Geertruida de Haas-Lorentz

In this Dutch name, the birth surname is Lorentz and the marital name is De Haas-Lorentz.
In this article, we use Dutch capitalization for the tussenvoegsels in Dutch family names. The first letter in De Haas and in De Haas-Lorentz is capitalized unless it is preceded by a name, initial or title of nobility.
Geertruida de Haas-Lorentz
De Haas-Lorentz in 1927
Born
Geertruida Luberta Lorentz

(1885-10-20)20 October 1885
Leiden, South Holland, Netherlands
Died1973 (aged 87–88)
Leiden, South Holland, Netherlands
Alma materUniversity of Leiden
Known forFirst to perform fluctuational analysis of electrons as Brownian particles
Spouse
(m. 1910; died 1960)
Children4
FatherHendrik Lorentz
Scientific career
FieldsPhysics
InstitutionsTechnical University of Delft
ThesisOver de theorie van de Brown'schen beweging en daarmede verwante verschijnselen (1912)
Doctoral advisorHendrik Lorentz

Geertruida Luberta "Berta" de Haas-Lorentz (20 November 1885 – 1973) was a Dutch physicist and a professor at the Technical University of Delft. She was the first to theoretically study thermal fluctuations in electric circuits, treating electrons as Brownian particles. Consequently she is considered one of the pioneers of electrical noise theory. She was the daughter and doctoral student of Hendrik Lorentz. She went by the name Berta, or Ber.[1]

Life

Berta Lorentz was born in Leiden, Netherlands, the eldest daughter of the physicist and 1902 Nobel Prize in Physics winner Hendrik Lorentz and Aletta Catharina Kaiser. Berta was the eldest of four children. Her siblings were Johanna Wilhelmina (born 1889), Gerrit (born 1893, died 1894), and Rudolf (born 1895).[2] At that time of her birth, her father was Professor of Theoretical Physics at the University of Leiden.[3] Her mother, Aletta Kaiser, took care of the children and household, did charity work, and was heavily involved with the local women's suffrage movement.[4]

On 22 December 1910, Berta Lorentz married Wander Johannes de Haas, who would become professor of experimental physics in Leiden, and they went on to have two sons and two daughters. Some of their children changed their last name to "Lorentz de Haas."[5][6]

She studied physics at the University of Leiden with her father as dissertation advisor[7] and earned her doctor's degree in 1912 on a thesis entitled "On the theory of Brownian motion and related phenomena" (Dutch: Over de theorie van de Brown'schen beweging en daarmede verwante verschijnselen).[8]

After defending her doctoral dissertation in Leiden, De Haas-Lorentz taught physics at the Technical University of Delft and translated some of her father's works into German.[3] She also wrote a biography of her father.[9]

Berta de Haas-Lorentz died in 1973 in Leiden.

Research

De Haas-Lorentz was one the first to apply Albert Einstein's theory of Brownian motion to other domains.[10] During her thesis work, she was the first to carry out a theoretical analysis of thermal fluctuation of electrons in electrical circuits, predating the experimental discovery of the Johnson–Nyquist noise.[11] She considered that a circuit with resistance R and inductance L should store an energy E = LI2/2, where I is the current. If there was a fluctuating thermal current, by the equipartition theorem the energy would be related to the thermal energy kT where k is the Boltzmann constant and T is the temperature. De Haas-Lorentz obtained,

,

where the angle brackets denote the thermal average.[12]

She was also the first to propose thermal fluctuations limit the detection of electromagnetic radiation.[10]

In collaboration with her husband, the De Haas couple showed that experiments carried by James Clerk Maxwell failed to prove the hypothesis of André-Marie Ampère, that magnetism in matter is caused by microscopic current loops.[13][14]

outdoors, Geertrudia is holding one child and Hendrik is holding the other
Geertrudia de Haas-Horentz, center, with father Hendrik Lorentz (kneeling) and two small children (unknown)

She also predicted the London penetration depth for superconductivity in 1925, before the development of the London equations in 1935.[15][16]

Selected works

  • De Haas-Lorentz, Geertruida (1912). Over de theorie van de Brown'sche beweging en daarmede verwante verschijnselen (PDF) (Doctoral dissertation thesis) (in Dutch). University of Leiden.
  • De Haas-Lorentz, Geertruida (1913). Die Brownsche Bewegung und einige verwandte erscheinungen (in German). Braunschweig: F. Vieweg. OCLC 5160522.
  • De Haas-Lorentz, Geertruida; Lorentz, H. A. (1919). Theorie der quanta. OCLC 81861598.
  • Lessen over theoretische natuurkunde : aan de Rijks-Universiteit te Leiden. Vol. 1–5. 1919–1926. OCLC 805502380. – contributing author
  • Lorentz, H. A.; Bruins, Eva Dina; Reudler, Johanna; De Haas-Lorentz, Geertruida Luberta (1928). Kinetische Probleme (in German). Leipzig: Akademische Verlagsgesellschaft. OCLC 28005510.
  • De Haas-Lorentz, Geertruida Luberta (1946). De beide hoofdwetten der thermodynamica en hare voornaamste toepassingen (in Dutch). 's-Gravenhage: M. Nijhoff. OCLC 361410098.
  • De Haas-Lorentz, Geertruida Luberta, ed. (1957). H. A. Lorentz: impression of his life and work. Amsterdam: North-Holland Pub. Co. OCLC 317334917.

Notes

  1. ^ Kox & Schatz 2021, p. 38.
  2. ^ Kox & Schatz 2021, p. 39.
  3. ^ a b Parkadze, V. (1988). Women Physicists. Tbilisi. pp. 71–75.{{cite book}}: CS1 maint: location missing publisher (link)
  4. ^ Kox & Schatz 2021, pp. 42–44.
  5. ^ Kox & Schatz 2021, p. 257.
  6. ^ "To the Memory of A.M. Lorentz de Haas" (PDF).
  7. ^ De Haas-Lorentz, Geertruida. "Math Genealogy Project". Retrieved 24 October 2020.
  8. ^ De Haas-Lorentz, Geertruida (1912). "Over de theorie van de Brown'sche beweging en daarmede verwante verschijnselen" (PDF).
  9. ^ De Haas-Lorentz, Geertruida Luberta (1957). H.A. Lorentz: Impressions of His Life and Work. North-Holland Publishing Company.
  10. ^ a b Van Der Ziel, A. (1 January 1980). "History of Noise Research". In Marton, L.; Marton, C. (eds.). Advances in Electronics and Electron Physics. Vol. 50. Academic Press. pp. 351–409. doi:10.1016/S0065-2539(08)61066-5. ISBN 978-0-12-014650-5. Retrieved 16 March 2024.
  11. ^ Dörfel, G. (15 August 2012). "The early history of thermal noise: The long way to paradigm change". Annalen der Physik. 524 (8): 117–121. Bibcode:2012AnP...524..117D. doi:10.1002/andp.201200736. ISSN 0003-3804.
  12. ^ Yeang, Chen-Pang (30 January 2024). Transforming Noise: A History of Its Science and Technology from Disturbing Sounds to Informational Errors, 1900-1955. Oxford University Press. ISBN 978-0-19-888776-8.
  13. ^ Haas, W. J.; Haas-Lorentz, G.L. (1917). "An experiment of Maxwell and Ampere molecular currents" (PDF). KNAW, Proceedings. 19 (I). Amsterdam: 248–255. Bibcode:1917KNAB...19..248D.
  14. ^ San Miguel, Alfonso; Pallandre, Bernard (13 March 2024). "Revisiting the Einstein-de Haas experiment: the Ampère Museum's hidden treasure" (PDF). Europhysics News: 12–14.
  15. ^ Fossheim, Kristian; Sudbø, Asle (2005). Superconductivity: physics and applications. John Wiley & Sons.
  16. ^ De Haas-Lorentz, G. L. (1925). "Iets over het mechanisme van inductieverschijnselen". Physica (in Dutch). 5: 384–388.

References

  • Kox, Anne J.; Schatz, H. F. (2021). "A living work of art": the life and science of Hendrik Antoon Lorentz (1st ed.). Oxford: Oxford University Press. p. 38. ISBN 978-0-19-887050-0. OCLC 1194958040.