s atomic theory was not immediately accepted by all scientists One problem was the lack of uniform nomenclature The word atom implied indivisibility but Dalton instead defined an atom as being the basic particle of any substance which meant that compound atoms such as carbon dioxide could divided as opposed to elementary atoms 17 Other scientists used their own nomenclature which only added to the general confusion For instance J J Berzelius used the term organic atoms to refer to particles containing three or more elements because he thought this only existed in organic compounds 18 A second problem was philosophical Scientists in the 19th century had no way of directly observing atoms They inferred the existence of atoms through indirect observations such as Dalton s law of multiple proportions Some Scientists notably those who ascribed to the school of positivism argued that scientists should not attempt to deduce the deeper reality of the universe but only systemize what patterns they can directly observe The anti atomists argued that while atoms might be a useful abstraction for predicting how elements react they do not reflect concrete reality Such scientists were sometimes known as equivalentists because they preferred the theory of equivalent weights which is a generalization of Proust s law of definite proportions For example 1 gram of hydrogen will combine with 8 grams of oxygen to form 9 grams of water therefore the equivalent weight of oxygen is 8 grams This position was eventually quashed by two important advancements that happened later in the 19th century the development of the periodic table and the discovery that molecules have an internal architecture that determines their properties 19 Dalton s law of multiple proportions was also shown to not be a universal law when it came to organic substances For instance in oleic acid there is 34 g of hydrogen for every 216 g of carbon and in methane there is 72 g of hydrogen for every 216 g of carbon 34 and 72 form a ratio of 17 36 which is not a ratio of small whole numbers We know now that carbon based substances can have very large molecules larger than any the other elements can form Oleic acid s formula is C18H34O2 and methane s is CH4 20 Isomerism Scientists discovered some substances have the exact same chemical content but different properties For instance in 1827 Friedrich Wohler discovered that silver fulminate and silver cyanate are both 107 parts silver 12 parts carbon 14 parts nitrogen and 12 parts oxygen we now know their formulas as both AgCNO In 1830 Jons Jacob Berzelius introduced the term isomerism to describe the phenomenon In 1860 Louis Pasteur hypothesized that the molecules of isomers might have the same set of atoms but in different arrangements 21 In 1874 Jacobus Henricus van t Hoff proposed that the carbon atom bonds to other atoms in a tetrahedral arrangement Working from this he explained the structures of organic molecules in such a way that he could predict how many isomers a compound could have Consider for example pentane C5H12 In van t Hoff s way of modelling molecules there are three possible configurations for pentane and scientists did go on to discover three and only three isomers of pentane 22 23 nbsp n pentane nbsp isopentane nbsp neopentaneJacobus Henricus van t Hoff s way of modelling molecular structures correctly predicted three possible isomers for pentane C5H12 Isomerism was not something that could be fully explained by alternative theories to atomic theory such as radical theory and the theory of types 24 25 Mendeleev s periodic table Main article Periodic table Dmitrii Mendeleev noticed that when he arranged the elements in a row according to their atomic weights there was a certain periodicity to them 26 117 For instance the second element lithium had similar properties to the ninth element sodium and the sixteenth element potassium a period of seven Likewise beryllium magnesium and calcium were similar and all were seven places apart from each other on Mendeleev s table Using these patterns Mendeleev predicted the existence and properties of new elements which were later discovered in nature scandium gallium and germanium 26 118 Moreover the periodic table could predict how many atoms of other elements that an atom could bond with e g germanium and carbon are in the same group on the table and their atoms both combine with two oxygen atoms each GeO2 and CO2 Mendeleev found these patterns validated atomic theory because it showed that the elements could be categorized by their atomic weight Inserting a new element into the middle of a period would break the parallel between that period and the next and would also violate Dalton s law of multiple proportions 27 nbsp Mendeleev s periodic table from 1871 In the modern periodic table the periodicity of the elements mentioned above is eight rather than seven because the noble gases were not known back when Mendeleev devised his table The rows also now have different lengths 2 8 18 and 32 to fit with quantum theory Brownian motion In 1827 the British botanist Robert Brown observed that dust particles inside pollen grains floating in water constantly jiggled about for no apparent reason In 1905 Albert Einstein theorized that this Brownian motion was caused by the water molecules continuously knocking the grains about and developed a mathematical model to describe it This model was validated experimentally in 1908 by French physicist Jean Perrin who used Einstein s equations to determine the size of atoms 28 Kinetic diameters of various simple molecules Molecule Perrin s measurements 29 Modern measurementsHelium 1 7 10 10 m 2 6 10 10 mArgon 2 7 10 10 m 3 4 10 10 mMercury 2 8 10 10 m 3 10 10 mHydrogen 2 10 10 m 2 89 10 10 mOxygen 2 6 10 10 m 3 46 10 10 mNitrogen 2 7 10 10 m 3 64 10 10 mChlorine 4 10 10 m 3 20 10 10 mStatistical mechanics In order to introduce the Ideal gas law and statistical forms of physics it was necessary to postulate the existence of atoms In 1738 Swiss physicist and mathematician Daniel Bernoulli postulated that the pressure of gases and heat were both caused by the underlying motion of molecules In 1860 James Clerk Maxwell who was a vocal proponent of atomism was the first to use statistical mechanics in physics 30 Ludwig Boltzmann and Rudolf Clausius expanded his work on gases and the laws of Thermodynamics especially the second law relating to entropy In the 1870s Josiah Willard Gibbs extended the laws of entropy and thermodynamics and coined the term statistical mechanics Einstein later independently reinvented Gibbs laws because they had only been printed in an obscure American journal 31 Einstein later commented that had he known of Gibbs work he would not have published those papers at all but confined myself to the treatment of some few points that were distinct 32 All of statistical mechanics and the laws of heat gas and entropy took the existence of atoms as a necessary postulate Discovery of subatomic particles Main articles Electron and Plum pudding model nbsp nbsp The cathode rays blue were emitted from the cathode sharpened to a beam by the slits then deflected as they passed between the two electrified plates Atoms were thought to be the smallest possible division of matter until 1897 when J J Thomson discovered the electron through his work on cathode rays 33 A Crookes tube is a sealed glass container in which two electrodes are separated by a vacuum When a voltage is applied across the electrodes cathode rays are generated creating a glowing patch where they strike the glass at the opposite end of the tube Through experimentation Thomson discovered that the rays could be deflected by an electric field in addition to magnetic fields which was already known He concluded that these rays rather than being a form of light were composed of very light negatively charged particles Thomson called these corpuscles but other scientists called them electrons following an 1894 suggestion by George Johnstone Stoney for naming the basic unit of electrical charge 34 He measured the mass to charge ratio and discovered it was 1800 times smaller than that of hydrogen the smallest atom These corpuscles were a particle unlike any other previously known Thomson suggested that atoms were divisible and that the corpuscles were their building blocks 35 To explain the overall neutral charge of the atom he proposed that the corpuscles were distributed in a uniform sea of positive charge 36 This became known as the plum pudding model as the electrons were embedded in the positive charge like bits of fruit in a dried fruit pudding though Thomson thought the electrons moved about within the atom 37 Discovery of the nucleus Main article Geiger Marsden experiments nbsp The Geiger Marsden experiment Left Expected results alpha particles passing through the plum pudding model of the atom with negligible deflection Right Observed results a small portion of the particles were deflected by the concentrated positive charge of the nucleus Thomson s plum pudding model was disproved in 1909 by one of his former students Ernest Rutherford who discovered that most of the mass and positive charge of an atom is concentrated in a very small fraction of its volume which he assumed to be at the very center Ernest Rutherford and his colleagues Hans Geiger and Ernest Marsden came to have doubts about the Thomson model after they encountered difficulties when they tried to build an instrument to measure the charge to mass ratio of alpha particles these are positively charged particles emitted by certain radioactive substances such as radium The alpha particles were being scattered by the air in the detection chamber which made the measurements unreliable Thomson had encountered a similar problem in his work on cathode rays which he solved by creating a near perfect vacuum in his instruments Rutherford didn t think he d run into this same problem because alpha particles are much heavier than electrons According to Thomson s model of the atom the positive charge in the atom is not concentrated enough to produce an electric field strong enough to deflect an alpha particle and the electrons are so lightweight they should be pushed aside effortlessly by the much heavier alpha particles Yet there was scattering so Rutherford and his colleagues decided to investigate this scattering carefully 38 Between 1908 and 1913 Rutherford and his colleagues performed a series of experiments in which they bombarded thin foils of metal with alpha particles They spotted alpha particles being deflected by angles greater than 90 To explain this Rutherford proposed that the positive charge of the atom is not distributed throughout the atom s volume as Thomson believed but is concentrated in a tiny nucleus at the center Only such an intense concentration of charge could produce an electric field strong enough to deflect the alpha particles as observed 38 Rutherford s model is sometimes called the planetary model 39 However Hantaro Nagaoka was quoted by Rutherford as the first to suggest a planetary atom in 1904 40 And planetary models had been suggested as early as 1897 such as the one by Joseph Larmor 41 Probably the earliest solar system model was found in an unpublished note by Ludwig August Colding in 1854 whose idea was that atoms were analogous to planetary systems that rotate and cause magnetic polarity 42 First steps toward a quantum physical model of the atom Main article Bohr model The planetary model of the atom had two significant shortcomings The first is that unlike planets orbiting a sun electrons are charged particles An accelerating electric charge is known to emit electromagnetic waves according to the Larmor formula in classical electromagnetism An orbiting charge should steadily lose energy and spiral toward the nucleus colliding with it in a small fraction of a second The second problem was that the planetary model could not explain the highly peaked emission and absorption spectra of atoms that were observed nbsp The Bohr model of the atomQuantum theory revolutionized physics at the beginning of the 20th century when Max Planck and Albert Einstein postulated that light energy is emitted or absorbed in discrete amounts known as quanta singular quantum This led to a series of quantum atomic models such as the quantum model of Arthur Erich Haas in 1910 and the 1912 John William Nicholson quantum atomic model that quantized angular momentum as h 2p 43 44 In 1913 Niels Bohr incorporated this idea into his Bohr model of the atom in which an electron could only orbit the nucleus in particular circular orbits with fixed angular momentum and energy its distance from the nucleus i e their radii being proportional to its energy 45 Under this model an electron could not spiral into the nucleus because it could not lose energy in a continuous manner instead it could only make instantaneous quantum leaps between the fixed energy levels 45 When this occurred light was emitted or absorbed at a frequency proportional to the change in energy hence the absorption and emission of light in discrete spectra 45 Bohr s model was not perfect It could only predict the spectral lines of hydrogen not those of multielectron atoms 46 Worse still it could not even account for all features of the hydrogen spectrum as spectrographic technology improved it was discovered that applying a magnetic field caused spectral lines to multiply in a way that Bohr s model couldn t explain In 1916 Arnold Sommerfeld added elliptical orbits to the Bohr model to explain the extra emission lines but this made the model very difficult to use and it still couldn t explain more complex atoms 47 48 Discovery of isotopes Main article Isotope While experimenting with the products of radioactive decay in 1913 radiochemist Frederick Soddy discovered that there appeared to be more than one variety of some elements 49 The term isotope was coined by Margaret Todd as a suitable name for these varieties 50 That same year J J Thomson conducted an experiment in which he channeled a stream of neon ions through magnetic and electric fields striking a photographic plate at the other end He observed two glowing patches on the plate which suggested two different deflection trajectories Thomson concluded this was because some of the neon ions had a different mass 51 The nature of this differing mass would later be explained by the discovery of neutrons in 1932 all atoms of the same element contain the same number of protons while different isotopes have different numbers of neutrons 52 Discovery of nuclear particles Main articles Atomic nucleus and Discovery of the neutron In 1917 Rutherford bombarded nitrogen gas with alpha particles and observed hydrogen nuclei being emitted from the gas Rutherford recognized these because he had previously obtained them bombarding hydrogen with alpha particles and observing hydrogen nuclei in the products Rutherford concluded that the hydrogen nuclei emerged from the nuclei of the nitrogen atoms themselves in effect he had split a nitrogen 53 From his own work and the work of his students Bohr and Henry Moseley Rutherford knew that the positive charge of any atom could always be equated to that of an integer number of hydrogen nuclei This coupled with the atomic mass of many elements being roughly equivalent to an integer number of hydrogen atoms then assumed to be the lightest particles led him to conclude that hydrogen nuclei were singular particles and a basic constituent of all atomic nuclei He named such particles protons Further experimentation by Rutherford found that the nuclear mass of most atoms exceeded that of the protons it possessed he speculated that this surplus mass was composed of previously unknown neutrally charged particles which were tentatively dubbed neutrons In 1928 Walter Bothe observed that beryllium emitted a highly penetrating electrically neutral radiation when bombarded with alpha particles It was later discovered that this radiation could knock hydrogen atoms out of paraffin wax Initially it was thought to be high energy gamma radiation since gamma radiation had a similar effect on electrons in metals but James Chadwick found that the ionization effect was too strong for it to be due to electromagnetic radiation so long as energy and momentum were conserved in the interaction In 1932 Chadwick exposed various elements such as hydrogen and nitrogen to the mysterious beryllium radiation and by measuring the energies of the recoiling charged particles he deduced that the radiation was actually composed of electrically neutral particles which could not be massless like the gamma ray but instead were required to have a mass similar to that of a proton Chadwick now claimed these particles as Rutherford s neutrons 54 For his discovery of the neutron Chadwick received the Nobel Prize in 1935 55 Quantum physical models of the atom Main article Atomic orbital nbsp The five filled atomic orbitals of a neon atom separated and arranged in order of increasing energy from left to right with the last three orbitals being equal in energy Each orbital holds up to two electrons which most probably exist in the zones represented by the colored bubbles Each electron is equally present in both orbital zones shown here by color only to highlight the different wave phase In 1924 Louis de Broglie proposed that all moving particles particularly subatomic particles such as electrons exhibit a degree of wave like behavior Erwin Schrodinger fascinated by this idea explored whether or not the movement of an electron in an atom could be better explained as a wave rather than as a particle Schrodinger s equation published in 1926 56 describes an electron as a wave function instead of as a point particle This approach elegantly predicted many of the spectral phenomena that Bohr s model failed to explain Although this concept was mathematically convenient it was difficult to visualize and faced opposition 57 One of its critics Max Born proposed instead that Schrodinger s wave function did not describe the physical extent of an electron like a charge distribution in classical electromagnetism but rather gave the probability that an electron would when measured be found at a particular point 58 This reconciled the ideas of wave like and particle like electrons the behavior of an electron or of any other subatomic entity has both wave like and particle like aspects and whether one aspect or the other is more apparent depends upon the situation 59 A consequence of describing electrons as waveforms is that it is mathematically impossible to simultaneously derive the position and momentum of an electron This became known as the Heisenberg uncertainty principle after the theoretical physicist Werner Heisenberg who first published a version of it in 1927 60 Heisenberg analyzed a thought experiment where one attempts to measure an electron s position and momentum simultaneously However Heisenberg did not give precise mathematical definitions of what the uncertainty in these measurements meant The precise mathematical statement of the position momentum uncertainty principle is due to Earle Hesse Kennard Wolfgang Pauli and Hermann Weyl 61 62 This invalidated Bohr s model with its neat clearly defined circular orbits The modern model of the atom describes the positions of electrons in an atom in terms of probabilities An electron can potentially be found at any distance from the nucleus but depending on its energy level and angular momentum exists more frequently in certain regions around the nucleus than others this pattern is referred to as its atomic orbital The orbitals come in a variety of shapes sphere dumbbell torus etc with the nucleus in the middle 63 The shapes of atomic orbitals are found by solving the Schrodinger equation however analytic solutions of the Schrodinger equation are known for very few relatively simple model Hamiltonians including the hydrogen atom and the dihydrogen cation Even the helium atom which contains just two electrons has defied all attempts at a fully analytic treatment 64 65 66 See also nbsp Physics portalSpectroscopy History of molecular theory Timeline of chemical element discoveries Introduction to quantum mechanics Kinetic theory of gases Atomism The Physical Principles of the Quantum TheoryFootnotes a combination of the negative term a and tomh the term for cut Iron II oxide s formula is written here as Fe2O2 rather than the more conventional FeO because this better illustrates the explanation Pullman Bernard 1998 The Atom in the History of Human Thought Oxford England Oxford University Press pp 31 33 ISBN 978 0 19 515040 7 Archived from the original on 5 February 2021 Retrieved 25 October 2020 Melsen 1952 From Atomos to Atom pp 18 19 Pullman 1998 The Atom in the History of Human Thought p 198 Dalton reaffirmed that atoms are indivisible and indestructible and are the ultimate constituents of matter Weisstein Eric W Lavoisier Antoine 1743 1794 scienceworld wolfram com Retrieved 2009 08 01 Law of definite proportions chemistry Encyclopedia Britannica Retrieved 2020 09 03 Dalton 1817 A New System of Chemical Philosophy vol 2 p 36 Melsen 1952 From Atomos to Atom p 137 Dalton 1817 A New System of Chemical Philosophy vol 2 p 28 Millington 1906 John Dalton p 113 Dalton 1808 A New System of Chemical Philosophy vol 1 pp 316 319 Dalton 1808 A New System of Chemical Philosophy vol 1 pp 316 319 Holbrow et al 2010 Modern Introductory Physics pp 65 66 Johnson Chris Avogadro his contribution to chemistry Archived from the original on 2002 07 10 Retrieved 2009 08 01 Alan J Rocke 1984 Chemical Atomism in the Nineteenth Century Columbus Ohio State University Press Avogadro Amedeo 1811 Essay on a Manner of Determining the Relative Masses of the Elementary Molecules of Bodies and the Proportions in Which They Enter into These Compounds Journal de Physique 73 58 76 Hinshelwood Cyril N Pauling Linus 1956 10 19 Amedeo Avogadro Science 124 3225 708 713 Bibcode 1956Sci 124 708H doi 10 1126 science 124 3225 708 ISSN 0036 8075 PMID 17757602 Pullman 1998 The Atom in the History of Human Thought p 201 Pullman 1998 The Atom in the History of Human Thought p 202 Pullman 1998 The Atom in the History of Human Thought p 226 The first development is the establishment of the periodic classification of the elements marking the successful climax of concerted efforts to arrange the chemical properties of elements according to their atomic weight The second is the emergence of structural chemistry which ousted what was a simple and primitive verbal description of the elemental composition be it atomic or equivalentist of substances and replaced it with a systematic determination of their internal architecture Trusted 1999 The Mystery of Matter p 73 Pullman 1998 The Atom in the History of Human Thought p 230 Melsen 1952 From Atomos to Atom pp 147 148 Henry Enfield Roscoe Carl Schorlemmer 1895 A Treatise on Chemistry Volume 3 Part 1 pp 121 122 Henry Enfield Roscoe Carl Schorlemmer 1895 A Treatise on Chemistry Volume 3 Part 1 pp 121 The radical theory and the theory of types are capable of explaining many cases of isomerism but it was not until the doctrine of the linking of atoms was established that a clear light was thrown on this subject Adolphe Wurtz 1880 The Atomic Theory p 291 It is in this manner that the theory of atomicity predicts interprets and limits the number of isomers it has furnished the elements of one of the greatest advances which science has accomplished in the last twenty years The theory of atomicity has successfully attacked the problem by introducing into the discussion exact data which have been in a great number of cases confirmed by experiment a b Scerri Eric R 2020 The Periodic Table Its Story and Its Significance 2nd ed New York Oxford University Press ISBN 978 0 190 91436 3 Brito Angmary Rodriguez Maria A Niaz Mansoor 2005 A Reconstruction of Development of the Periodic Table Based on History and Philosophy of Science and Its Implications for General Chemistry Textbooks Journal of Research in Science Teaching 42 1 84 111 Bibcode 2005JRScT 42 84B doi 10 1002 tea 20044 The Nobel Prize in Physics 1926 NobelPrize org Retrieved 2023 02 08 Perrin 1909 Brownian Movement and Molecular Reality p 50 See Maxwell J C 1860 Illustrations of the dynamical theory of gases Part I On the motions and collisions of perfectly elastic spheres Philosophical Magazine 4th series 19 19 32 Maxwell J C 1860 Illustrations of the dynamical theory of gases Part II On the process of diffusion of two or more kinds of moving particles among one another Philosophical Magazine 4th series 20 21 37 Navarro Luis Gibbs Einstein and the Foundations of Statistical Mechanics Archive for History of Exact Sciences vol 53 no 2 Springer 1998 pp 147 80 http www jstor org stable 41134058 Stone A Douglas Einstein and the quantum the quest of the valiant Swabian Princeton University Press 2013 ISBN 978 0 691 13968 5 quoted from Folsing Albert Einstein 110 Thomson J J 1897 Cathode rays facsimile from Stephen Wright Classical Scientific Papers Physics Mills and Boon 1964 Philosophical Magazine 44 269 293 doi 10 1080 14786449708621070 Olenick Richard P Apostol Tom M Goodstein David L 1986 12 26 Beyond the Mechanical Universe From Electricity to Modern Physics Cambridge University Press p 435 ISBN 978 0 521 30430 6 Whittaker E T 1951 A History of the Theories of Aether and Electricity Vol 1 Nelson London Thomson J J 1904 On the Structure of the Atom an Investigation of the Stability and Periods of Oscillation of a number of Corpuscles arranged at equal intervals around the Circumference of a Circle with Application of the Results to the Theory of Atomic Structure Philosophical Magazine 7 39 237 doi 10 1080 14786440409463107 Hon Giora Goldstein Bernard R 2013 09 06 J J Thomson s plum pudding atomic model The making of a scientific myth Annalen der Physik 525 8 9 A129 A133 Bibcode 2013AnP 525A 129H doi 10 1002 andp 201300732 S2CID 119853037 a b Heilbron 2003 Ernest Rutherford and the Explosion of Atoms pp 64 68 Rutherford model Definition amp Facts Encyclopedia Britannica Retrieved 23 August 2021 Rutherford either knew the article or looked it up for he cited it on the last page of his classic paper The Scattering of a and b Particles by Matter and the Structure of the Atom Phil Mag 21 1911 669 Larmor Joseph 1897 On a Dynamical Theory of the Electric and Luminiferous Medium Part 3 Relations with material media Philosophical Transactions of the Royal Society 190 205 300 Bibcode 1897RSPTA 190 205L doi 10 1098 rsta 1897 0020 that of the transmission of radiation across a medium permeated by molecules each consisting of a system of electrons in steady orbital motion and each capable of free oscillations about the steady state of motion with definite free periods analogous to those of the planetary inequalities of the Solar System Helge Kragh Niels Bohr and the Quantum Atom The Bohr Model of Atomic Structure 1913 1925 2012 Chap 1 ISBN 9780199654987 Oxford Scholarship Online doi 10 1093 acprof oso 9780199654987 001 0001 J W Nicholson Month Not Roy Astr Soc lxxii pp 49 130 677 693 729 1912 The Atomic Theory of John William Nicholson Russell McCormmach Archive for History of Exact Sciences Vol 3 No 2 25 8 1966 pp 160 184 25 pages Springer a b c Bohr Niels 1913 On the constitution of atoms and molecules PDF Philosophical Magazine 26 153 476 502 Bibcode 1913PMag 26 476B doi 10 1080 14786441308634993 Archived PDF from the original on 2022 10 09 Kragh Helge 1979 Niels Bohr s Second Atomic Theory Historical Studies in the Physical Sciences 10 123 186 doi 10 2307 27757389 ISSN 0073 2672 JSTOR 27757389 Hentschel Klaus 2009 Zeeman Effect In Greenberger Daniel Hentschel Klaus Weinert Friedel eds Compendium of Quantum Physics Berlin Heidelberg Springer Berlin Heidelberg pp 862 864 doi 10 1007 978 3 540 70626 7 241 ISBN 978 3 540 70622 9 Retrieved 2023 02 08 Eckert Michael April 2014 How Sommerfeld extended Bohr s model of the atom 1913 1916 The European Physical Journal H 39 2 141 156 Bibcode 2014EPJH 39 141E doi 10 1140 epjh e2013 40052 4 ISSN 2102 6459 S2CID 256006474 Frederick Soddy The Nobel Prize in Chemistry 1921 Nobel Foundation Retrieved 2008 01 18 Fleck Alexander 1957 Frederick Soddy Biographical Memoirs of Fellows of the Royal Society 3 203 216 doi 10 1098 rsbm 1957 0014 p 208 Up to 1913 we used the phrase radio elements chemically non separable and at that time the word isotope was suggested in a drawing room discussion with Dr Margaret Todd in the home of Soddy s father in law Sir George Beilby Thomson J J 1913 Rays of positive electricity Proceedings of the Royal Society A 89 607 1 20 Bibcode 1913RSPSA 89 1T doi 10 1098 rspa 1913 0057 S2CID 124295244 as excerpted in Henry A Boorse amp Lloyd Motz The World of the Atom Vol 1 New York Basic Books 1966 Retrieved on August 29 2007 Flowers Paul et al 2022 Chemistry 2e OpenStax pp 70 71 ISBN 978 1 947172 61 6 Rutherford Ernest 1919 Collisions of alpha Particles with Light Atoms IV An Anomalous Effect in Nitrogen Philosophical Magazine 37 222 581 doi 10 1080 14786440608635919 Chadwick James 1932 Possible Existence of a Neutron PDF Nature 129 3252 312 Bibcode 1932Natur 129Q 312C doi 10 1038 129312a0 S2CID 4076465 Archived PDF from the original on 2022 10 09 The Nobel Prize in Physics 1935 NobelPrize org Retrieved 2023 02 08 Schrodinger Erwin 1926 Quantisation as an Eigenvalue Problem Annalen der Physik 81 18 109 139 Bibcode 1926AnP 386 109S doi 10 1002 andp 19263861802 Mahanti Subodh Erwin Schrodinger The Founder of Quantum Wave Mechanics Archived from the original on 2009 04 17 Retrieved 2009 08 01 Mahanti Subodh Max Born Founder of Lattice Dynamics Archived from the original on 2009 01 22 Retrieved 2009 08 01 Greiner Walter 4 October 2000 Quantum Mechanics An Introduction Springer ISBN 9783540674580 Retrieved 2010 06 14 Heisenberg W 1927 Uber den anschaulichen Inhalt der quantentheoretischen Kinematik und Mechanik Zeitschrift fur Physik in German 43 3 4 172 198 Bibcode 1927ZPhy 43 172H doi 10 1007 BF01397280 S2CID 122763326 Busch Paul Lahti Pekka Werner Reinhard F 17 October 2013 Proof of Heisenberg s Error Disturbance Relation Physical Review Letters 111 16 160405 arXiv 1306 1565 Bibcode 2013PhRvL 111p0405B doi 10 1103 PhysRevLett 111 160405 ISSN 0031 9007 PMID 24182239 S2CID 24507489 Appleby David Marcus 6 May 2016 Quantum Errors and Disturbances Response to Busch Lahti and Werner Entropy 18 5 174 arXiv 1602 09002 Bibcode 2016Entrp 18 174A doi 10 3390 e18050174 Milton Orchin Roger Macomber Allan Pinhas R Wilson The Vocabulary and Concepts of Organic Chemistry Second Edition PDF Archived PDF from the original on 2022 10 09 Retrieved 2010 06 14 Zwiebach Barton 2022 Mastering Quantum Mechanics Essentials Theory and Applications Cambridge MIT Press pp 281 305 ISBN 978 0 262 36689 2 OCLC 1306066387 Grivet Jean Philippe January 2002 The Hydrogen Molecular Ion Revisited Journal of Chemical Education 79 1 127 Bibcode 2002JChEd 79 127G doi 10 1021 ed079p127 ISSN 0021 9584 Levin F S Shertzer J 1985 12 01 Finite element solution of the Schrodinger equation for the helium ground state Physical Review A 32 6 3285 3290 Bibcode 1985PhRvA 32 3285L doi 10 1103 PhysRevA 32 3285 ISSN 0556 2791 PMID 9896495 BibliographyAndrew G van Melsen 1960 First published 1952 From Atomos to Atom The History of the Concept Atom Translated by Henry J Koren Dover Publications ISBN 0 486 49584 1 J P Millington 1906 John Dalton J M Dent amp Co London E P Dutton amp Co New York Jaume Navarro 2012 A History of the Electron J J and G P Thomson Cambridge University Press ISBN 978 1 107 00522 8 Jennifer Trusted 1999 The Mystery of Matter MacMillan ISBN 0 333 76002 6 Bernard Pullman 1998 The Atom in the History of Human Thought Translated by Axel Reisinger Oxford University Press ISBN 0 19 511447 7 Jean Perrin 1910 1909 Brownian Movement and Molecular Reality Translated by F Soddy Taylor and Francis Further readingCharles Adolphe Wurtz 1881 The Atomic Theory D Appleton and Company New York Alan J Rocke 1984 Chemical Atomism in the Nineteenth Century From Dalton to Cannizzaro Ohio State University Press Columbus open access full text at http digital case edu islandora object ksl 3Ax633gj985 External links nbsp Wikiquote has quotations related to Atomic theory Atomism by S Mark Cohen Atomic Theory detailed information on atomic theory with respect to electrons and electricity The Feynman Lectures on Physics Vol I Ch 1 Atoms in Motion Retrieved from https en wikipedia org w index php title Atomic theory amp oldid 1193200470, wikipedia, wiki, book, books, library,

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