Timeline of fluid and continuum mechanics

This timeline describes the major developments, both experimental and theoretical understanding of fluid mechanics and continuum mechanics. This timeline includes developments in:

Prehistory and antiquity

Free body diagram of a ball floating on water. The principles of buoyancy were known in classical antiquity.
  • Before 3000 BC – Civilization starts by settling around rivers, coast and lakes.
  • 3000 BC – Irrigation techniques develop in Mesopotamia and Ancient Egypt.[1] Indus Valley Civilisation develops city-wide drainage systems and toilet systems.[1] Egyptians develop reed boats.
  • 2300 BC – Construction of the Nahrawan Canal.[1]
  • 2000–1500 BC – First dams constructed in India to control water.[1]
  • 1700 BC – Windmill are used in Babylonia to pump water.
  • 14th century BC – Water clock are developed in Egypt under the reign of Amenhotep III. Clepsydra water clock design is developed in ancient Greece.[1]
  • 6th century BC – Theodorus of Samos invents the water level. Ancient Rome's drainage system is designed during the reign of Tarquinius Priscus. Rome's Cloaca Maxima is constructed by lining a river bed with stone. Tunnel of Eupalinos is constructed in Samos.[1]
  • 4th century BC – Mencius describes how to measure an elephant using displacement of water. Development of rain gauges in India.[1] Aqua Appia first Roman aqueduct is built in Rome.[1]
  • 3rd century BC – Archimedes published On Floating Bodies describing the general principle for buoyancy and hydrostatics. Archimedes develops Archimedes' screw for water extraction.[1]
  • 2nd century BC – The aqueduct Aqua Tepula and Aqua Marcia aqueducts are completed in Rome.[1] Zhang Heng of Han dynasty designs the first known seismoscope.[2][3][4]
  • 1st century BC – Frontinus publishes his treatise De aquaeductu on Roman water engineering. Hero of Alexandria makes a series of experiments and devices with fluids, including the aeolipile steam device and wind harnessing devices.

Middle ages

  • 8th–13th century – Arab Agricultural Revolution
  • 725 – Northumbrian monk Bede publishes The Reckoning of Time, which includes a quantitative description of the influence of the moon and the sun over the tides.
  • c. 850– Abu Ma'shar al-Balkhi (Albumasar) publishes his Kitab al-madkhal al-kabir recording the Moon position and tides, he recognizes that there are two tides in day.[5]
  • 850 – The Book of Ingenious Devices is published by the Banū Mūsā brothers, describing a number of early automatic controls using fluid mechanics.[6][7]
  • 1206 – Ismail al-Jazari invented water-powered programmable automata/robots and water music devices.[8]

Renaissance

  • 1432 – Portuguese develop caravels for long-distance ocean travel.[1]
  • 1450 –Nicholas of Cusa publishes his experiments with fluids in Idiota de staticis experimentis, including the first proposal to measure air moisture using wool.
  • 1480-1510 – Leonardo da Vinci develops the first sophisticated parachute, the first descriptions of capillary action, and the first turbine water wheels designs.[1]
  • 1586 – Simon Stevin publishes De Beghinselen des Waterwichts ("Principles on the weight of water") on hydrostatics. He first details the hydrostatic paradox.[9]
  • 1596 – Galileo Galilei produces the first (Galileo) thermometer.[1]

17th century

18th century

1832 steam engine based on James Watt's principles.
  • 1713 – Antoine Parent introduces the concept of shear stress.[12]
  • 1714 – Daniel Gabriel Fahrenheit develops the mercury-in-glass thermometer along the Fahrenheit temperature scale.[1]
  • 1718–1719 – James Jurin writes the law of capillary action, known as Jurin's law.
  • 1727 – Leonhard Euler introduces linear elasticity and the Young's modulus.[12]
  • 1732 – Henri Pitot discovers how to measure the pressure from the speed of a fluid using a Pitot tube.[13]
  • 1738 – Daniel Bernoulli publishes Hydrodynamica discussing the mathematical relation between pressure and velocity of fluids according to Bernoulli's principle.[1]
  • 1742 – Anders Celsius designs a thermometer with the Celsius scale.
  • 1744 – Euler introduces the concept of deformation and strain.[12]
  • 1747 – Jean le Rond d'Alembert's formula for the solutions of the wave equation in a string gets published.[14]
  • 1752 – D'Alembert show an inconsistency of treating fluids as inviscid incompressible fluids, known as d'Alembert's paradox.
  • 1757 – Euler introduces the Euler equations of fluid dynamics for incompressible and non-viscous flow. He also introduces the mathematical model for buckling.[12]
  • 1764 – James Watt develops his steam water condenser leading to efficient steam engines.[1]
  • 1765 – Jean-Charles de Borda experiments with whirling arm experiments. He corrects the available theories of air friction.[15]
  • 1766 – de Borda publishes "Mémoire sur l’Écoulement des Fluides par les Orifices des Vases" on hydraulics and resistance of fluid through orifices. He comes up with Borda–Carnot equation.
  • 1768 – Antoine de Chézy provides a semi-empirical formula for resistance of open channel flow, described by Chézy formula.[1]
  • 1775 – Pierre-Simon Girard invents the water turbine.[1]
  • 1776 – Charles Bossut, supervised by the Marquis de Condorcet and d'Alembert, publishes Nouvelles expériences sur la resistance de fluides, a report on a series experiments to test currents theories of hydraulics.
  • 1775-76 – Pierre-Simon Laplace introduces the mathematical theory for tidal forces on oceans.[16]
  • 1779 – Pierre-Louis-Georges du Buat publishes Principes de l'hydraulique ("Principles of hydraulics"), with semiempirical equations for the flow of water through pipes and open channels.[17][18]
  • 1780 – Jacques Charles discover a gas law that describes the relationship between temperature and volume, given by Charles's law.
  • 1782 – The Montgolfier brothers invent the hot air balloon.[1]
  • 1785 – First theories of friction are introduced by Charles-Augustin de Coulomb.[19]
  • 1787 – Ernst Chladni, publishes his experiments on vibrational modes of thin solid surfaces, describing the Chladni patterns created using a violin bow, based on previous experiments by Hooke.
  • 1797 – Giovanni Battista Venturi discovers the Venturi effect.[20]
  • 1799 – George Cayley introduces modern fixed wing-machines and identifies three important factors for flying machines: thrust, lift, drag, and weight.

19th century

An F/A-18C Hornet breaks the sound barrier in the skies. Description of fluid at supersonic speeds were explored at the end of the 19th century before the development of manned airplanes.

20th century

Schlieren photograph showing the thermal convection plume rising from an ordinary candle in still air. Precise mathematical theories of turbulence were not invented until the 20th century.

21st century

See also

  • History of aviation

References

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  2. ^ Needham, Joseph (1959). Science and Civilization in China, Volume 3: Mathematics and the Sciences of the Heavens and the Earth. Cambridge: Cambridge University Press. pp. 626–635. Bibcode:1959scc3.book.....N.
  3. ^ Dewey, James; Byerly, Perry (February 1969). "The early history of seismometry (to 1900)". Bulletin of the Seismological Society of America. 59 (1): 183–227.
  4. ^ Agnew, Duncan Carr (2002). "History of seismology". International Handbook of Earthquake and Engineering Seismology. International Geophysics. 81A: 3–11. Bibcode:2002InGeo..81....3A. doi:10.1016/S0074-6142(02)80203-0. ISBN 9780124406520.
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    • That Wenham and Browning were attempting to build a wind tunnel is briefly mentioned in: Sixth Annual Report of the Aeronautical Society of Great Britain for the Year 1871, p. 6. From p. 6: "For this purpose [viz, accumulating experimental knowledge about the effects of wind pressure], the Society itself, through Mr. Wenham, had directed a machine to be constructed by Mr. Browning, who, he was sure, would take great interest in the work, and would give to it all the time and attention required."
    • In 1872, the wind tunnel was demonstrated to the Aeronautical Society. See: Seventh Annual Report of the Aeronautical Society of Great Britain for the Year 1872, pp. 6–12.
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