The word
atom is derived from the
ancient Greek word
Atomos, which means "uncuttable". However, this ancient idea was based in philosophical reasoning rather than scientific reasoning. Modern atomic theory is not based on these old concepts. In the early 19th century, the scientist
John Dalton found evidence that matter really is composed of discrete units, and so applied the word
atom to those units.
Philosophy The basic idea that matter is made up of tiny indivisible particles is an old idea that appeared in many ancient cultures. These ancient ideas were based on philosophical reasoning rather than scientific evidence, and modern atomic theory is not based on these old concepts. For example, 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 the grey oxide there is one atom of oxygen for every atom of tin, and in the white oxide there are two atoms of oxygen for every atom of tin (
SnO and
SnO2). Dalton also analyzed
iron oxides. 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. These substances are known today as
iron(II) oxide and
iron(III) oxide, and their formulas are FeO and Fe2O3 respectively. Iron(II) oxide's formula is normally written as FeO, but since it is a crystalline substance we could alternately write it as Fe2O2, and when we contrast that with Fe2O3, the 2:3 ratio for the oxygen is plain to see. As a final example:
nitrous oxide is 63.3%
nitrogen and 36.7% oxygen,
nitric oxide is 44.05% nitrogen and 55.95% oxygen, and
nitrogen dioxide is 29.5% nitrogen and 70.5% oxygen. Adjusting these figures, in nitrous oxide there is 80 g of oxygen for every 140 g of nitrogen, in nitric oxide there is about 160 g of oxygen for every 140 g of nitrogen, and in nitrogen dioxide there is 320 g of oxygen for every 140 g of nitrogen. 80, 160, and 320 form a ratio of 1:2:4. The respective formulas for these oxides are
N2O,
NO, and
NO2.
Discovery of the electron In 1897,
J. J. Thomson discovered that
cathode rays can be deflected by electric and magnetic fields, which meant that cathode rays are not a form of light but made of electrically charged particles, and their charge was negative given the direction the particles were deflected in. He measured these particles to be 1,700 times lighter than
hydrogen (the lightest atom). He called these new particles
corpuscles but they were later renamed
electrons since these are the particles that carry electricity. Thomson also showed that electrons were identical to particles given off by
photoelectric and radioactive materials. Thomson explained that an electric current is the passing of electrons from one atom to the next, and when there was no current the electrons embedded themselves in the atoms. This in turn meant that atoms were not indivisible as scientists thought. The atom was composed of electrons whose negative charge was balanced out by some source of positive charge to create an electrically neutral atom. Ions, Thomson explained, must be atoms which have an excess or shortage of electrons.
Discovery of the nucleus : The extreme scattering of some alpha particles suggested the existence of a nucleus of concentrated charge. The electrons in the atom logically had to be balanced out by a commensurate amount of positive charge, but Thomson had no idea where this positive charge came from, so he tentatively proposed that it was everywhere in the atom, the atom being in the shape of a sphere. This was the mathematically simplest hypothesis to fit the available evidence, or lack thereof. Following from this, Thomson imagined that the balance of electrostatic forces would distribute the electrons throughout the sphere in a more or less even manner. Thomson's model is popularly known as the
plum pudding model, though neither Thomson nor his colleagues used this analogy. Thomson's model was incomplete, it was unable to predict any other properties of the elements such as
emission spectra and
valencies. It was soon rendered obsolete by the discovery of the
atomic nucleus. Between 1908 and 1913,
Ernest Rutherford and his colleagues
Hans Geiger and
Ernest Marsden performed a series of experiments in which they bombarded thin foils of metal with a beam of
alpha particles. They did this to measure the scattering patterns of the alpha particles. They spotted a small number of alpha particles being deflected by angles greater than 90°. This shouldn't have been possible according to the Thomson model of the atom, whose charges were too diffuse to produce a sufficiently strong electric field. The deflections should have all been negligible. Rutherford proposed that the positive charge of the atom is concentrated in a tiny volume at the center of the atom and that the electrons surround this nucleus in a diffuse cloud. This nucleus carried almost all of the atom's mass. Only such an intense concentration of charge, anchored by its high mass, could produce an electric field that could deflect the alpha particles so strongly.
Bohr model A problem in classical mechanics is that an accelerating charged particle radiates
electromagnetic radiation, causing the particle to lose
kinetic energy. Circular motion counts as acceleration, which means that an electron orbiting a central charge should spiral down into that nucleus as it loses speed. In 1913, the physicist
Niels Bohr proposed a new model in which the electrons of an atom were assumed to orbit the nucleus but could only do so in a finite set of orbits, and could jump between these orbits only in discrete changes of energy corresponding to absorption or radiation of a
photon. Thomson later found that the positive charge in an atom is a positive multiple of an electron's negative charge. In 1913,
Henry Moseley discovered that the frequencies of X-ray emissions from an
excited atom were a mathematical function of its
atomic number and hydrogen's nuclear charge. In 1919,
Rutherford bombarded
nitrogen gas with
alpha particles and detected
hydrogen ions being emitted from the gas, and concluded that they were produced by alpha particles hitting and splitting the nuclei of the nitrogen atoms. These observations led Rutherford to conclude that the hydrogen nucleus is a singular particle with a positive charge equal to the electron's negative charge. He named this particle "
proton" in 1920. The number of protons in an atom (which Rutherford called the "
atomic number") was found to be equal to the element's ordinal number on the
periodic table and therefore provided a simple and clear-cut way of distinguishing the elements from each other. The atomic weight of each element is higher than its proton number, so Rutherford hypothesized that the surplus weight was carried by unknown particles with no electric charge and a mass equal to that of the proton. 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.
The current consensus model In 1925,
Werner Heisenberg published the first consistent mathematical formulation of quantum mechanics (
matrix mechanics). One year earlier,
Louis de Broglie had proposed that all particles behave like waves to some extent, and in 1926
Erwin Schrödinger used this idea to develop the
Schrödinger equation, which describes electrons as three-dimensional
waveforms rather than points in space. A consequence of using waveforms to describe particles is that it is mathematically impossible to obtain precise values for both the
position and
momentum of a particle at a given point in time. This became known as the
uncertainty principle, formulated by Werner Heisenberg in 1927. Thus, the planetary model of the atom was discarded in favor of one that described
atomic orbital zones around the nucleus where a given electron is most likely to be found. This model was able to explain observations of atomic behavior that previous models could not, such as certain structural and
spectral patterns of atoms larger than hydrogen. == Structure ==