Pat'sBlog

Sunday, 6 April 2025

On This Day in Math - April 6

Abel Statue at Univ of Oslo, *Monuments on Mathematicians

Niels Henrik Abel
1802 - 1829
mathematician, famed due to
epoch-making works in
theory of equations, [theory of] infinite series
and elliptic functions

Science can amuse and fascinate us all, but it is engineering that changes the world.

~Isaac Asimov

The 96th day of the year; 96 is the smallest number that can be written as the difference of 2 squares in 4 ways. *What's So Special About This Number?
(students are encouraged to find them all...Is there a smaller number that can be so expressed in 3 ways?)

The sum of 96 consecutive squared integers is a square number ( $x^2 + (x+1)^2 + (x+2)^2 +(x+3)^2 + \dotsm + (x+95)^2 = y^2$ ) can be solved with eight sets of 96 consecutive year days. One solution is $13^2 + 14^2 + \dotsm + 108^2 = 652^2$ *Ben Vitale

Ninety Six, South Carolina. There is much confusion about the mysterious name, "Ninety-Six," and the true origin may never be known. Speculation has led to the mistaken belief that it was 96 miles to the nearest Cherokee settlement of Keowee; to a counting of creeks crossing the main road leading from Lexington, SC, to Ninety-Six; to an interpretation of a Welsh expression, "nant-sych," meaning "dry gulch." Pitcher Bill Voiselle of the Boston Braves was from Ninety Six, South Carolina, and wore uniform number 96.

There are five numbers less than 100 that have 12 divisors, 60, 72, 84,90, and 96 . Of the ten neighboring numbers on each side, seven are prime. The other three are semi-primes, with two prime factors. Is it generally true that highly composite numbers are more likely to occur with prime neighbors?

96 is a strobogrammatic number, rotated by 180 degrees, it is the same. Numbers like 81 that rotate to form a different number are often called ambigrams.

Several more number facts about 96 and other numbers at the Extended Number Facts pages.

EVENTS

648 B.C. First Greek record of a total solar eclipse is made. See June 4, 780 B.C., and October 13, 2128 B.C. *VFR

"Zeus, the father of the Olympic Gods, turned mid-day into night,
hiding the light of the dazzling Sun; and sore fear came upon men."
"Nothing can be surprising any more or impossible or miraculous,
now that Zeus, father of the Olympians has made night out of noonday,
hiding the bright sunlight, and . . . fear has come upon mankind.
After this, men can believe anything, expect anything.
~ Archilochus, Greek poet

*Ted Pedas, Eclipse History web site.

1741 Euler's First paper on partitions is given. (This may be where generating functions are first used). On September 4, 1740, Philip Naudé the younger (1684-1747) wrote Euler from Berlin to ask “how many ways can the number 50 be written as a sum of seven different positive integers?” The problem seems to have captured Euler’s imagination. Euler gave his first answer on April 6, 1741, in a paper he read at the weekly meeting of the St. Petersburg Academy. That paper was published ten years later and is number 158 on Eneström’s index. (Ed Sandifer, "How Euler Did It") [E158 can be downloaded in English from Euler Project]

Euler answered two questions posed by Philip Naud´e and stated what became known as the pentagonal number theorem.

In 1674 Leibniz had written to J. Bernoulli asking about “divulsions of integers,” now called partitions. A basic problem is determining the number p(n) of ways that a positive integer n can be written as the sum of positive integers; for example, p(4) = 5, corresponding to the sums 4, 3 + 1, 2 +2, 2 + 1 + 1 and 1 + 1 + 1 + 1. *Brian Hopkins and Robin Wilson

1761 the Royal Society agreed to send Nevil Maskelyne to the island of St Helena to observe a transit of Venus which would take place on 6 June 1761. Maskelyne had earlier proposed that the same expedition should try to measure the parallax of the star Sirius.

This Venus transit was important since accurate measurements would allow the distance from the Earth to the Sun to be accurately measured and the scale of the solar system determined. He set sail on the ship Prince Henry on 18 January 1761. During the voyage he experimented with the lunar position method of determining longitude using the lunar tables produced by Tobias Mayer. He arrived in St Helena on 6 April 1761 in plenty of time to find a good site for observing and to set up his instruments. Sadly, the 6 June was cloudy and he was unable to make measurements of the transit. He spent several months on St Helena trying to compute the parallax of Sirius but eventually decided that his instruments were faulty. Disappointed, Maskelyne set sail for England on the ship Warwick in February 1762. Reaching Plymouth on 15 May, he went back to Chipping Barnet, where he was a curate, and worked on publishing a book. He published the lunar distance method for determining longitude in The British Mariner's Guide (1763) where he also included Tobias Mayer's tables.

1841 William Thompson, the future Lord Kelvin, age 16, was formally entered at St. Peter's (or Peterhouse) Cambridge as a student of the college. His father, Professor James Thompson, may have urged him to enter Peterhouse because of the college's mathematical coach, Hopkins, whom Professor Kelvin admired. It would become the college of choice for many young Scots for a while. Tait went there, and Maxwell began there but later transferred to Trinity. *Silvanus Phillips Thompson, The life of Lord Kelvin

1846 In early 1846 at the age of 14, Maxwell wrote a paper on ovals. In this work he generalised the definition of an ellipse by defining the locus of a point where the sum of m times the distance from one fixed point plus n times the distance from a second fixed point is constant. If m = n = 1 then the curve is an ellipse. Maxwell also defined curves where there were more than two foci. This became his first paper On the description of oval curves, and those having a plurality of foci which was read to the Royal Society of Edinburgh on 6 April 1846. These ideas were not entirely new as Descartes had defined such curves before but the work was remarkable for a 14 year old.

1852, Edward Sabine announced that the 11 year sunspot cycle was "absolutely identical" with the geomagnetic cycle. Later, using a larger dataset, Rudolf Wolf confirmed this fact. Since Newton's explanation of the effect of the sun's gravity on earth, this was the first new phenomenon of the sun interacting with the earth. Thus began continuing studies of the solar-terrestrial activity. Sabine was an Irish geophysicist, astronomer, and explorer, who made extensive pendulum measurements to determine the shape of the earth, and established magnetic observatories to relate sunspot activity with disturbances in terrestrial magnetism. Sabine was knighted in 1869.

Sir Edward Sabin was an Irish astronomer, geophysicist, ornithologist, explorer, soldier and the 30th president of the Royal Society.

In 1869, the American Museum of Natural History in New York City was officially created with the signing of a bill by the Governor of New York, John Thompson Hoffman. The museum began from the efforts of Albert Smith Bickmore, one-time student of Harvard zoologist Louis Agassiz, who was successful in his proposal to create a natural history museum in Central Park, New York City, with the support of William E. Dodge, Jr., Theodore Roosevelt, Sr., Joseph Choate, and J. Pierpont Morgan. It opened to the public 27 Apr 1871. With a series of exhibits, the Museum's collection went on view for the first time in the Central Park Arsenal, the Museum's original home, on the eastern side of Central Park. *TIS

1909 Ernst Zermelo (1871–1953) liked to argue that it is impossible for anyone ever to reach the North Pole, because the amount of whiskey needed to reach any latitude is proportional to the tangent of that latitude. Unaware of this argument, Robert E. Peary wrote in his diary on this date. “The Pole at last!!! The prize of 3 centuries, my dream & ambition for 23 years. Mine at last. I cannot bring myself to realize it. It all seems so simple ... .” Peary, his remarkable Black associate, Matthew Henson, and four Eskimos were the ﬁrst humans to reach the North Pole. See The National Geographic Society. 100 Years of Adventure and Discovery (1987), pp. 53 & 59. [Reid, Hilbert, p. 97.]*VFR

1922 Emmy Noether named “unofficial associate professor” at Gottingen. This purely honorary position reveals the strong prejudice of the day against women. [DSB 10, 138 and A. Dick, xiii.] Thony Christie sent me a note that says "In 1922 Emmy Noether was appointed 'außerordentliche Professur' which is not an 'unofficial associate professor' but is an official professorial post without a chair. " Thanks, Thony

1929 To celebrate the centenary of the Death of Neils Henrik Abel, Norway issued a set of stamps in his honor. This is the first set of stamps honoring a mathematician in Philatelic history.

1938 DuPont researcher Roy Plunkett and his assistant, Jack Rebok, discovered polytetraﬂuoroethylene, the slipperiest man-made substance. Teﬂon became a household word in 1960 when Teﬂon-coated frying pans were introduced. The Manhattan Project used it in producing Uranium-235, for it was the only gasket material that would contain the corrosive hexaﬂouride.

In 1955, a report that Jupiter emitted radio waves was the subject of a page-length column of the New York Times. Discovered by Bernard F. Burke and Kenneth L. Franklin, astronomers at the Carnegie Institution in Washington, the waves resembled short bursts of static, similar to the interference on home radios caused by lightning. This was the first time radio waves were detected from any planet in our solar system. The astronomers announced their find at the semi-annual meeting of the American Astronomical Society in Princeton, N.J. Discovered at first by chance, it took several weeks to pinpoint Jupiter as the origin, rather than any local source on Earth.*TIS

SOUND' ON JUPITER IS PICKED UP IN U.S.; Scientists Say Radio Waves From the Big Planet May Be Caused by Huge Storms 400,000,000 MILES AWAY Emissions Are Detected by Carnegie Men--Life on Mars Stirs Debate

1956 The ﬁrst circular office building, the Capitol Tower, at Hollywood and Vine in Los Angeles, was dedicated. The building has a diameter of 92 feet and a height of 150 feet. Above the 13 ﬂoors was a 90 foot spire from which a beacon ﬂashed the word “Hollywood” in Morse code. *FFF

1963 Watson-Watt is remembered as the inventor of Radar, for which he received a patent on April 2, 1935. Twenty-eight years later he read a poem in a science meeting in San Francisco about the strange twist of Technological Karma that led to his getting a speeding ticket in Canada in 1956. Reportedly he told the officer who stopped him, "If I knew what you were going to do with it, I would never have invented it." The poem reads:

Pity Sir Watson-Watt,
strange target of this radar plot
and thus, with others I can mention,
the victim of his own invention.
His magical all-seeing eye
enabled cloud-bound planes to fly
but now by some ironic twist
it spots the speeding motorist
and bites, no doubt with legal wit,
the hand that once created it.

Oh Frankenstein who lost control
of monster man created whole,
with fondest sympathy regard
one more hoist with his petard.
As for you courageous boffins
who may be nailing up your coffins,
particularly those whose mission
deals in the realm of nuclear fission,
pause and contemplate fate's counter plot
and learn with us what's Watson-Watt.

*nndb.com

1967 Spain issued a stamp picturing Averroes (1126–1198) physician and philosopher. [Scott #1461] *VFR

1972 Cray Research is an American supercomputer manufacturer based in Seattle, Washington. The company's predecessor, Cray Research, Inc. (CRI), was founded in 1972 by computer designer Seymour Cray.

Cray Inc., a subsidiary of Hewlett Packard Enterprise, is an American supercomputer manufacturer headquartered in Seattle, Washington. It also manufactures systems for data storage and analytics. Several Cray supercomputer systems are listed in the TOP500, which ranks the most powerful supercomputers in the world.

In 1972, the company was founded by computer designer Seymour Cray as Cray Research, Inc., and it continues to manufacture parts in Chippewa Falls, Wisconsin, where Cray was born and raised.

1992 Microsoft Releases Windows 3.1:
Microsoft Corporation releases Windows 3.1, an operating system that provided IBM and IBM-compatible PCs with a graphical user interface (though Windows was not the first such interface for PCs). Retail price was $149.00. In replacing the previous DOS command line interface with its Windows system, however, Microsoft created a program similar to the Macintosh operating system, and was sued by Apple for copyright infringement. (Microsoft later prevailed in this suit).
Windows 3.1 added multimedia extensions allowing support for sound cards, MIDI, and CD Audio, Super VGA (800 x 600) monitors, and increased the speed of modem it would support to 9600 bps. It also finally abandoned "Real Mode," a vestigial environment dating back to the 8086 CPU. It provided scalable fonts and trapped the "three finger salute" (CTRL-ALT-DEL), prompting the user to avoid inadvertent re-boots. It also refined its OLE (Object Linking and embedding) concept, allowing users to cut and paste between applications.*CHM

1995 Stephen Hawking, in response to a request for a "time travel equation" from the editors of THE FACE magazine, sent the following fax: "Thank you for your recent fax. I do not have any equations for time travel. If I had, I would win the National Lottery every week." *Letters of Note web site

The Face is a British music, fashion, and culture monthly magazine originally published from 1980 to 2004, and relaunched in 2019.

Hawking once published a party invitation in his mini-series Into the Universe With Stephen Hawking, Hawking hoped to lure futuristic time travelers. You are cordially invited to a reception for Time Travellers, the invitation read, along with the the date, time, and coordinates for the event. The theory, Hawking explained, was that only someone from the future would be able to attend. for a cocktail party at his home. A film of the event depicts a dismal cocktail party. Three trays of canapes sit uneaten, and flutes filled with Krug champagne go untouched. Balloons decorate the walls, and a giant banner displays the words “Welcome, Time Travellers.

As it happened, Hawking’s party was actually an experiment on the possibility of time travel. (Invitations were sent only after the party was over.) Along with many physicists, Hawking had mused about whether going forward and back in time was possible. And what time traveler could resist sipping champagne with Stephen Hawking himself?

Unfortunately, no one came. *Atlas Obscura

BIRTHS

1749 Samuel Vince (6 April 1749; Fressingfield – 28 November 1821; Ramsgate) was an English clergyman, mathematician and astronomer at the University of Cambridge.
The son of a plasterer, Vince was admitted as a sizar to Caius College, Cambridge in 1771. In 1775 he was Senior Wrangler, and Winner of the Smith Prize at Cambridge. Migrating to Sidney Sussex College in 1777, he gained his M.A. in 1778 and was ordained a clergyman in 1779.
He was awarded the Copley Medal in 1780 and was Plumian Professor of Astronomy and Experimental Philosophy at Cambridge from 1796 until his death.
As a mathematician, Vince wrote on many aspects of his expertise, including logarithms and imaginary numbers. His Observations on the Theory of the Motion and Resistance of Fluids and Experiments upon the Resistance of Bodies Moving in Fluids had later importance to aviation history. He was also author of the influential A Complete System of Astronomy (3 vols. 1797-1808).
Vince also published the pamphlet The Credibility of Christianity Vindicated, In Answer to Mr. Hume's Objections; In Two Discourses Preached Before the University of Cambridge by the Rev. S. Vince. In this work, Vince made an apology of the Christian religion and, like Charles Babbage, sought to present rational arguments in favor of the belief in miracles, against David Hume's criticism. *Wik

Image of Vince at Cambridge

1801 William Hallowes Miller (6 Apr 1801; 20 May 1880 at age 79) Welsh mineralogist known for his Millerian indices built on his system of reference axes for crystals by which the different systems of crystal forms can be designated using a a set of three integers for each crystal face. When he published this scheme in A Treatise on Crystallography (1839), he provided an alternative to the existing confusion due to the many different descriptive systems previously in use. In his early career he published successful textbooks for hydrostatics and hydrodynamics (1831) and differential calculus (1833). Miller also prepared new standards in 1843 to replace the National Standards of weight and length that had been lost in the 1834 fire that destroyed the Parliament buildings. *TIS For an interesting story about how mathematics was related to the fire, read here.

1890 André-Louis Danjon (6 Apr 1890; 21 Apr 1967 at age 76) French astronomer who devised a now standard five-point scale for rating the darkness and colour of a total lunar eclipse, which is known as the Danjon Luminosity Scale. He studied Earth's rotation, and developed astronomical instruments, including a photometer to measure Earthshine - the brightness of a dark moon due to light reflected from Earth. It consisted of a telescope in which a prism split the Moon's image into two identical side-by-side images. By adjusting a diaphragm to dim one of the images until the sunlit portion had the same apparent brightness as the earthlit portion on the unadjusted image, he could quantify the diaphragm adjustment, and thus had a real measurement for the brightness of Earthshine.*TIS

1903 Harold Eugene Edgerton (6 Apr 1903; 4 Jan 1990 at age 86) was an American engineer and ultra-high-speed photographer who, as a graduate at the Massachusetts Institute of Technology (1926), used a strobe light in his studies, which,. by 1931, he applied the strobe to ultra-high-speed photography. He formed a company (1947) to specialize in electronic technology, which led to inventing the Rapatronic camera, capable of photographing US nuclear bomb test explosions from a distance of 7 miles. Throughout his career he applied high-speed photography as a tool in various scientific applications. He also developed sonar to study the ocean floor. Using side-scan sonar, in 1973, he helped locate the sunken Civil War battleship USS Monitor, lost since 1862, off Cape Hatteras, NC. *TIS

1947 Michael Worboys (born April 6, 1947, ) is a British mathematician and computer scientist. He is professor of spatial informatics at the School of Computing and Mathematical Sciences at the University of Greenwich, London, England.

Worboys is mostly known for his research on the computational and mathematical foundations of Geographic Information Science (GIS). In 1993 he founded the GIS Research UK (GISRUK) conference series, which is still held annually. With Matt Duckham, he wrote the well-known text book GIS: a computing perspective.*Wik

DEATHS

1528 Albrecht Durer (21 May 1471, 6 April 1528) German artist who published a book on geometric constructions (1535) using a straight-edge and compass. Although designed to enable artists better represent a natural three-dimensional scene on a canvas, Dürer included careful proofs to establish the validity of the constructions. In this respect, it could be regarded as the oldest surviving text on applied mathematics. He also wrote on the proportions of the human body.*TIS

Perhaps his most well known work to mathematicians is his Melancholia engraving which includes a magic square containing the year of the work, 1514, in adjacent squares (above the angel in the foreground). The polyhedron conceals the horizon, the starting point for linear perspective, a subject Dürer wrote about and used with aplomb. Rather than tidy orthogonals converging in vanishing point, the lines implied by the edges of the polyhedron zoom in all directions.

Interestingly, on the passion facade Sagrada Familia in Barcelona there is a very similar 4x4 magic square with two fourteens and two tens but no 12 or 16. The rows, columns and diagonals add up to 33 the age of Christ at his crucifixion. The magic square appears next to a sculpture of the kiss of Judas emphasising Christ’s betrayal by Judas Iscariot.

1829 Niels Henrik Abel, age 26, died of tuberculosis. In 1929 Norway issued four stamps for the centenary of his death. [Scott #145–148] Neils Henrik Abel was born at Fomm¨oy, a small island near Stavanger in Norway. Before going to the university in 1821 he attacked, with the vigor and immodesty of youth, the problem of the solution of the quintic equation. He submitted a solution for publication but found an error before it was published. In 1823 he proved the impossibility of a solution involving radicals that solves ﬁfth or higher degree equations. *VFR
He developed the concept of elliptic functions independently of Carl Gustav Jacobi, and the theory of Abelian integrals and functions became a central theme of later 19th-century analysis. He had difficulty finding an academic position, was troubled by poverty, and died in poverty in his late twenties.*TIS
I love Abel's commet on Gauss' writing style, "He is like the fox, who effaces his tracks in the sand with his tail."
The early death of this talented mathematician, of whom Adrien-Marie Legendre said "quelle tête celle du jeune Norvégien!" ("what a head the young Norwegian has"), cut short a career of extraordinary brilliance and promise. Under Abel's guidance, the prevailing obscurities of analysis began to be cleared, new fields were entered upon and the study of functions so advanced as to provide mathematicians with numerous ramifications along which progress could be made. His works, the greater part of which originally appeared in Crelle's Journal, were edited by Bernt Michael Holmboe and published in 1839 by the Norwegian government, and a more complete edition by Ludwig Sylow and Sophus Lie was published in 1881. The adjective "abelian", derived from his name, has become so commonplace in mathematical writing that it is conventionally spelled with a lower-case initial "a" (e.g., abelian group, abelian category, and abelian variety). (Wikipedia)

1963 Otto Struve (12 Aug 1897, 6 Apr 1963 at age 65) Russian-American astronomer who was a fourth generation astronomer, the great-grandson of Friedrich Struve. He made detailed spectroscopic investigations of stars, especially close binaries and peculiar stars, the interstellar medium (where he discovered H II regions), and gaseous nebulae. He contributed to the understanding of the broadening of spectral lines due to stellar rotation, electric fields, and turbulence and worked to separate these effects from each other and from chemical abundances. He was a pioneer in the study of mass transfer in closely interacting binary stars. Struve emigrated to the USA (1921) and joined the Yerkes Observatory, Wisconsin, becoming its director in 1932. *TIS

1992 Isaac Asimov (2 Jan 1920; 6 Apr 1992) American author and biochemist, who was a prolific writer of science fiction and of science books for the layperson. Born in Petrovichi, Russia, he emigrated with his family to New York City at age three. He entered Columbia University at the age of 15 and at 18 sold his first story to Amazing Stories. After earning a Ph.D., he taught biochemistry at Boston University School of Medicine after 1949. By 18 Mar 1941, Asimov had already written 31 stories, sold 17, and 14 had been published. As an author, lecturer, and broadcaster of astonishing range, he is most admired as a popularizer of science (The Collapsing Universe; 1977) and a science fiction writer (I, Robot;1950). He coined the term "robotics." He published about 500 volumes.*TIS

1993 John Charles Burkill FRS(1 February 1900 – 6 April 1993) was an English mathematician who worked on analysis and introduced the Burkill integral. The Burkill integral is an integral introduced by Burkill for calculating areas. It is a special case of the Kolmogorov integral.

Burkill was born in Holt, Norfolk, and educated at St Paul's School and Trinity College, Cambridge, where he won the Smith's Prize. He became a research fellow at Trinity in 1922, and two years later was appointed Professor of Pure Mathematics at Liverpool University. In 1929, he returned to Cambridge to take up a position as Reader in Mathematical Analysis, as a fellow not of Trinity but of Peterhouse. In 1948, he won the Adams Prize, and was elected a fellow of the Royal Society in 1953. He was Master of Peterhouse from 1968 to 1973. His doctoral students included Frederick Gehring.

In 1928 he married Margareta Braun, who was born in Germany but educated at Newnham College, Cambridge. Her father was German and her mother was Russian. Burkill and his wife had three children of their own, but Margareta arranged for hundreds of refugee children to come to Britain and some joined their household. Two became noted academics. After Margareta's death in 1984 Burkill lived in Sheffield, where his adopted son Harry was based, and died there in 1993.

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

Saturday, 5 April 2025

Three Times the Symmetry?

Just saw a post at Futility Closet that makes me wonder, yet again, where does he find these things... O. K. so this one was from Scripta Mathematica (1955..what, you don't browse old math mags on a daily basis???)

If you haven't discovered his blog yet, just go there and ramble around... there is no particular theme other than, in the words of an old song, "things that make you go, Hmmm!"

The thing he posted this time was this...in layers.
First, there was this palindrome... if you don't know the word, it means it reads the same front to back and back to front, like "Madam I am Adam." only numerical. (Long after I first wrote this, I learned that the Catalan term for a numeric palindrome is "capicua", which I am told means "heads and tails.")

0264 + 4125 + 5610 = 0165 + 5214 + 4620

Ok, admit it, that's cute... not mind bending cute, but cute... but then he adds,

If you put multiplication signs in the middle of each of the terms... it is STILL true (do check please)

02 × 64 + 41 × 25 + 56 × 10 = 01 × 65 + 52 × 14 + 46 × 20

Ok, that elevates it to damn near mind bending cute... if you doubt it, go find a second example. Do it with just two four digit numbers to make it easy, or do it with five if you think that is easy...and if you manage, just to torque your brain, see if it also works if you replace the multiplication sign with a Plus sign... Yeah...

02 + 64 + 41 + 25 + 56 + 10 = 01 + 65 + 52 + 14 + 46 + 20

Nah, that's it, there couldn't be anymore... I mean what else could you do ?
No, don't even imagine that if you squared each term it would still work... don't check, that couldn't possibly be true...

No really, that would just be impossible...

Stop looking down here...you know it couldn't be true...

Stop I say

Well, I warned you... now you have only yourself to blame...

Ok, just to be upfront, it doesn't end there.....

On This Day in Math - April 5

How dare we speak of the laws of chance? Is not chance the antithesis of all law?
~Joseph Bertrand

The 95th day of the year; 95⁰ + 95¹ + 95² + 95³ + 95⁴ + 95⁵ + 95⁶ is prime. *Prime Curios
(An anon. comment pointed out that for 97, you have to go up ro the 16th power to get a prime sum. Many numbers don't have prime sum below the 200th power....my thanks for the contribution.)
95 and its reversal (59) begin fewer four-digit prime numbers (seven) than any other two-digit number.

95 is the number of planar partitions of 10. (A plane partition is a two-dimensional array of integers n_(i,j) that are nonincreasing both from left to right and top to bottom and that add up to a given number n. Here's one plane partition of 22

5 4 2 1 1
3 2
2 2

95 is the sum of 7 consecutive primes = 5 + 7 + 11 + 13 + 17 + 19 + 23

EVENTS

1610 Writing to Galileo, Kepler was impressed by the observation that stars seen through the telescope still sparkled, in contrast to the circular appearance of planets. He asked:

"What other conclusion shall we draw from this difference, Galileo, than that the fixed stars generate their light from within, whereas the planets, being opaque, are illuminated from without; that is, to use Bruno’s terms, the former are suns, the latter, moons, or earths?"

*Steven Soter, Ciclops.org

1752 Taxes are due in England. Previously they were due on March 25, the ﬁrst day of the year, but because the adoption of the Gregorian calendar reform necessitated the dropping of eleven days, the tax date was changed also. Apparently the tax collectors couldn’t do fractions. *VFR Technically, I believe this is the last day of the "tax year" in England, and dates of payment for individuals cooperations and small businesses are all on other days,

In 1753, the British Museum was founded by an Act of Parliament granting £20,000 to purchase the 50,000 volume library of Sir Hans Sloane and his vast collection of 69,352 items of nature and art. Sloane was a prominent London physician who made the collection available in his will at much below its intrinsic value. Montagu House, Bloomsbury, was purchased in 1754 by the government to house this and other collections. Since it opened, on 15 Jan 1759, the Museum has been collecting, conserving and studying millions of artefacts. The British Museum established its Research Laboratory in 1920 with the appointment of Dr Alexander Scott as its first scientist.*TIS The myth that Sloan had invented the process of Hot Chocolate, which is still strongly promoted in the shops in Chelsea that feature this product, is a myth. See James Delbourgo's Article on Sloan and Cocoa here. Skipping to page 78 for details of the history of Chocolate in use around Europe in the 17th century. It had been used for much longer by the natives of South America with some apparent religious or spiritual relationship.

1792 George Washington cast the ﬁrst presidential veto in the USA. Amazingly, mathematics was involved. It seemed so easy. The 1787 US Constitution laid out simple rules for deciding how many representatives each state shall receive:
"Representatives and direct taxes shall be apportioned among the several States which may be included within this Union, according to their respective numbers, ... The number of Representatives shall not exceed one for every thirty thousand, but each State shall have at least one Representative ...". It may have seemed easy, but for the 200+ years of US government, the question of "Who gets how many?" continues to perplex and promote controversy. When congress discussed mathematical methods of applying this constitutional directive there were two methods of prime consideration, Jefferson's method, and Hamilton's method. Congress selected Hamilton's method and in the first use of the Presidential veto . President Washington rejected the bill. Congress submitted and passed another bill using Jefferson's method. The method used has changed frequently over the years with a method by Daniel Webster adopted in 1842, (the original 65 Representatives had grown to 223) and then replaced with Hamilton's method in 1852 (234 Representatives). In a strange "Only in America" moment in 1872, the congress reapportioned without actually adopting an official method and some analysis suggest that the difference caused Rutherford Hayes to win instead of Samuel Tilden who would have won had Hamilton's method been used. Since 1931 the US House has had 435 Representatives with the brief exception of when Alaska and Hawaii became states. Then there was a temporary addition of one seat for each until the new apportionment after the 1960 Census. In 1941 the Huntington-Hill Method was adopted and has remained in continuous (and contentious) use ever since.(Pat B)

Chaotic Elections! A Mathematician Looks at Voting

1800 A UFO sighting near Baton Rouge, Louisiana will be reported to the American Philosophical Society by Thomas Jefferson, President of the society, and (at that time) Vice-President of the United States. The report of a UFO by a Vice-President is still the highest government official to report a UFO. The report itself was written by the naturalist William Dunbar: "A phenomenon was seen to pass Baton Rouge on the night of the 5th April 1800, of which the following is the best description I have been able to obtain. It was first seen in the South West, and moved so rapidly, passing over the heads of the spectators, as to disappear in the North East in about a quarter of a minute. It appeared to be of the size of a large house, 70 or 80 feet long"

Four years later, On March 13, 1804, Thomas Jefferson (who was President at the time) wrote to Dunbar, charging him with the task of assembling the first scientific expedition into the southern territory of the Louisiana Purchase which was referred to as "The Great Expedition".

In 1881, Hermann von Helmholtz presented The Faraday Lecture before the Fellows of the Chemical Society in London. His topic was The Modern Development of Faraday's Conception of Electricity. Helmholtz recognized Michael Faraday as being the person who most advanced the general scientific method, saying “His principal aim was to express in his new conceptions only facts, with the least possible use of hypothetical substances and forces.” *TIS

1893, Thomas Corwin Mendenhall, then Superintendent of Weights and Measures, with the approval of the Secretary of the Treasury, decided that the International Meter and Kilogram would in the future be regarded as the fundamental standards of length and mass in the United States, both for metric and customary weights and measures. This decision, which has come to be known as "The Mendenhall Order," was first published as Bulletin No. 26 of the Coast and Geodetic Survey under the title Fundamental Standards of Length and Mass. The Mendenhall Order initiated a departure from the previous policy of attempting to maintain our standards of length and mass to be identical with those of Great Britain.*TIS (And after all this time we have completely converted to metric ;-] )

1955 On the 5th of April, 1955, Nobel laureate Bertrand Russell sent a following letter to Albert Einstein along with a rough draft of what would soon be known as the Russell-Einstein Manifesto - a written warning to the world's population on the dangers of nuclear weapons, and a plea for all leaders to avoid war when faced with conflict - and asked him to be both a signatory and supporter. Einstein's short reply, and in fact the last letter he ever wrote, arrived a week later:

Dear Bertrand Russell,
Thank you for your letter of April 5. I am gladly willing to sign your excellent statement. I also agree with your choice of the prospective signers.

With kind regards,

A. Einstein.

Einstein passed away on the 18th of that month, and the manifesto was released to the public on July 9th.
* Shaun Usher, Letters of Note Web site

In 1963, the U.S. Atomic Energy Commission gave the Fermi Award to J. Robert Oppenheimer for research in nuclear energy. Oppenheimer was the chief scientist of the Manhattan Project during WWII that created the atomic bomb. Later, he opposed the more destructive hydrogen bomb development and his security clearance was revoked (1954). Nine years later, a wiser U.S. government awarded Oppenheimer the prestigious Fermi Award, "For contributions to theoretical physics as a teacher and originator of ideas, and for leadership of the Los Alamos Laboratory and the atomic energy program during critical years." The actual presentation of the medal and $50,000 was made 2 Dec 1963 by President Lyndon B. Johnson. *TIS
American Prometheus: The Triumph and Tragedy of J. Robert Oppenheimer

BIRTHS

1588- Thomas Hobbes (5 April 1588 – 4 December 1679) was an English scholar and amateur mathematician who wrote on optics and on geometry. He attacked the 'new' methods of mathematical analysis. Hobbes was caught in a series of conflicts from the time of publishing his De Corpore in 1655. In Leviathan he had assailed the system of the original universities. Because Hobbes was so evidently opposed to the existing academic arrangements, and because De Corpore contained not only tendentious views on mathematics, but an unacceptable proof of the squaring of the circle (which was apparently an afterthought), mathematicians took him to be a target for polemics. John Wallis was not the first such opponent, but he tenaciously pursued Hobbes. The resulting controversy continued well into the 1670s. *Wik

1607 Honor´e Fabri, or Honoratus Fabrius,(5 April 1607 or 8 April 1608 – 8 March 1688) He developed the inﬁnitesimal methods of Cavalieri and Torricelli and his quadrature of the cycloid inspired Leibniz. Some of his geometrical work boils down to special cases of xn sin x dx, sinn x dx and arcsin x dx dy. [DSB 4, 506] *VFR In his treatise on man he claims to have discovered the circulation of the blood, prior to William Harvey, but after having investigated this question, Father Auguste Bellynck arrives at the conclusion that, at best, Father Fabri may have made the discovery independently of Harvey. *Wik

1617 Seth Ward (1 April, 1617* – 6 January 1689) (It seems clear he was born in 1617, and baptized on 5 April of that year. I have seen both Jan 1 and April 1, and even April 5, but that seems very unlikely) He was an English mathematician, astronomer, and bishop, born in Hertfordshire, and educated at Sidney Sussex College, Cambridge, where he graduated B.A. in 1636 and M.A. in 1640, becoming a Fellow in that year. In 1643 he was chosen university mathematical lecturer, but he was deprived of his fellowship next year for opposing the Solemn League and Covenant (with Isaac Barrow, John Barwick and Peter Gunning).
In the 1640s, he took instruction in mathematics from William Oughtred, and stayed with relations of Samuel Ward.
In 1649, he became Savilian professor of astronomy at Oxford University, and gained a high reputation by his theory of planetary motion. It was propounded in the works entitled In Ismaelis Bullialdi astro-nomiae philolaicae fundamenta inquisitio brevis (Oxford, 1653), against the cosmology of Ismael Boulliau, and Astronomia geometrica (London, 1656) on the system of Kepler. About this time he was engaged in a philosophical controversy with Thomas Hobbes, in fact a small part of the debate with John Webster launched by the Vindiciae academiarum he wrote with John Wilkins which also incorporated an attack on William Dell.
He was one of the original members of the Royal Society of London. In 1643 he was chosen university mathematical lecturer, but he was deprived of his fellowship next year for opposing the Solemn League and Covenant (with Isaac Barrow, John Barwick and Peter Gunning).

In 1659, he was appointed President of Trinity College, Oxford, but not having the statutory qualifications he resigned in 1660.*Wik

1622 – Vincenzo Viviani,(April 5, 1622 – September 22, 1703) Italian mathematician In 1639, at the age of 17, he was an assistant of Galileo Galilei in Arcetri. He remained a disciple until Galileo's death in 1642. From 1655 to

1656, Viviani edited the first edition of Galileo's collected works. He was a leader in his field and founded the Accademia del Cimento. As one of the first important scientific societies, this organization came before England's Royal Society. In 1639, at age 17, he became the student, secretary and assistant of Galileo (now blind) in Arcetri, until Galileo died in 1642. A note from Thony Christie informed me that after Galileo's death, his papers were being used by the local butcher to wrap his meat and sausages until Viviani rescued what was left of them.

During his long career, Viviani published a number of books on mathematical and scientific subjects. He edited the first edition of Galileo's collected works (1655-1656), and worked tirelessly to have his master's memory rehabilitated. In 1660, together with Borelli, he measured the velocity of sound by timing the difference between the flash and the sound of a cannon. They obtained the value of 350 metres per second.*TIS

Viviani's Theorem is named for him. The theorem states that in an equilateral triangle, for any point interior to triangle, the sum of the perpendicular distances to the sides is equal to the altitude of the triangle. In the figure h=PA + PB + PC. If the point is outside the triangle, the relationship will still hold if one or more of the perpendiculars is treated as a negative value. The theorem can be generalized to a regular n-gon to state, for any point P interior to a regular n-gon, the sum of the perpendicular distances to the n sides is n times the apothem of the figure.

It is also applicable to parallelograms, The sum of the distances from any point P inside a parallelogram is independent of the location of P.

For the tetrahedron, the generalization is even stronger. The perpendiculars from any point in a tetrahedron sum to the same value if, and only if, the four faces are acute and of equal area. (If you are a fan of math terminology, such tetrahedra are called disphenoid, From di- (“twice, double”) +‎ sphenoid (“wedge-shaped crystal or bone of the skull”, and just an extension on that for terminology freaks, like me, the term for a number that is the product of three distinct primes is called a sphenic number.)

*Wik

1877 Georg Faber (5 April 1877 in Kaiserslautern, Germany - 7 March 1966 in Munich, Germany) Faber's most important work was on the polynomial expansion of functions. This is the problem of expanding an analytical function in an area bounded by a smooth curve as a sum of polynomials, where the polynomials are determined by the area. These polynomials are now known as 'Faber polynomials' and first appear in Faber's 1903 paper Über polynomische Entwickelungen published in Mathematische Annalen. Another important paper which he also published in Mathematische Annalen, this time in 1909, was Über stetige Funktionen. In this paper he introduced the 'hierarchical basis' and explicitly used it for the representation of functions. In fact Faber was building on the idea of Archimedes who computed approximately using a hierarchy of polygonal approximations of a circle. Only in the 1980s was Faber's idea seen to be an important ingredient for the efficient solution of partial differential equations. One further achievement of Faber is worthy of mention. In 1894 Lord Rayleigh made the following claim:" ... given a fixed area of ox-hide to make a drum, the ground tone is lowest if you make your drum circular. " Two mathematicians independently verified Rayleigh's conjecture, Faber and Edgar Krahn. *SAU

1901 Subbayya Sivasankaranarayana Pillai (April 5, 1901 Nagercoil, Tamil Nadu - 31 August 1950, Cairo, Egypt) was an Nagercoil native Indian mathematician specializing in number theory. His contribution to Waring's problem was described in 1950 by K. S. Chandrasekharan as "almost certainly his best piece of work and one of the very best achievements in Indian Mathematics since Ramanujan". In number theory, a Pillai prime, named for him, is a prime number p for which there is an integer n > 0 such that the factorial of n is one less than a multiple of the prime, but the prime is not one more than a multiple of n. To put it algebraically,

$n! \equiv -1 \mod p but p \not\equiv 1 \mod n$ . The first few Pillai primes are 23, 29, 59, 61, 67, 71, 79, 83, 109, 137, 139, 149, 193, ... (sequence A063980 in OEIS). *Wik

1911 Computer Pioneer Cuthbert Hurd Is Born:
The mathematician son of an itinerant preacher, IBM President Thomas Watson Sr. hired Hurd in early 1949 as IBM's second Ph.D. A figure generally unknown to history, Hurd quietly encouraged IBM upper management to enter into the computer field, convincing them in the early 1950s that a market for scientific computers existed after a cross-country sales trip revealed pent-up demand. At the time, IBM enjoyed large profits from its traditional punch card accounting business so the change was difficult for IBM to make internally. Hurd's first great success was in selling 10 of IBM's 701 computers, its first commercial scientific machine which rented for $18,000 a month. Shortly thereafter, he became manager of the IBM team that invented and developed the FORTRAN programming language under John Backus. Hurd died on May 22, 1996 in Portola Valley, California.*CHM

1911 Walter Warwick Sawyer (or W. W. Sawyer) (April 5,1911–February 15, 2008) was a mathematician, mathematics educator and author, who taught on several continents.
Born in London, England , he attended Highgate School and was an undergraduate at St. John's College, Cambridge, obtaining a BA in 1933. He was an assistant lecturer in mathematics from 1933 to 1937 at University College, Dundee and from 1937 to 1944 at Manchester University. From 1945 to 1947, he was the head of mathematics at Leicester College of Technology.
In 1948 W. W. Sawyer became the first head of the mathematics department of what is now the University of Ghana. From 1951 to 1956, he was at Canterbury College (now the University of Canterbury in New Zealand). He left Canterbury College to become an associate professor at the University of Illinois, where he worked from winter 1957 through June 1958. While there, he criticized the New Math movement, which included the people who had hired him. From 1958 to 1965, he was a professor of mathematics at Wesleyan University. In the fall of 1965 he became a professor at the University of Toronto, appointed to both the College of Education and the Department of Mathematics. He retired in 1976.
W. W. Sawyer was the author of some 11 books. He is probably best known for his semi-popular works Mathematicians Delight and Prelude to Mathematics. Both of these have been translated into many languages. Mathematician's Delight was still in print 65 years after it was written. Some mathematicians have credited these books with helping to inspire their choice of a career.
W.W. Sawyer died on February 15, 2008, at the age of 96. He was survived by a daughter, Anne. *Wik
His first book "Mathematician’s Delight" (1943), was written with the aim "to dispel the fear of mathematics." It is one of the most successful math book ever written, going through numerous editions, translations into 10 languages, and selling more than 500,000 copies.

My favorite Sawyer quote:

Complete success would mean that every individual felt,
"I enjoyed the mathematics that I had time to learn.
If I ever need or want to learn some more,
I shall not be afraid to do so."

May I say, "A delightful book."

1918 Wanda Szmielew née Montlak (5 April 1918 – 27 August 1976) was a Polish mathematical logician who first proved the decidability of the first-order theory of abelian groups.She completed high school in 1935 and married, taking the name Szmielew. In the same year she entered the University of Warsaw, where she studied logic under Adolf Lindenbaum, Jan Łukasiewicz, Kazimierz Kuratowski, and Alfred Tarski. Her research at this time included work on the axiom of choice, but it was interrupted by the 1939 Invasion of Poland.

Szmielew became a surveyor during World War II, during which time she continued her research on her own, developing a decision procedure based on quantifier elimination for the theory of abelian groups. She also taught for the Polish underground. After the liberation of Poland, Szmielew took a position at the University of Łódź, which was founded in May 1945.

In 1949 and 1950, Szmielew visited the University of California, Berkeley, where Tarski had found a permanent position after being exiled from Poland for the war. She lived in the home of Tarski and his wife as Tarski's mistress, leaving her husband behind in Poland,[3 and completed a Ph.D. at Berkeley in 1950 under Tarski's supervision, with her dissertation consisting of her work on abelian groups.

In 1947, she published her paper on the axiom of choice, earned a master's degree from the University of Warsaw, and moved to Warsaw as a senior assistant.

Returning to Warsaw as an assistant professor, her interests shifted to the foundations of geometry. With Karol Borsuk, she published a text on the subject in 1955 (translated into English in 1960), and another monograph, published posthumously in 1981 and (in English translation) 1983.

*SAU

DEATHS

1678 - Claude Hardy (1598 in Le Mans, France- 5 April 1678 in Paris, France) was a French lawyer and amateur mathematician who made Latin translations of some of Euclid's work. A translation into French of Viète's book on algebra, originally written in Latin, appeared around 1630 with Antoine Vasset as the translator. It is believed that "Antoine Vasset" was a pseudonym for Claude Hardy. In 1630, under his own name, Hardy published Examen and in 1638 he published Refutation. These works dealt with the problem of the duplication of the cube*SAU

1684 William Brouncker (1620 – 5 April 1684) He was the King’s nominee and ﬁrst president of the Royal Society of London (1666–1677). His mathematical work concerned in particular the calculations of the lengths of the parabola and cycloid, and the quadrature of the hyperbola, which requires approximation of the natural logarithm function by infinite series. He was the first European to solve what is now known as Pell's equation. He was the first in England to take interest in generalized continued fractions and, following the work of John Wallis, he provided development in the generalized continued fraction of pi *Wik
In 1656 he gave the continued fraction expansion

. . . and used it to calculate π correct to ten decimal places. *VFR

1861 Ferdinand Joachimsthal (9 March 1818 in Goldberg, Prussian Silesia (now Złotoryja, Poland) - 5 April 1861 in Breslau, Germany (now Wrocław, Poland)) Influenced by the work of Jacobi, Dirichlet and Steiner, Joachimsthal wrote on the theory of surfaces where he made substantial contributions, particularly to the problem of normals to conic sections and second degree surfaces. *SAU

FunFact about his name: Joachimsthal was a region rich in silver, and the name shortened to daler (daler, from German T(h)aler, short for Joachimsthaler,) was the term the Spanish used for their silver coins around the time the American colonies were forming (and revolting) . The term became the name of the currency of the newly formed US government.

1900 Joseph-Louis-François Bertrand (11 Mar 1822; 5 Apr 1900 at age 78) was a French mathematician and educator and educator remembered for his elegant applications of differential equations to analytical mechanics, particularly in thermodynamics, and for his work on statistical probability and the theory of curves and surfaces. In 1845 Bertrand conjectured that there is at least one prime between n and (2n-2) for every n greater than 3, as proved five years later by Chebyshev. It is not clear to me if he was the one who suggested the jingle

I've told you once and I'll tell you again
There's always a prime between n and 2n.

In 1855 he translated Gauss's work on the theory of errors and the method of least squares into French. He wrote a number of notes on the reduction of data from observations. *TIS At age 11 he started to attend classes at the Ecole Polytechnique, where his Uncle Duhamel was a well-known professor of mathematics. At 17 he received his doctor of science degree. *VFR
In combinatorics, Bertrand's ballot problem is the question: "In an election where candidate A receives p votes and candidate B receives q votes with p > q, what is the probability that A will be strictly ahead of B throughout the count?" which Bertrand asked, and proved in 1887 in Comptes Rendus de l'Académie des Sciences.
The answer is $\frac{p-q}{p+q}.$

2004 – Heiner Zieschang (12 November 1936 in Kiel – 5 April 2004) was a German mathematician. He was a professor at Ruhr University in Bochum from 1968 till 2002. He was a topologist. In 1996 he was an honorary doctor of University of Toulouse and in 1997 he was an honorary professor of Moscow State University.

2009 Irving John ("I.J."; "Jack") Good (9 December 1916 – 5 April 2009) was a British mathematician who worked as a cryptologist at Bletchley Park with Alan Turing. After World War II, Good continued to work with Turing on the design of computers and Bayesian statistics at the University of Manchester. Good moved to the United States where he was professor at Virginia Tech.
He was born Isadore Jacob Gudak to a Polish-Jewish family in London. He later anglicized his name to Irving John Good and signed his publications "I. J. Good."
An originator of the concept now known as "technological singularity," Good served as consultant on supercomputers to Stanley Kubrick, director of the 1968 film 2001: A Space Odyssey. Good's published work ran to over three million words. He was known for his work on Bayesian statistics. He published a number of books on probability theory. In 1958 he published an early version of what later became known as the Fast Fourier Transform but in a journal so obscure that it never became widely known.*Wik

2022 Sidney Altman (May 7, 1939 – April 5, 2022) was a Canadian-American[1] molecular biologist, who was the Sterling Professor of Molecular, Cellular, and Developmental Biology and Chemistry at Yale University. In 1989, he shared the Nobel Prize in Chemistry with Thomas R. Cech for their work on the catalytic properties of RNA.

While at Yale, Altman's Nobel Prize work came with the analysis of the catalytic properties of the ribozyme RNase P, a ribonucleoprotein particle consisting of both a structural RNA molecule and one (in prokaryotes) or more (in eukaryotes) proteins. Originally, it was believed that, in the bacterial RNase P complex, the protein subunit was responsible for the catalytic activity of the complex, which is involved in the maturation of tRNAs. During experiments in which the complex was reconstituted in test tubes, Altman and his group discovered that the RNA component, in isolation, was sufficient for the observed catalytic activity of the enzyme, indicating that the RNA itself had catalytic properties, which was the discovery that earned him the Nobel Prize.[7] Although the RNase P complex also exists in eukaryotic organisms, his later work revealed that in those organisms, the protein subunits of the complex are essential to the catalytic activity, in contrast to the bacterial RNase P.

Altman was elected a Fellow of the American Academy of Arts and Sciences in 1988[8] and a member of both the National Academy of Sciences and the American Philosophical Society in 1990. *Wik

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