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Daniel Bernoulli

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Daniel Bernoulli

Daniel Bernoulli
Daniel Bernoulli
Born 8 February 1700
Groningen, Dutch Republic
Died 17 March 1782 (aged 82)
Basel, Republic of the Swiss
Known for Bernoulli's Principle,
early Kinetic theory of gases,

Daniel Bernoulli FRS (; Swiss ;[1] 8 February 1700 – 17 March 1782) was a Swiss mathematician and physicist and was one of the many prominent mathematicians in the Bernoulli family. He is particularly remembered for his applications of mathematics to mechanics, especially fluid mechanics, and for his pioneering work in probability and statistics. His name is commemorated in the Bernoulli principle, a particular example of the conservation of energy, which describes the mathematics of the mechanism underlying the operation of two important technologies of the 20th century: the carburetor and the airplane wing.

Early life

Frontpage of Hydrodynamica (1738)

Daniel Bernoulli was born in Groningen, in the Netherlands, into a family of distinguished mathematicians.[2] The Bernoulli family came originally from Antwerp, at that time in the Spanish Netherlands, but emigrated to escape the Spanish persecution of the Huguenots. After a brief period in Frankfurt the family moved to Basel, in Switzerland.

Daniel was the son of Johann Bernoulli (one of the "early developers" of calculus),[2] nephew of Jacob Bernoulli (who "was the first to discover the theory of probability"),[2] and older brother of Johann II.  Daniel Bernoulli was described by W. W. Rouse Ball as "by far the ablest of the younger Bernoullis".[3] He is said to have had a bad relationship with his father. Upon both of them entering and tying for first place in a scientific contest at the University of Paris, Johann, unable to bear the "shame" of being compared as Daniel's equal, banned Daniel from his house. Johann Bernoulli also plagiarized some key ideas from Daniel's book Hydrodynamica in his own book Hydraulica which he backdated to before Hydrodynamica. Despite Daniel's attempts at reconciliation, his father carried the grudge until his death.[4]

When Daniel was seven, his younger brother Johann II Bernoulli was born. Around schooling age, his father, Johann, encouraged him to study business, there being poor rewards awaiting a mathematician. However, Daniel refused, because he wanted to study mathematics. He later gave in to his father's wish and studied business. His father then asked him to study in medicine, and Daniel agreed under the condition that his father would teach him mathematics privately, which they continued for some time.[4] Daniel studied medicine in Basel, Heidelberg, and Strasbourg, and earned a PhD in anatomy and botany in 1721.[5]

He was a contemporary and close friend of Leonhard Euler. He went to St. Petersburg in 1724 as professor of mathematics, but was very unhappy there, and a temporary illness in 1733 gave him an excuse for leaving St. Petersberg.[4] He returned to the University of Basel, where he successively held the chairs of medicine, metaphysics, and natural philosophy until his death.[6]

In May, 1750 he was elected a Fellow of the Royal Society.[7]

Mathematical work

His earliest mathematical work was the Exercitationes (Mathematical Exercises), published in 1724 with the help of Goldbach. Two years later he pointed out for the first time the frequent desirability of resolving a compound motion into motions of translation and motion of rotation. His chief work is Hydrodynamica, published in 1738; it resembles Joseph Louis Lagrange's Mécanique Analytique in being arranged so that all the results are consequences of a single principle, namely, conservation of energy. This was followed by a memoir on the theory of the tides, to which, conjointly with the memoirs by Euler and Colin Maclaurin, a prize was awarded by the French Academy: these three memoirs contain all that was done on this subject between the publication of Isaac Newton's Philosophiae Naturalis Principia Mathematica and the investigations of Pierre-Simon Laplace. Bernoulli also wrote a large number of papers on various mechanical questions, especially on problems connected with vibrating strings, and the solutions given by Brook Taylor and by Jean le Rond d'Alembert.[3]

Together Bernoulli and Euler tried to discover more about the flow of fluids. In particular, they wanted to know about the relationship between the speed at which blood flows and its pressure. To investigate this, Daniel experimented by puncturing the wall of a pipe with a small open ended straw and noted that the height to which the fluid rose up the straw was related to fluid's pressure in the pipe.[8]

Soon physicians all over Europe were measuring patients' blood pressure by sticking point-ended glass tubes directly into their arteries. It was not until about 170 years later, in 1896 that an Italian doctor discovered a less painful method which is still in use today. However, Bernoulli's method of measuring pressure is still used today in modern aircraft to measure the speed of the air passing the plane; that is its air speed.

Taking his discoveries further, Daniel Bernoulli now returned to his earlier work on Conservation of Energy. It was known that a moving body exchanges its kinetic energy for potential energy when it gains height. Daniel realised that in a similar way, a moving fluid exchanges its kinetic energy for pressure. Mathematically this law is now written:

\tfrac12 \rho u^2 + P = \text{constant}

where P is pressure, ρ is the density of the fluid and u is its velocity. A consequence of this law is that if the velocity increases then the pressure falls. This is exploited by the wing of an aeroplane which is designed to create an area above its surface where the air velocity increases. The pressure in this area is lower than that under the wing, so the wing is pushed upwards by the relatively higher pressure under the wing.


Daniel Bernoulli was also the author in 1738 of Specimen theoriae novae de mensura sortis (Exposition of a New Theory on the Measurement of Risk),[9] in which the St. Petersburg paradox was the base of the economic theory of risk aversion, risk premium and utility.[10]

One of the earliest attempts to analyze a statistical problem involving censored data was Bernoulli's 1766 analysis of smallpox morbidity and mortality data to demonstrate the efficacy of vaccination.[11]


In Hydrodynamica (1738) he laid the basis for the kinetic theory of gases, and applied the idea to explain Boyle's law.[3]

He worked with Euler on elasticity and the development of the Euler-Bernoulli beam equation.[12] Bernoulli's principle is of critical use in aerodynamics.[6]

According to Léon Brillouin, the principle of superposition was first stated by Daniel Bernoulli in 1753: "The general motion of a vibrating system is given by a superposition of its proper vibrations."[13]

See also


  1. ^ Mangold, Max (1990) Duden — Das Aussprachewörterbuch. 3. Auflage. Mannheim/Wien/Zürich, Dudenverlag.
  2. ^ a b c Rothbard, Murray. Daniel Bernoulli and the Founding of Mathematical Economics, Mises Institute (excerpted from An Austrian Perspective on the History of Economic Thought)
  3. ^ a b c  
  4. ^ a b c  . (1998)
  5. ^ Anderson, John David (1997). A History of Aerodynamics and its Impact on Flying Machines. New York, NY: Cambridge University Press.  
  6. ^ a b [Anon.] (2001) "Daniel Bernoulli", Encyclopaedia Britannica
  7. ^ "Library and Archive Catalogue". Royal Society. Retrieved 13 December 2010. 
  8. ^ The Turner Collection, Keele University, includes Bernoulli's diagram to illustrate how pressure is measured. See also part of Bernoulli's original Latin explanation.
  9. ^ English translation in Bernoulli, D. (1954). "Exposition of a New Theory on the Measurement of Risk" (PDF). Econometrica 22 (1): 23–36.  
  10. ^ Stanford Encyclopedia of Philosophy: "The St. Petersburg Paradox by R. M. Martin
  11. ^ reprinted in Blower, S; Bernoulli, D (2004). "An attempt at a new analysis of the mortality caused by smallpox and of the advantages of inoculation to prevent it" (PDF). Reviews in medical virology 14 (5): 275–88.  
  12. ^  
  13. ^ Brillouin, L. (1946). Wave propagation in Periodic Structures: Electric Filters and Crystal Lattices, McGraw–Hill, New York, p. 2.


Original entry based on the public domain Rouse History of Mathematics

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