Googol Explained

A googol is the large number 10100 or ten to the power of one hundred. In decimal notation, it is written as the digit 1 followed by one hundred zeroes: 10,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000,000. Its systematic name is ten duotrigintillion (short scale) or ten sexdecilliard (long scale). Its prime factorization is

2100 x 5100.

Etymology

The term was coined in 1920 by 9-year-old Milton Sirotta (1911–1981), nephew of American mathematician Edward Kasner.[1] He may have been inspired by the contemporary comic strip character Barney Google.[2] Kasner popularized the concept in his 1940 book Mathematics and the Imagination.[3] Other names for this quantity include ten duotrigintillion on the short scale (commonly used in English speaking countries),[4] ten thousand sexdecillion on the long scale, or ten sexdecilliard on the Peletier long scale.

Size

A googol has no special significance in mathematics. However, it is useful when comparing with other very large quantities, such as the number of subatomic particles in the visible universe or the number of hypothetical possibilities in a chess game. Kasner used it to illustrate the difference between an unimaginably large number and infinity, and in this role it is sometimes used in teaching mathematics. To put in perspective the size of a googol, the mass of an electron, just under, can be compared to the mass of the visible universe, estimated at between and .[5] It is a ratio in the order of about to, or at most one ten-billionth of a googol (0.00000001% of a googol).

Another way of illustrating the immense size of a googol is to picture the Frontier supercomputer, which as of 2022 is the most powerful supercomputer in the world and measures, almost exactly the same size of a basketball court with run-offs and sidelines.[6] The Frontier is capable of making 1,102,000 TFLOPs (1.1 quintillion calculations per second). If the supercomputer was shrunk down to the size of an atom (for reference, a typical grain of sand might have 37 quintillion atoms),[7] and if every atom in the observable universe (~ atoms total[8]) was as powerful as a Frontier supercomputer, it would take approximately 100 seconds of parallel computing to manually add up all the digits like an adding machine (instead of using shorthand calculations).

Carl Sagan pointed out that the total number of elementary particles in the universe is around (the Eddington number) and that if the whole universe were packed with neutrons so that there would be no empty space anywhere, there would be around . He also noted the similarity of the second calculation to that of Archimedes in The Sand Reckoner. By Archimedes's calculation, the universe of Aristarchus (roughly 2 light years in diameter), if fully packed with sand, would contain grains. If the much larger observable universe of today were filled with sand, it would still only equal grains. Another 100,000 observable universes filled with sand would be necessary to make a googol.[9]

The decay time for a supermassive black hole of roughly 1 galaxy-mass due to Hawking radiation is on the order of .[10] Therefore, the heat death of an expanding universe is lower-bounded to occur at least one googol years in the future.

A googol is considerably smaller than a centillion.[11]

Properties

A googol is approximately equal to

70!1.1979 x 10100

(factorial of 70). Using an integral, binary numeral system, one would need 333 bits to represent a googol, i.e.,

10100=

(100/log102)
2

2332.19280949

. However, a googol is well within the maximum bounds of an IEEE 754 double-precision floating point type without full precision in the mantissa.

Using modular arithmetic, the series of residues (mod n) of one googol, starting with mod 1, is as follows:

0, 0, 1, 0, 0, 4, 4, 0, 1, 0, 1, 4, 3, 4, 10, 0, 4, 10, 9, 0, 4, 12, 13, 16, 0, 16, 10, 4, 16, 10, 5, 0, 1, 4, 25, 28, 10, 28, 16, 0, 1, 4, 31, 12, 10, 36, 27, 16, 11, 0, ...

This sequence is the same as that of the residues (mod n) of a googolplex up until the 17th position.

Cultural impact

Widespread sounding of the word occurs through the name of the company Google, with the name "Google" being an accidental misspelling of "googol" by the company's founders,[12] which was picked to signify that the search engine was intended to provide large quantities of information.[13] In 2004, family members of Kasner, who had inherited the right to his book, were considering suing Google for their use of the term "googol";[14] however, no suit was ever filed.[15]

Since October 2009, Google has been assigning domain names to its servers under the domain "1e100.net", the scientific notation for 1 googol, in order to provide a single domain to identify servers across the Google network.[16] [17]

The word is notable for being the subject of the £1 million question in a 2001 episode of the British quiz show Who Wants to Be a Millionaire?, when contestant Charles Ingram was discovered to have cheated his way through the show with the help of a confederate in the studio audience.[18]

See also

External links

Notes and References

  1. Bialik . Carl . There Could Be No Google Without Edward Kasner . The Wall Street Journal Online . June 14, 2004 . live . https://web.archive.org/web/20161130145858/http://www.wsj.com/articles/SB108575924921724042 . November 30, 2016.
  2. Book: The Hidden History of Coined Words . Ralph Keyes . Oxford University Press . 2021 . 978-0-19-046677-0 . 120 . Extract of page 120
  3. Book: Kasner, Edward. Newman, James R.. Mathematics and the Imagination. 1940. Simon and Schuster, New York. 0-486-41703-4. live. https://web.archive.org/web/20140703073029/http://books.google.com/books?id=Ad8hAx-6m9oC&lpg=PP1&dq=Mathematics%20and%20the%20Imagination&pg=PP1. 2014-07-03. The relevant passage about the googol and googolplex, attributing both of these names to Kasner's nine-year-old nephew, is available in Book: James R. Newman . The world of mathematics . 3 . 2000 . Dover Publications . Mineola, New York . 1956 . 978-0-486-41151-4 . 2007–2010.
  4. Book: Bromham . Lindell . An Introduction to Molecular Evolution and Phylogenetics . 2016 . Oxford University Press . New York, NY . 978-0-19-873636-3 . 494 . 2nd . April 15, 2022.
  5. Web site: Mass of the universe . Kristine . McPherson . 2006 . The Physics Factbook . Elert . Glenn . 2019-08-24.
  6. Web site: Basketball Court Dimensions & Markings Harrod Sport . 2022-09-14 . www.harrodsport.com.
  7. Book: Yongsheng, Zhong . Chinese Classic Economics . 2016-07-31 . Paths International . 978-1-84464-467-4 . en.
  8. Web site: Villanueva . John Carl . 2009-07-31 . How Many Atoms Are There in the Universe? . 2022-09-14 . Universe Today . en-US.
  9. Book: Sagan, Carl. Carl Sagan. Cosmos. 1981. Book Club Associates. 220–221.
  10. Page . Don N. . Particle emission rates from a black hole: Massless particles from an uncharged, nonrotating hole . Physical Review D . American Physical Society (APS) . 13 . 2 . 1976-01-15 . 0556-2821 . 10.1103/physrevd.13.198 . 198–206. 1976PhRvD..13..198P. See in particular equation (27).
  11. Book: Stewart . Ian . Infinity: A Very Short Introduction . 2017 . Oxford University Press . New York, NY . 978-0-19-875523-4 . 20 . April 15, 2022.
  12. Web site: Origin of the name "Google" . Koller . David . January 2004 . Stanford University . July 4, 2012 . https://web.archive.org/web/20120627081942/http://graphics.stanford.edu/~dk/google_name_origin.html . June 27, 2012 . dead .
  13. Web site: Google! Beta website . Google, Inc. . https://web.archive.org/web/19990221202430/http://www.google.com/company.html . February 21, 1999 . October 12, 2010 . dead .
  14. Web site: Have your Google people talk to my 'googol' people. 16 May 2004. live. https://web.archive.org/web/20140904125042/http://articles.baltimoresun.com/2004-05-16/entertainment/0405150243_1_google-googol-internet-search-engine. 2014-09-04.
  15. Book: Nowlan, Robert A. . Masters of Mathematics: The Problems They Solved, Why These Are Important, and What You Should Know about Them . Sense Publishers . 2017 . 978-9463008938 . Rotterdam . 221 . en.
  16. Web site: Google doppelgänger casts riddle over interwebs . 8 February 2010 . 30 December 2015 . The Register . Cade Metz . live . https://web.archive.org/web/20160303180937/https://www.theregister.co.uk/2010/02/08/google_mystery_domain/ . 3 March 2016 .
  17. Web site: What is 1e100.net? . 30 December 2015 . Google Inc. . live . https://web.archive.org/web/20160109065331/https://support.google.com/faqs/answer/174717?hl=en . 9 January 2016 .
  18. .