NationMaster - Encyclopedia: Atomic theory

This article focuses on the historical models of the atom. For a history of the study of how atoms combine to form molecules, see History of the molecule. In chemistry, the history of the molecule traces the origins of the concept or idea of the existence, in nature, of a bonded structure of two or more atoms, according to which the structures of the universe are built. ...

In chemistry and physics, atomic theory is a theory of the nature of matter, which states that matter is composed of discrete units called atoms, as opposed to obsolete beliefs that matter could be divided into any arbitrarily small quantity. Or, in a nutshell, the idea that all things are made of atoms. For other uses, see Chemistry (disambiguation). ... A magnet levitating above a high-temperature superconductor demonstrates the Meissner effect. ... The word theory has a number of distinct meanings in different fields of knowledge, depending on their methodologies and the context of discussion. ... This article is about matter in physics and chemistry. ... Properties For other meanings of Atom, see Atom (disambiguation). ...

Atomic theory began hundreds of years ago as a philosophical concept, and in the 19th century achieved widespread scientific acceptance thanks to discoveries in the field of stoichiometry. The chemists of the era believed the basic units of the elements were also the fundamental particles of nature and named them atoms (derived from the Greek word atomos, meaning "indivisible"). However, around the turn of the 20^th century, through various experiments with electromagnetism and radioactivity, physicists discovered that the so-called "indivisible atom" was actually a conglomerate of various subatomic particles (chiefly, electrons, protons and neutrons) which can exist separately from each other. In fact, in certain extreme environments such as neutron stars, extreme temperature and pressure prevents atoms from existing at all. The field of science which studies subatomic particles is particle physics, and it is in this field that physicists hope to discover the true fundamental nature of matter. Stoichiometry (sometimes called reaction stoichiometry to distinguish it from composition stoichiometry) is the calculation of quantitative (measurable) relationships of the reactants and products in chemical reactions (chemical equations). ... Electromagnetism is the physics of the electromagnetic field: a field which exerts a force on particles that possess the property of electric charge, and is in turn affected by the presence and motion of those particles. ... Radioactivity may mean: Look up radioactivity in Wiktionary, the free dictionary. ... Properties The electron (also called negatron, commonly represented as e−) is a subatomic particle. ... For alternative meanings see proton (disambiguation). ... Properties In physics, the neutron is a subatomic particle with no net electric charge and a mass of 940 MeV/c² (1. ... This article is about the celestial body. ... Thousands of particles explode from the collision point of two relativistic (100 GeV per nucleon) gold ions in the STAR detector of the Relativistic Heavy Ion Collider. ...

Philosophical atomism

The concept that matter is composed of discrete units and cannot be divided into any arbitrarily small quantities has been around for thousands of years, but these ideas were founded in abstract, philosophical reasoning rather than experimentation and empirical observation. The nature of atoms in philosophy varied considerably over time and between cultures and schools, and often had spiritual elements. Nevertheless, the basic idea of the atom was adopted by scientists thousands of years later because it could elegantly explain new discoveries in the field of chemistry. Concern has been expressed that this article or section is missing information about: discussions of existence of atoms among prominent physicists up to the end of 19th century. ...

Indian

Some of the earliest known theories were developed in ancient India in the 6th century BCE by Kanada, a Hindu philosopher.^[1] In Hindu philosophy, the Nyaya and Vaisheshika schools developed elaborate theories on how atoms combined into more complex objects (first in pairs, then trios of pairs)^[1], but believed the interactions were ultimately driven by the will of God (specifically, the Hindu Ishvara), and that the atoms themselves were otherwise inactive, without physical properties of their own^{[citation needed]}. By contrast, Jainic philosophy linked the behavior of matter to the nature of the atoms themselves. Each atom, according to Jaina philosophy, has one kind of taste, one smell, one color, and two kinds of touch, though it is unclear what was meant by “kind of touch”. Atoms can exist in one of two states: subtle, in which case they can fit in infinitesimally small spaces, and gross, in which case they have extension and occupy a finite space. Although atoms are made of the same basic substance, they can combine based on their eternal properties to produce any of six “aggregates,” which seem to correspond with the Greek concept of “elements”: earth, water, shadow, sense objects, karmic matter, and unfit matter.^[2]^{[page # needed]} Ancient India may refer to: The ancient History of India, generally means the history of India only. ... Kanada (also transliterated as Kanad and in other ways; Sanskrit à¤•à¤£à¤¾à¤¦) was a Hindu sage who founded the philosophical school of Vaisheshika. ... This article discusses the adherents of Hinduism. ... (Sanskrit ni-ÄyÃ¡, literally recursion, used in the sense of syllogism, inference)) is the name given to one of the six orthodox or astika schools of Hindu philosophyâ€”specifically the school of logic. ... Vaisheshika, also Vaisesika, (Sanskrit: à¤µà¥ˆà¤¶à¥†à¤·à¤¿à¤•)is one of the six Hindu schools of philosophy (orthodox Vedic systems) of India. ... Ishvara (Sanskrit lord, master, from an adjective capable) is a philosophical concept in Hinduism, similar to the Abrahamic concept of God. ... Jaina Solo (b. ...

Greek

In the 5^th century BCE, Democritus developed the concept of atoms in order to reconcile two conflicting schools of thought on the nature of reality. On one side was Heraclitus, who believed that the nature of all existence is change. On the other side was Parmenides, who believed instead that all change is illusion. â€Ž Democritus (Greek: ) was a pre-Socratic Greek materialist philosopher (born at Abdera in Thrace ca. ... Heraclitus of Ephesus (Ancient Greek - HerÃ¡kleitos ho EphÃ©sios (Herakleitos the Ephesian)) (about 535 - 475 BC), known as The Obscure (Ancient Greek - ho SkoteinÃ³s), was a pre-Socratic Greek philosopher, a native of Ephesus on the coast of Asia Minor. ... Parmenides of Elea (Greek: , early 5th century BC) was an ancient Greek philosopher born in Elea, a Hellenic city on the southern coast of Italy. ...

Parmenides denied the existence of motion, change and void (empty space), and he came to these beliefs through very abstract thinking and perhaps a confused mixture of logic and observation. He believed there is no such thing as void, equating it with non-being (ie "if the void is, then it is not nothing; therefore it is not the void"). This in turn meant that motion is impossible, because there is no void to move into.^[3] He also wrote that that which is must be an indivisible unity, for if it were manifold, then there would have to be a void that could divide it (and he did not believe the void exists). This ultimately led him to believe that all existence is a single, all-encompassing mass that is unchanging (see monism); what seems like change is some sort of illusion. For other uses, see Monist (disambiguation). ...

Democritus accepted most of Parmenides's arguments, except for the idea that change is an illusion. He believed change was real, and if it was not then at least the illusion had to be explained. He thus supported the concept of void, and stated that the universe is made up of multiple indivisble Parmenidean entities that move around in the void. These entities, which are, are indeed unchangeable and indivisible ("atomos", the Greek word for uncuttable), but their arrangement in space is constantly changing. Democritus's atoms were made of the same material but had a limitless variety of shapes and sizes; this, coupled with their arrangement in space, explained all the different substances and objects in the universe.^[4]

Islamic

During the 11th century (in the Islamic Golden Age), Islamic atomists developed atomic theories that represent a synthesis of both Greek and Indian atomism. Older Greek and Indian ideas were further developed by Islamic atomists, along with new Islamic ideas, such as the possibility of there being particles smaller than an atom. The most successful form of Islamic atomism was in the Asharite school of philosophy, most notably in the work of the philosopher al-Ghazali (1058-1111). In Asharite atomism, atoms are the only perpetual, material things in existence, and all else in the world is “accidental” meaning something that lasts for only an instant. Nothing accidental can be the cause of anything else, except perception, as it exists for a moment. Contingent events are not subject to natural physical causes, but are the direct result of God’s constant intervention, without which nothing could happen. Thus nature is completely dependent on God, which meshes with other Asharite Islamic ideas on causation, or the lack thereof.^[5] During the Islamic Golden Age, usually dated from the 8th century to the 13th century,[1] engineers, scholars and traders of the Islamic world contributed enormously to the arts, agriculture, economics, industry, literature, navigation, philosophy, sciences, and technology, both by preserving and building upon earlier traditions and by adding many... Concern has been expressed that this article or section is missing information about: discussions of existence of atoms among prominent physicists up to the end of 19th century. ... Concern has been expressed that this article or section is missing information about: discussions of existence of atoms among prominent physicists up to the end of 19th century. ...

Modern atomic theory

Birth

In the early years of the 19th century, John Dalton developed his atomic theory in which he proposed that each chemical element is composed of atoms of a single, unique type, and that though they are both immutable and indestructible, they can combine to form more complex structures (chemical compounds). How precisely Dalton arrived at his theory is not entirely clear, but nonetheless it allowed him to explain a number of chemistry puzzles he and his contemporaries were pondering at the time.. John Dalton John Dalton (September 6, 1766 â€“ July 27, 1844) was an English chemist and physicist, born at Eaglesfield, near Cockermouth in Cumberland. ...

The first was the law of conservation of mass, formulated by Antoine Lavoisier in 1789, which states that the total mass in a chemical reaction remains constant (that is, the reactants have the same mass as the products).^[6] This law suggested to Dalton that matter is fundamentally indestructible. The law of conservation of mass/matter, also known as law of mass/matter conservation (or the Lomonosov-Lavoisier law), states that the mass of a closed system of substances will remain constant, regardless of the processes acting inside the system. ... Antoine-Laurent de Lavoisier (August 26, 1743 â€“ May 8, 1794), the father of modern chemistry [1], was a French nobleman prominent in the histories of chemistry, finance, biology, and economics. ...

The second was the law of definite proportions. First proven by the French chemist Joseph Louis Proust in 1799,^[7] this law states that if a compound is broken down into its constituent elements, then the masses of the constituents will always have the same proportions, regardless of the quantity or source of the original substance. Proust had synthesized copper carbonate through numerous methods and found that in each case the ingredients combined in the same proportions as they were produced when he broke down natural copper carbonate. This article or section does not cite any references or sources. ... Joseph Louis Proust, born September 26, 1754 in Angers in the Maine-et-Loire, departement of France - died July 5, 1826, was a chemist. ...

Dalton studied and expanded upon Proust's work to develop the law of multiple proportions: if two elements form more than one compound between them, then the ratios of the masses of the second element which combine with a fixed mass of the first element will be ratios of small integers. One pair of reactions Dalton is believed to have studied involved nitric oxide (NO) and oxygen (O₂). In one combination, these gases formed dinitrogen trioxide (N₂O₃), but when he repeated the combination with twice the amount of oxygen (a ratio of 1:2 - small integers), they instead formed nitrogen dioxide (NO₂). In chemistry, the law of multiple proportions is one of the most basic laws of stoichiometry. ... The integers consist of the positive natural numbers (1, 2, 3, …) the negative natural numbers (−1, −2, −3, ...) and the number zero. ... R-phrases , , , , S-phrases , , , Except where noted otherwise, data are given for materials in their standard state (at 25 Â°C, 100 kPa) Infobox disclaimer and references Nitric oxide or Nitrogen monoxide is a chemical compound with chemical formula NO. This gas is an important signaling molecule in the body of... General Name, symbol, number oxygen, O, 8 Chemical series nonmetals, chalcogens Group, period, block 16, 2, p Appearance colourless (gas) colourless (liquid) Standard atomic weight 15. ... The chemical compound dinitrogen trioxide (chemical formula: N2O3) is a pale blue liquid, and is unstable above 3Â°C (37Â° F) at standard pressure. ... [1] R-phrases , S-phrases , , , , , Supplementary data page Structure and properties n, Îµr, etc. ...

Dalton also believed atomic theory could explain why water absorbed different gases in different proportions: for example, he found that water absorbed carbon dioxide far better than it absorbed nitrogen. Dalton hypothesized this was due to the differences in mass and complexity of the gases' respective particles. Indeed, carbon dioxide molecules (CO₂) are heavier and larger than nitrogen molecules (N₂). Carbon dioxide is a chemical compound composed of two oxygen atoms covalently bonded to a single carbon atom. ... General Name, symbol, number nitrogen, N, 7 Chemical series nonmetals Group, period, block 15, 2, p Appearance colorless gas Standard atomic weight 14. ...

In 1803 Dalton published his first list of relative atomic weights for a number of substances (though he did not publicly discuss how he obtained these figures until 1808).^[8] Dalton estimated the atomic weights according to the mass ratios in which they combined, with hydrogen being the basic unit. However, Dalton did not conceive that with some elements atoms exist in molecules – 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)^[9]. This, in addition to the crudity of his equipment, resulted in his table being highly flawed. For instance, he believed 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 (an oxygen atom is actually 16 times heavier than a hydrogen atom). Image File history File links A_New_System_of_Chemical_Philosophy_fp. ... Image File history File links A_New_System_of_Chemical_Philosophy_fp. ... John Dalton John Dalton (September 6, 1766 â€“ July 27, 1844) was an English chemist and physicist, born at Eaglesfield, near Cockermouth in Cumberland. ...

The flaw in Dalton's theory was corrected 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 its volume).^[10] Avogadro's law allowed him to deduce the diatomic nature of numerous gases by studying the volumes at which they reacted. For instance: since two liters of hydrogen will react with just one liter of oxygen to produce two liters of water vapor (at constant pressure and temperature), it meant a single oxygen molecule splits in two in order to form two particles of water. Thus, Avogadro was able to offer more accurate estimates of the atomic mass of oxygen and various other elements, and firmly established the distinction between molecules and atoms. Avogadro redirects here. ... This article does not cite any references or sources. ...

In 1827, the British botanist Robert Brown observed that dust particles floating in water constantly jiggled about for no apparent reason. In 1905, Albert Einstein theorised that this Brownian motion was caused by the water molecules continuously knocking the grains about, and developed a hypothetical mathematical model to describe it.^[11] This model was validated experimentally in 1908 by French physicist Jean Perrin, thus providing additional validation for particle theory (and by extension atomic theory). Robert Brown (1773â€“1858) Robert Brown (December 21, 1773â€“June 10, 1858) is acknowledged as the leading British botanist to collect in Australia during the first half of the 19th century. ... â€œEinsteinâ€ redirects here. ... Three different views of Brownian motion, with 32 steps, 256 steps, and 2048 steps denoted by progressively lighter colors. ... Jean Baptiste Perrin, generally known as Jean Perrin (Lille, September 30, 1870 – April 17, New York, 1942), was a French physicist. ...

Discovery of subatomic particles

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.^[12] 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 waves, were composed of negatively charged particles he called "corpuscles" (they would later be renamed electrons by other scientists). Image File history File links No higher resolution available. ... Image File history File links No higher resolution available. ... The Crookes tube is an evacuated glass cone with 3 node elements (one anode and two cathodes). ... Sir Joseph John Thomson, OM , FRS (December 18, 1756 â€“ August 30, 1940) often known as J. J. Thomson, was an English physicist, the discoverer of the electron. ... For other uses, see Electron (disambiguation). ... A schematic diagram of a Crookes tube apparatus. ... The Crookes tube is an evacuated glass cone with 3 node elements (one anode and two cathodes). ... A schematic diagram of a Crookes tube apparatus. ...

Thomson believed that the corpuscles emerged from the very atoms of the electrode. He thus concluded that atoms were divisible, and that the corpuscles were their building blocks. To explain the overall neutral charge of the atom, he proposed that the corpuscles were distributed in a uniform sea or cloud of positive charge; this was the plum pudding model.^[13] A schematic representation of the plum pudding model of the atom. ...

Since atoms were found to be actually divisible, physicists later invented the term "elementary particles" to describe indivisible particles. For the novel, see The Elementary Particles. ...

Discovery of the nucleus

Thomson's plum pudding model was disproved in 1909 by one of his 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. Image File history File links Download high-resolution version (455x604, 28 KB)[edit] Summary Made it myself. ... Image File history File links Download high-resolution version (455x604, 28 KB)[edit] Summary Made it myself. ... A schematic representation of the plum pudding model of the atom. ... Ernest Rutherford, 1st Baron Rutherford of Nelson OM PC FRS (30 August 1871 â€“ 19 October 1937), widely referred to as Lord Rutherford, was a nuclear physicist who became known as the father of nuclear physics. ...

In the gold foil experiment, Hans Geiger and Ernest Marsden (colleagues of Rutherford working at his behest) shot alpha particles through a thin sheet of gold, striking a fluorescent screen that surrounded the sheet.^[14] Given the very small mass of the electrons, the high momentum of the alpha particles and the unconcentrated distribution of positive charge of the plum pudding model, the experimenters expected all the alpha particles to either pass through without significant deflection or be absorbed. To their astonishment, a small fraction of the alpha particles experienced heavy deflection. This led Rutherford to propose the planetary model of the atom in which pointlike electrons orbited in the space around a massive, compact nucleus—like planets orbiting the Sun.^[15] Top: Expected results: alpha particles passing through the plum pudding model of the atom undisturbed. ... Johannes (Hans) Wilhelm Geiger (September 30, 1882 â€“ September 24, 1945) was a German physicist. ... Sir Ernest Marsden (1888 - 1970), was a British-New Zealand physicist. ... An alpha particle is deflected by a magnetic field Alpha radiation consists of helium-4 nuclei and is readily stopped by a sheet of paper. ... GOLD refers to one of the following: GOLD (IEEE) is an IEEE program designed to garner more student members at the university level (Graduates of the Last Decade). ... Fluorescence induced by exposure to ultraviolet light in vials containing various sized Cadmium selenide (CdSe) quantum dots. ... The nucleus of an atom is the very small dense region, of positive charge, in its centre consisting of nucleons (protons and neutrons). ...

Discovery of isotopes

In 1913, J.J. Thomson 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; thus did he discover the existence of isotopes.^[16] Sir Joseph John Thomson, OM , FRS (December 18, 1756 â€“ August 30, 1940) often known as J. J. Thomson, was an English physicist, the discoverer of the electron. ... For other uses, see Isotope (disambiguation). ...

Discovery of nuclear particles

In 1918, Rutherford bombarded nitrogen gas with alpha particles and observed hydrogen nuclei being emitted from the gas. Rutherford concluded that the hydrogen nuclei emerged from the nuclei of the nitrogen atoms themselves (in effect, he split the atom).^[17] He later found that the positive charge of any atom could always be equated to that of an integer number of hydrogen nuclei. This, coupled with the facts that hydrogen was the lightest element known and that the atomic mass of every other element was roughly equivalent to a whole multiple of hydrogen's atomic mass, led him to conclude hydrogen nuclei were singular particles and a basic constituent of all atomic nuclei: the proton. 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 hitherto unknown neutrally charged particles, which were tentatively dubbed "neutrons". Prouts hypothesis was an early 19th century attempt to explain the existence of the various chemical elements through a hypothesis regarding the internal structure of the atom. ... Ernest Rutherford, 1st Baron Rutherford of Nelson OM PC FRS (30 August 1871 â€“ 19 October 1937), widely referred to as Lord Rutherford, was a nuclear physicist who became known as the father of nuclear physics. ... General Name, symbol, number nitrogen, N, 7 Chemical series nonmetals Group, period, block 15, 2, p Appearance colorless gas Standard atomic weight 14. ... An alpha particle is deflected by a magnetic field Alpha radiation consists of helium-4 nuclei and is readily stopped by a sheet of paper. ... Stylized lithium-7 atom: 3 protons, 4 neutrons & 3 electrons (~1800 times smaller than protons/neutrons). ... For other uses, see Proton (disambiguation). ...

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 ionisation effect was too strong for it to be due to electromagnetic radiation. In 1932, he 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 with a mass similar to that of a proton.^[18] For his discovery of the neutron, Chadwick received the Nobel Prize in 1935. Walther Wilhelm Georg Bothe (January 8, 1891 - February 8, 1957) was a German physicist, mathematician, chemist, and Nobel Prize winner. ... General Name, symbol, number beryllium, Be, 4 Chemical series alkaline earth metals Group, period, block 2, 2, s Appearance white-gray metallic Standard atomic weight 9. ... Sir James Chadwick, CH (20 October 1891 â€“ 24 July 1974) was an English physicist and Nobel laureate who is best known for discovering the neutron. ... This article or section does not adequately cite its references or sources. ...

Quantum physical models of the atom

The planetary model of the atom had shortcomings. Firstly, according to the Larmor formula in classical electromagnetism, an accelerating electric charge emits electromagnetic waves; an orbiting charge would steadily lose energy and spiral towards the nucleus, colliding with it in a small fraction of a second. Another phenomenon the model did not explain was why excited atoms only emit light within certain discrete spectra. The Larmor formula is used to calculate the power radiated by a nonrelativistic electron as it accelerates. ... Classical electrodynamics (or classical electromagnetism) is a theory of electromagnetism that was developed over the course of the 19th century, most prominently by James Clerk Maxwell. ... This box: Electric charge is a fundamental conserved property of some subatomic particles, which determines their electromagnetic interaction. ... Electromagnetic radiation is a propagating wave in space with electric and magnetic components. ... An elements emission spectrum is the relative intensity of electromagnetic radiation of each frequency it emits when it is heated (or more generally when it is excited). ...

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). In 1913, Niels Bohr incorporated this idea into his Bohr model of the atom, in which the electrons could only orbit the nucleus in particular circular orbits with fixed angular momentum and energy, their distances from the nucleus being proportional to their respective energies.^[19] Under this model electrons could not spiral into the nucleus because they could not lose energy in a continuous manner; instead, they could only make instantaneous "quantum leaps" between the fixed energy levels.^[19] 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).^[19] Image File history File links No higher resolution available. ... Image File history File links No higher resolution available. ... The Bohr model of the hydrogen atom () or a hydrogen-like ion (), where the negatively charged electron confined to an atomic shell encircles a small positively charged atomic nucleus, and an electron jump between orbits is accompanied by an emitted or absorbed amount of electromagnetic energy . ... For a less technical and generally accessible introduction to the topic, see Introduction to quantum mechanics. ... â€œPlanckâ€ redirects here. ... â€œEinsteinâ€ redirects here. ... In physics, a quantum (plural: quanta) is an indivisible entity of energy. ... Niels Henrik David Bohr (October 7, 1885 â€“ November 18, 1962) was a Danish physicist who made fundamental contributions to understanding atomic structure and quantum mechanics, for which he received the Nobel Prize in Physics in 1922. ... The Bohr model of the hydrogen atom () or a hydrogen-like ion (), where the negatively charged electron confined to an atomic shell encircles a small positively charged atomic nucleus, and an electron jump between orbits is accompanied by an emitted or absorbed amount of electromagnetic energy . ... This gyroscope remains upright while spinning due to its angular momentum. ... Quantum Leap is a science fiction television series that ran for 97 episodes from March 1989 to May 1993 on NBC. It follows the adventures of Dr. Samuel Beckett (played by Scott Bakula), a brilliant scientist who after researching time-travel, and doing experiments in something he calls The Imaging... A quantum mechanical system can only be in certain states, so that only certain energy levels are possible. ...

Bohr's model was only able to predict the spectral lines of hydrogen; it couldn't predict those of multielectron atoms. Worse still, as spectrographic technology improved, additional spectral lines in hydrogen were observed which 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 complex atoms. Arnold Johannes Wilhelm Sommerfeld (December 5, 1868 in KÃ¶nigsberg, East Prussia â€“ April 26, 1951 in Munich, Germany) was a German physicist who introduced the fine-structure constant in 1919. ...

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,^[20] describes an electron as a wavefunction instead of as a point particle, and it elegantly predicted many of the spectral phenomena Bohr's model failed to explain. Although this concept was mathematically convenient, it was difficult to visualize, and faced opposition.^[21] One of its critics, Max Born, proposed instead that Schrodinger's wavefunction described not the electron but rather all its possible states, and thus could be used to calculate the probability of finding an electron at any given location around the nucleus.^[22] Louis-Victor-Pierre-Raymond, 7th duc de Broglie, generally known as Louis de Broglie (August 15, 1892â€“March 19, 1987), was a French physicist and Nobel Prize laureate. ... Erwin Schrödinger, as depicted on the former Austrian 1000 Schilling bank note. ... In physics, the Schrödinger equation, proposed by the Austrian physicist Erwin Schrödinger in 1925, describes the time-dependence of quantum mechanical systems. ... Max Born (December 11, 1882 â€“ January 5, 1970) was a German physicist and mathematician. ...

Since a wavefunction incorporates time as well as position, it is impossible to simultaneously derive precise values for both the position and momentum of a particle for any given point in time; this became known as the uncertainty principle. 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—tends to exist more frequently in certain regions around the nucleus than others; this pattern is referred to as its atomic orbital. Image File history File links Neon_orbitals. ... In quantum physics, the outcome of even an ideal measurement of a system is not deterministic, but instead is characterized by a probability distribution, and the larger the associated standard deviation is, the more uncertain we might say that that characteristic is for the system. ... In chemistry, an atomic orbital is the region in which an electron may be found around a single atom. ...

See also

In quantum mechanics, the orbital and spin angular momentum of bodies can interact in angular momentum coupling. ... In chemistry, the history of the molecule traces the origins of the concept or idea of the existence, in nature, of a bonded structure of two or more atoms, according to which the structures of the universe are built. ... The discovery of the elements known to exist today is presented here in chronological order. ... The 1698 Savery Engine - the worlds first engine built by Thomas Savery as based on the designs of Denis Papin. ... This box: Werner Heisenberg and Erwin SchrÃ¶dinger, founders of Quantum Mechanics. ... Kinetic theory or kinetic theory of gases attempts to explain macroscopic properties of gases, such as pressure, temperature, or volume, by considering their molecular composition and motion. ... Quantum chemistry is a branch of theoretical chemistry, which applies quantum mechanics and quantum field theory to address issues and problems in chemistry. ... Timeline of quantum mechanics, molecular physics, atomic physics, nuclear physics, and particle physics 585 BC Buddha stated that there were indivisible particles of mind and matter which vibrated 3 trillion times in the blink of an eye which he called kalapas 440 BC Democritus speculates about fundamental indivisible particles---calls... A timeline of events related to thermodynamics, statistical mechanics, and random processes. ...

Notes

^ ^a ^b Teresi, Dick (2003). Lost Discoveries: The Ancient Roots of Modern Science. Simon & Schuster, 213–214. ISBN 074324379X.
^ Gangopadhyaya, Mrinalkanti. Indian Atomism: History and Sources. Atlantic Highlands, New Jersey: Humanities Press, 1981. ISBN 0-391-02177-X
^ Bertrand Russel. (1946). History of Western Philosophy. pg 75. ISB 0-415-32505-6
^ Andre G. van Melsen. (1952) From Atomos to Atom. ISBN 0-486-49584-1
^ Gardet, L. “djuz’” in Encyclopaedia of Islam CD-ROM Edition, v. 1.1. Leiden: Brill, 2001.
^ Weisstein, Eric W. "Lavoisier, Antoine (1743-1794)." scienceworld.wolfram.com. Retrieved on August 29, 2007.
^ Proust, Joseph Louis. "Researches on Copper", excerpted from Ann. chim. 32, 26-54 (1799) [as translated and reproduced in Henry M. Leicester and Herbert S. Klickstein, A Source Book in Chemistry, 1400-1900 (Cambridge, MA: Harvard, 1952)]. Retrieved on August 29, 2007.
^ Dalton, John. "On the Absorption of Gases by Water and Other Liquids", in Memoirs of the Literary and Philosophical Society of Manchester. 1803. Retrieved on August 29, 2007.
^ Johnson, Chris. "Avogadro - his contribution to chemistry." Last modified on July 4, 2004. Retrieved on August 29, 2007.
^ Avogadro, Amedeo. "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." 1811. Journal de Physique, 73, 58-76. Retrieved on August 29, 2007.
^ Einstein, Albert. "On the Movement of Small Particles Suspended in Stationary Liquids Required by the Molecular-Kinetic Theory of Heat." Annal der Physik. Retrieved on August 29, 2007.
^ Thomson, J.J. "Cathode rays." Philosophical Magazine, 44, 293 (1897). [facsimile from Stephen Wright, Classical Scientific Papers, Physics (Mills and Boon, 1964).] Retrieved on August 29, 2007.
^ Thomson, J.J. "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 March 1904. Series 6, Vol 7, No 39. Retrieved on August 29, 2007.
^ Geiger, H. "The Scattering of the α-Particles by Matter." Proceedings of the Royal Society February 17, 1910. Series A 82: 495–500. Retrieved on August 29, 2007.
^ Rutherford, Ernest. "The Scattering of α and β Particles by Matter and the Structure of the Atom." Philosophical Magazine. May 1911. Series 6, Vol. 21. Retrieved on August 29, 2007.
^ Thomson, J.J. "Rays of positive electricity." Proceedings of the Royal Society. 1913. A 89, 1–20 [as excerpted in Henry A. Boorse & Lloyd Motz, The World of the Atom, Vol. 1 (New York: Basic Books, 1966)]. Retrieved on August 29, 2007.
^ Rutherford, Ernest. "Collisions of alpha Particles with Light Atoms. IV. An Anomalous Effect in Nitrogen." Philosophical Magazine. 1919. 6th series, 37, 581. Retrieved on August 29, 2007.
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^ ^a ^b ^c Bohr, N. "On the constitution of atoms and molecules." Philosophical Magazine. July 1913. 26, 1-25. Retrieved on August 29, 2007.
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^ Mahanti, Subodh. "Max Born: Founder of Lattice Dynamics." Retrieved on August 29, 2007.

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