Sunday, 8 September 2024

On This Day in Math - September 8

 



We Must Know, We Will Know

~David Hilbert


The 251st day of the year; 251 is a prime number that is also the sum of three consecutive primes (79 + 83 + 89) and of seven consecutive primes (23 + 29 + 31 + 37 + 41 + 43 + 47). In addition, it is the smallest integer that can be the sum of three cubes in two different ways. 251 =23+ 33+63 = 13+53+53
and there are 251 primes less than 1600.*@MathYearRound

and wow: The 251st Fibonacci number (12776523572924732586037033894655031898659556447352249) has a sum of digits equal to 251. *jim wilder ‏@wilderlab

251 is the largest prime day year that is the concatenation of two squares.



EVENTS


1636 The General Court of Massachusetts Bay appropriated 400 Pounds for the "creation of a college in New Towne." Originally named Cambridge College, it was renamed in 1638 in honor of Reverend John Harvard who bequeathed the college about 800 pounds, and 300 books. The first building was called the "Indian College" and was erected in 1637. #FFF 




1679 Leibniz writes to Huygens with a letter and essay which describes his analysis “situs”, a precursor of vector analysis,  *A history of vector analysis ,Michael J. Crowe; pg 3

His universal mathematics would later blossom into the symbolic logic of George Boole, and still later, in 1910, into the great Principia Mathematica of Whitehead and Russell. 


1829  "August Kekulé, a German chemist, was born Sep. 7, 1829. In the early 1860s, Kekulé was writing a textbook of organic chemistry, and he was trying to work out the structure for what had recently been designated the 'aromatic compounds', which included benzene and its derivatives (not all molecules that are aromatic to the nose are aromatic to the chemist, and vice versa). Benzene was a particular problem. Its chemical formula is C6H6, meaning one benzene molecule has 6 carbon atoms and 6 hydrogen atoms, and it is quite stable. The stability was the surprise, because normally 6 carbon atoms would have gobs of hydrogen atoms bonded to them. Methane, for example, is a hydrocarbon, like benzene, but its chemical formula is CH4, meaning its one carbon atom is able to bond to 4 hydrogen atoms. So why is the benzene molecule satisfied with only 1 hydrogen atom for each of its carbon atoms?

In 1862, Kekulé had an idea. Suppose the 6 carbon atoms form a circle, or a six-sided ring, so that the carbon atoms use most of their bonds on each other. The six empty bonds would then be occupied by the 6 hydrogen atoms, sticking out from the ring. The most attractive feature of the concept was that one could now see how benzene derivatives such as toluene and phenol might form, by replacing one of the hydrogen atoms with a different group of atoms, such as a methyl group (as in toluene) or a hydroxyl radical (as in phenol). A 1979 German postage stamp depicts both Kekulé and his benzene ring, with its alternating single and double bonds (first image).

Kekulé's proposed structure was brilliant, but its fame in the history of science stems from the way Kekulé came up with his brainstorm. At a meeting organized in 1890 to celebrate the 25th anniversary of the benzene announcement (his paper was published in 1865), Kekulé told the gathering that he got the idea of the ring from a daydream in which he saw a snake biting its tail. He literally dreamed up the benzene ring. We don't know if it actually happened this way, but most historians see no reason to doubt it, since the account came from Kekulé's own mouth and was delivered to a gathering of his peers. Others, however, are skeptical, and wonder if Kekulé were not just trying to buttress his claim for priority in the discovery of the benzene ring."  *Linda Hall org




1844 The term ABELIAN INTEGRAL seems to have first occurred in a letter of Sept. 8, 1844, from William Henry Fox Talbot: "What is the definition of an Abelian Integral? for it appears to me that most integrals possess the Abelian property." The letter was addressed to John Frederick William Herschel, who, in his reply of Sept. 13, 1844, wrote: "I suppose the most general definition of an Abelian Integral might be taken to be this that between +(x) and +(φ(x)) there shall subsist an algebraical relation between several such functions." [The Talbot letters are available here *Jeff Miller Web site

The theory of abelian integrals originated with a paper by Niels Henrik Abel published in 1841. This paper was written during his stay in Paris in 1826 and presented to Augustin-Louis Cauchy in October of the same year. This theory, later fully developed by others,[2] was one of the crowning achievements of nineteenth century mathematics and has had a major impact on the development of modern mathematics. 



In 1854, Dr. John Snow removed the handle of the Broad Street water pump in London, thus effectively halting further spread of cholera. He had mapped the outbreaks, and thus suspected contamination of this community source of water. He was correct in this, one of the most symbolic gestures in the history of public health. Within days after the pump handle was removed, new cases of illness had ceased. Site investigation showed raw sewage from a leaking sewage cesspool that had contaminated the well water. Thus Snow, who was already a celebrated anaesthetist became a pioneer of epidemiology. The "John Snow" pub now stands beside the pink granite slab marking the site of the original pump.*TIS

A replica pump was installed in 1992 at the site of the 1854 pump. Every year the John Snow Society holds "Pumphandle Lectures" on subjects of public health. Until August 2015, when the pump was removed due to redevelopment, they also held a ceremony here in which they removed and reattached the pump handle to pay tribute to Snow's historic discovery. The original location of the historic pump is marked by a red granite paver. In addition, plaques on the John Snow pub at the corner describe the significance of Snow's findings at this site





1930 Hilbert’s radio broadcast in Konigsberg.  At the age of 68, Hilbert retired to conform with regulations at Gottingen.  It was the second great speech of his career. It contains the famous phrase “Wir mussen wissen. Wir werden wissen.” (We must know, we will know). These optimistic words are inscribed over Hilbert’s grave in Gottingen. A recording is available in the Gedenkband. Emil du Bois-Reymond had maintained that the nature of matter, and human consciousness would always remain unknowable. Hilbert refuted this pessimistic view with a spirit of scientific optimism.

We ought not believe those who today, with a philosophical air and a tone of superiority, prophesy the decline of culture, and are smug in their acceptance of the ignorabimus principle.... in place of this foolish Ignorabimus, let our resolution be, to the contrary: "We must know, we will know."


You can hear the four minute address, and read the English translation at the MAA website.


1966  In case someone forgot, The first episode of Star Trek airs.  Star Trek, the science fiction television series, was created by Gene Roddenberry. Set in the 23rd century, the original Star Trek follows the adventures of the starship Enterprise and its crew, led by Captain James T. Kirk (played by William Shatner), his First Officer Mr. Spock (Leonard Nimoy), and his Chief Medical Officer Leonard McCoy (DeForest Kelley). Star Trek was not an immediate hit and was initially broadcast for only three seasons (a total of 79 episodes). Many of the technologies shown in the series, including the “Tricorder” and personal communicator, influenced a generation of technologists working in portable communications and computing. The last episode aired on September 2, 1969.

*CHM


In 2040, the first visible conjunction during the 21st century of the crescent Moon with the five naked-eye visible planets - Mercury, Venus, Mars, Jupiter and Saturn - will occur. They will be seen clustered within a small distance of each other in the early evening sky, well east of the sun. When a similar grouping happened in the sky on 5 May 2000, the Moon and the same five planets were lost to view because of the glare of the Sun from among them.*TIS 






BIRTHS


1157 Alexander Neckam (8 Sep, 1157 - 31 Mar, 1217) English schoolman and scientist, who was a theology instructor at Oxford. Neckam then studied and lectured in Paris. In 1186, he returned to England, and in 1213 became abbot at Cirencester, Gloucestershire. In Paris, Neckam had learned of the mariner's compass, which the Chinese had been using for at least two centuries. In a book De utensilibus ("On Instruments") he wrote about 1180 was the first reference to the magnetic compass as being in use among the Europeans. (the Chinese encylopaedist Shen Kuo gave the first clear account of suspended magnetic compasses a hundred years earlier in 1088 AD with his book Mengxibitan, or Dream Pool Essays) His De naturis rerum ("On the Natures of Things"), a two-part introduction to a commentary on the Book of Ecclesiastes, is a miscellany of scientific information at that time novel in western Europe but already known to Greek and Muslim savants. *TIS




1584 Gregorius Saint Vincent born. His Opus geometricum (1647) contains the most beautiful frontispiece of any mathematics text. In this work, Gregorius was the first to develop the theory of the geometric series and also the first to show that the area under a hyperbola is a logarithm. *VFR (in the frontispiece he claims to have squared the circle) The engraved frontispiece shows sunrays inscribed in a square frame being arranged by graceful angels to produce a circle on the ground: 'mutat quadrata rotundis'. There was uneasiness in the learned world because no one in that world still believed that under the specific Greek rules the quadrature of a circle could possibly be effected, and few relished the thought of trying to locate an error, or errors, in 1200 pages of text. Four years later, in 1651, Christiaan Huygens found a serious defect in the last book of 'Opus geometricum', namely in Proposition 39 of Book X, on page 1121. This gave the book a bad reputation.*SAU


1588 Marin Mersenne born (8 September 1588 – 1 September 1648) was a French theologian, philosopher, mathematician and music theorist, and did important work in acoustics. Often called the center of the scientific world in the early 17th century for his communication with and between many of the most prominent scientific minds of the period. He also performed extensive experiments to determine the acceleration of falling objects by comparing them with the swing of pendulums, reported in his Cogitata Physico-Mathematica in 1644. He was the first to measure the length of the seconds pendulum, that is a pendulum whose swing takes one second, and the first to observe that a pendulum's swings are not isochronous as Galileo thought, but that large swings take longer than small swings. *Wik

In mathematics, a Mersenne prime is a prime number that is one less than a power of two. That is, it is a prime number of the form M(n) = 2^n − 1 for some integer n. They are named after Marin Mersenne who studied them in the early 17th century. If n is a composite number then so is 2^n − 1. Therefore, an equivalent definition of the Mersenne primes is that they are the prime numbers of the form M(p) = 2^p − 1 for some prime p.


The exponents n which give Mersenne primes are 2, 3, 5, 7, 13, 17, 19, 31, ... (sequence A000043 in the OEIS) and the resulting Mersenne primes are 3, 7, 31, 127, 8191, 131071, 524287, 2147483647, ... (sequence A000668 in the OEIS).

Below A Time Magazine photo when the 46th Mersenne prime was included in the best inventions of 2008.  The 45th MP had also been discovered (or invented?) that year as well.





1634 Hendrik van Heuraet (8 September 1634; Haarlem,Netherlands - 1600?) The dates of his birth and death are unclear as little is known of him. The birthdate is estimated from the date papers were signed for his inheritance, which had to happen on (or after) he turned twenty-one. His mother was Maria de Coninck who came from Oude Rijn, a town near to Leiden. His father was Abraham van Heuraet, an immigrant from Hamburg who had settled in Haarlem where he was a cloth merchant.
It is known is that he went with Hudde to the Protestant university in Saumur, a town on the river Loire in western France, in 1658. From Saumur he wrote a letter to van Schooten entitled Epistola de transmutatione curvarum linearum in rectas. Van Schooten published this letter in 1659. In it he gives a rectification method which reduces, for any arbitrary algebraic curve, the rectification to a quadrature of an associated curve, that is to computing the area under an associated curve. This was particularly important since at this time mathematicians believed that it was not possible to compare the length of a curved arc with a straight line segment. Van Heuraet's breakthrough is therefore significant in the development of mathematics. In particular, in the paper, he computed the integral ∫ √(1+y' 2) dx and applied his methods to the parabola. His methods of rectification of curves became part of a more general theory by Fermat which was produced independently and at about the same time. William Neile, independently of van Heuraet, had previously found the arc length of an algebraic curve in 1657 when he rectified the cubical parabola.
van Heuraet's work led to an argument with Huygens over a priority claim, suggesting that Huygens recognized the importance of the work. (most historians find little reason to side with Huygens in this claim) *SAU




1671 Pierre Polinière (8 September 1671, Coulonces, France - 9 February 1734, Coulonces, France) was an early investigator of electricity and electrical phenomena, notably "barometric light", a form of gas-discharge light, which suggested the possibility of electric lighting. He also helped to introduce the scientific method in French universities.*Wik





1861 Percy John Heawood (8 September 1861 - 24 January 1955 Durham, England) was a British mathematician. He devoted essentially his whole working life to the four color theorem and in 1890 he exposed a flaw in Alfred Kempe's proof, that had been considered as valid for 11 years. With the four color theorem being open again he established the five color theorem instead. The four color theorem itself was finally established by a computer-based proof in 1976. *Wik




1903 Cadambur Tiruvenkatachari Rajagopal (8 September 1903 – 25 April 1978) was an Indian mathematician.  Rajagopal was born in Triplicane, Madras, India. He was the first son of Tiruvenkatachari and Padmammal. He had two younger brothers, C.T. Venugopal, a distinguished civil servant, and C. T. K. Chari. They also had a young sister, Kamala. He studied at Presidency College and graduated with an Honours in mathematics in 1925. He was involved in the clerical service and then taught mathematics at Annamalai University. Rajagopal taught mathematics at Madras Christian College from 1931 to 1951. He joined the Ramanujan Institute for Advanced Study in Mathematics in 1951.

Collaborating on the teaching of conic sections, Rajagopal and Vaniyambadi Rajagopala Srinivasaraghavan wrote a textbook, An Introduction to Analytical Conics, that was published in 1955 by Oxford University Press in India. A reviewer noted "a pleasing feature is the frequent reference to the history of the subject", and "the authors pursue the theory in great detail, proving a large number of subsidiary results."

Rajagopal became Director of the Ramanujan Institute for Advanced Study in Mathematics in 1955. He helped the Institute to become India's leading mathematics research centre. The Institute is now associated with the University of Madras, after it was merged with the Department of Mathematics at the University in 1967.

Rajagopal conducted research on sequences, series, summability, and published more than 80 papers but is most noted for his work in the area of generalising and unifying Tauberian theorems. He also did research in many other mathematical topics.

Rajagopal also conducted research in the history of medieval Indian mathematics. He showed that the series for arctan x discovered by James Gregory and those for sin x and cos x discovered by Isaac Newton were known to the Hindu mathematicians 150 years earlier. He identified Madhava as the first discoverer of these series.



1918 Sir Derek Harold Richard Barton FRS FRSE (8 September 1918 – 16 March 1998) was an English organic chemist and Nobel Prize laureate for 1969.

Barton was an English chemist, a joint recipient (with Norwegian Odd Hassel) of the 1969 Nobel Prize for Chemistry for research that helped establish conformational analysis (the study of the 3-D geometric structure of complex molecules). In a brief paper in Experienta entitled “The Conformation of the Steroid Nucleus” (1950), Barton showed that organic molecules in general and steroid molecules in particular could be assigned a preferred conformation based on work of chemical physicists, in particular by Odd Hassel. Conformational analysis is useful in the elucidation of configuration, in the planning of organic synthesis, and in the analysis of reaction mechanisms. It is fundamental to a complete understanding of enzymatic processes. *TiS




1919 Albert H. Bowker, (8 September 1919 - 20 January 2008) Born in Winchendon MA. He received a BS in Math from MIT in 1941 and a PhD in Math-Stat from Columbia in 1949. Dr. Bowker served as founding Chairman of the Stat Dept at Stanford, being at Stanford until 1961. In 1963, he became Chancellor of the expanding City University of New York (CUNY), returning to California in 1971 to become Chancellor of the University of California at Berkeley.
Dr. Bowker was President of the Institute of Mathematical Statistics (IMS) in 1962 and President of the American Statistical Association (ASA) in 1964.
For an interesting and informative interview with Dr. Bowker conducted by Stanford's Ingram Olkin in 1987 in which Bowker told of his many interactions with well-known contributors to Statistics (including one with Fisher with reservations because of Neyman-Pearson theory) go here. *David Bee




1927  Marguerite Straus Frank (born September 8, 1927) is a French-American mathematician who is a pioneer in convex optimization theory and mathematical programming.  

She is famed both for her remarkable new discoveries of simple Lie algebras, and her solution to the problem of maximizing a concave quadratic function, now known as the Frank-Wolfe algorithm. This algorithm is used widely in traffic models to assign routes to strategic models such as those using Saturn (software).

*SAU




DEATHS



1637 Robert Fludd, also known as Robertus de Fluctibus (17 January 1574; Bearsted, Kent, UK – 8 September 1637; London, UK), was a prominent English Paracelsian physician. He is remembered as an astrologer, mathematician, cosmologist, Qabalist and Rosicrucian apologist.
Fludd is best known for his compilations in occult philosophy. He had a celebrated exchange of views with Johannes Kepler concerning the scientific and hermetic approaches to knowledge.
Between 1598 and 1604, Fludd studied medicine, chemistry and hermeticism on the European mainland. His itinerary is not known in detail. On his own account he spent a winter in the Pyrenees studying theurgy with the Jesuits.

On his return to England, Fludd entered Christ Church, Oxford. In 1605 he graduated M.B. and M.D. He then moved to London, settling in Fenchurch Street, and making repeated attempts to enter the College of Physicians. Fludd encountered problems with the College examiners, both because of his unconcealed contempt for traditional medical authorities, and because of his attitude. After at least six failures, he was admitted in 1609. Subsequently both his career and his standing in the College took a turn very much for the better. He was on good terms with Sir William Paddy. Fludd was one of the first to support in print the theory of the circulation of the blood of the College's William Harvey. To what extent Fludd may have actually influenced Harvey is still debated, in the context that Harvey's discovery is hard to date precisely. The term "circulation" was certainly ambiguous at that time
Fludd's works are mainly controversial. In succession he defended the Rosicrucians against Andreas Libavius, debated with Kepler (claiming the hermetic or "chemical" approach is deeper than the mathematical), argued against French natural philosophers including Gassendi and Mersenne, and engaged in the discussion of the weapon-salve, a form of sympathetic magic, current in the 17th century in Europe, whereby a remedy was applied to the weapon that had caused a wound in the hope of healing the injury it had made. (I suspect much of the success was having the doctors focus on the weapon rather than infecting the wounded body). *Wik




1882 Joseph Liouville (24 Mar 1809, 8 Sep 1882) French mathematician who discovered transcendental numbers (those which are not the roots of algebraic equations having rational coefficients), and that there are infinitely many of them. He also did work in real and complex analysis, number theory, and differential geometry. His name is remembered in the Sturm-Liouville theory of differential equations that generalizes Joseph Fourier's ideas, and are important in mathematical physics. He studied celestial mechanics. Liouville founded in 1836, and edited for nearly four decades, the Journal de Mathématique which remains a leading French mathematical publication. He edited and published (1843) the manuscripts left behind upon the untimely death of Evariste Galois 22 years earlier.*TIS Liouville was one of Lord Kelvin's mathematical heros, and he once stopped a lecture in Glascow to ask his students, "Do you know what a mathematician is?" He then wrote on the blackboard the equation  



and, pointing to the board stated, A mathematician is one to whom that is as obvious as twice two are four is to you. Liouville was a mathematician." *Walter Gratzer, Eurekas and Euphorias, pg 21




1894 Hermann Ludwig Ferdinand von Helmholtz (31 Aug 1821, 8 Sep 1894) German scientist who contributed much to physiology, optics, electrodynamics, mathematics, and meteorology, including the law of the conservation of energy (1847). He also developed thermodynamics, in particular introducing concept of free energy. In 1850, he measured the speed of a nerve impulse and, in 1851, invented the ophthalmoscope. He discovered the function of the cochlea in the inner ear and developed Thomas Young's theory of colour vision (published 1856). His study of muscle action led him to formulate a much more accurate theory concerning the conservation of energy than earlier proposed by Julius Mayer and James Joule. *TIS




1867 Derrick Norman Lehmer (27 July 1867, Somerset, Indiana, USA — 8 September 1938 in Berkeley, California, USA) was an American mathematician and number theorist.
In 1903, he presented a factorization of Jevons' number (8,616,460,799) at the San Francisco Section of the American Mathematical Society, December 19, 1903.
He published tables of prime numbers and prime factorizations, reaching 10,017,000 by 1909 (In Number Theory and Its History, Ore calls this the "best factor table now (1948) available"). He developed a variety of mechanical and electro-mechanical factoring and computational devices, such as the Lehmer sieve, built with his son Derrick Henry Lehmer.
He is also known for a reversible algorithm that assigns a Lehmer code to every permutation of size n. *SAU



1963 Robert Bell (15 Jan 1876, 8 Sept 1963) graduated from Glasgow University. He was appointed to a professorship at the University of Otago in New Zealand. He worked in Geometry and was editor of the EMS Proceedings for several years. *SAU


1969 Gordon Thomas Whyburn (January 7 1904 , September 8 1969) American mathematician who worked on the topology of point sets. *Wik


1981 Hideki Yukawa (23 Jan 1907, 8 Sep 1981) Japanese physicist who shared the 1949 Nobel Prize for Physics for "his prediction of the existence of mesons on the basis of theoretical work on nuclear forces." In his 1935 paper, On the Interaction of Elementary Particles*, he proposed a new field theory of nuclear forces that predicted the existence of the previously unknown meson. Mesons are particles heavier than electrons but lighter than protons. One type of meson was subsequently discovered in cosmic rays in 1937 by American physicists, encouraging him to further develop meson theory. From 1947, he worked mainly on the general theory of elementary particles in connection with the concept of the "non-local" field. He was the first Japanese Nobel Prize winner.*TIS Recently K Ken Nakamura ‏@KKenNakamura sent me a tweet that said,"In my generation every Japanese knew the name Yukawa; in fact Yukawa was a synonym with genius."




Credits :
*CHM=Computer History Museum
*FFF=Kane, Famous First Facts
*NSEC= NASA Solar Eclipse Calendar
*RMAT= The Renaissance Mathematicus, Thony Christie
*SAU=St Andrews Univ. Math History
*TIA = Today in Astronomy
*TIS= Today in Science History
*VFR = V Frederick Rickey, USMA
*Wik = Wikipedia
*WM = Women of Mathematics, Grinstein & Campbell

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