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== Career ==
== Career ==
Before starting his graduate degree at [[MIT]], Thiele worked for six months for Swift and Company in Chicago as a process analyst, before being employed with Peoples Gas as a chemical engineering from 1920 to 1922. After completing his doctoral thesis on steam-carbon reactions, he developed (jointly with McCabe) a graphical method of design for fractionating (i.e., [[distillation]]) columns as a transformational publication in ''Industrial and Engineering Chemistry'' in 1925. This approach to the design of distillation columns was rapidly adopted in undergraduate textbooks and has remained the traditional approach to teaching distillation to undergraduate chemical engineers for almost a century.<ref>{{cite web|url=https://www.youtube.com/watch?v=Cv4KjY2BJTA|title= McCabe-Thiele Graphical Method Example|accessdate=28 December 2017}}</ref>
Before starting his graduate degree at [[MIT]], Thiele worked for six months for Swift and Company in Chicago and later in Baltimore as a process analyst, before being employed with Peoples Gas Light and Coke Company as a chemical engineer from 1920 to 1922. After completing his doctoral thesis on steam-carbon reactions, he developed (jointly with McCabe) a graphical method of design for fractionating (i.e., [[distillation]]) columns as a transformational publication in ''Industrial and Engineering Chemistry'' in 1925. This approach to the design of distillation columns was rapidly adopted in undergraduate textbooks and has remained the traditional approach to teaching distillation to undergraduate chemical engineers for almost a century.<ref>{{cite web|url=https://www.youtube.com/watch?v=Cv4KjY2BJTA|title= McCabe-Thiele Graphical Method Example|accessdate=28 December 2017}}</ref>


Thiele joined the [[Standard Oil Company]] of Indiana (then [[Amoco]], now [[BP]]) as a chemical engineer in 1925.<ref>{{cite web|url=https://cbe.nd.edu/about/thiele-bio-by-kohn|title=Ernest W. Thiele|accessdate=28 December 2017}}</ref> He continued with this company for 35 years becoming an assistant director for research in 1935 and associate director for research in 1950. During the period of World War II, he contributed to numerous technologies related to nuclear materials processing and atomic energy including a heavy water extraction facility, the Lexington Project for the design of nuclear-powered aircraft, and as a consultant to the Congressional Joint Committee on Atomic Energy. In 1949 when there was fear that espionage was behind the loss of uranium missing from Argonne National Laboratory, Mr. Thiele was named by Congress to investigate the disappearance. Thiele reported "some small amount of uranium 235 may have been stolen," but he added "it was highly unlikely."<ref>{{Cite news|url=http://articles.chicagotribune.com/1993-12-06/news/9312060110_1_standard-oil-mr-thiele-university-of-notre-dame|title=Standard Oil Engineer Ernest Thiele|work=tribunedigital-chicagotribune|access-date=2017-12-29|language=en}}</ref> Government officials blamed the loss on mismanagement.
Thiele joined the [[Standard Oil Company]] of Indiana (then [[Amoco]], now [[BP]]) as a chemical engineer in 1925.<ref>{{cite web|url=https://cbe.nd.edu/about/thiele-bio-by-kohn|title=Ernest W. Thiele|accessdate=28 December 2017}}</ref> He continued with this company for 35 years becoming an assistant director for research in 1935 and associate director for research in 1950. During the period of World War II, he contributed to numerous technologies related to nuclear materials processing and atomic energy including a heavy water extraction facility, the Lexington Project for the design of nuclear-powered aircraft, and as a consultant to the Congressional Joint Committee on Atomic Energy.<ref>{{Cite news|url=http://articles.chicagotribune.com/1993-12-06/news/9312060110_1_standard-oil-mr-thiele-university-of-notre-dame|title=Standard Oil Engineer Ernest Thiele|work=tribunedigital-chicagotribune|access-date=2017-12-29|language=en}}</ref>


During 35 years at Standard Oil, Thiele exhibited remarkable creativity and produced 17 landmark publications, and 27 U.S. patents that served as the foundation of chemical engineering.<ref>{{cite web|url=http://www.nap.edu/catalog/5427.html|title=Memorial Tributes: National Academy of Engineering, Vol. 8|accessdate=28 December 2017}}</ref> Classic engineering papers include his breakthrough paper on the efficient design of distillation systems via computational methods with co-authr R.L. Geddes published in 1933 in '' Industrial and Engineering Chemistry''. Further work led to the development of solvent extraction of lubricating oils. Another landmark contribution was the 1939 ''Industrial & Engineering Chemistry'' paper that described the Thile modulus, a dimensionless quantity describing the boundary between reaction-controlled and transport-controlled catalytic particles.<ref>{{cite web|url=https://www.researchgate.net/publication/266484272_Ernest_W_Thiele_His_Impact_on_Chemical_Engineering|title=Ernest W. Thiele: His Impact on Chemical Engineering|accessdate=28 December 2017}}</ref>
During 35 years at Standard Oil, Thiele exhibited remarkable creativity and produced 17 landmark publications, and 27 U.S. patents that served as the foundation of chemical engineering.<ref>{{cite web|url=http://www.nap.edu/catalog/5427.html|title=Memorial Tributes: National Academy of Engineering, Vol. 8|accessdate=28 December 2017}}</ref> Classic engineering papers include his breakthrough paper on the efficient design of distillation systems via computational methods with co-authr R.L. Geddes published in 1933 in '' Industrial and Engineering Chemistry''. Further work led to the development of solvent extraction of lubricating oils. Another landmark contribution was the 1939 ''Industrial & Engineering Chemistry'' paper that described the Thile modulus, a dimensionless quantity describing the boundary between reaction-controlled and transport-controlled catalytic particles.<ref>{{cite web|url=https://www.researchgate.net/publication/266484272_Ernest_W_Thiele_His_Impact_on_Chemical_Engineering|title=Ernest W. Thiele: His Impact on Chemical Engineering|accessdate=28 December 2017}}</ref>

Revision as of 13:27, 29 December 2017

Ernest W. Thiele
File:ErnestThiele.jpg
Ernest Thiele
Born(1895-12-08)December 8, 1895
Died29 November 1993(1993-11-29) (aged 97)
NationalityAmerican
Alma materLoyola University
University of Illinois, Urbana-Champaign
MIT
Known forDistillation Graphical Theory
Computational Approaches to Distillation
Thiele Modulus
Extraction of Lubricants
AwardsFounders Award (AIChE, 1966)
National Academy of Engineering (1980)
Honorary Doctorate, Notre Dame 1971
Scientific career
FieldsChemical Engineer
InstitutionsNotre Dame University
Standard Oil Company / Amoco
Doctoral advisorR.T. Haslam

Ernest W. Thiele (born Dec. 8, 1895) was an influential chemical engineering researcher at Standard Oil (then Amoco, now BP) and Professor of Chemical Engineering at the University of Notre Dame. He is known for his highly impactful work in chemical reaction engineering, complex reacting systems, and separations, including distillation theory.

Early Life & Education

Ernest Thiele, born on Dec. 8, 1985, grew up in Chicago, Illinois. In 1916, he earned an A.B. degree from Loyola University in Chicago. He was stationed at the University of Illinois at Urbana–Champaign with the U.S. Army, where he completed a bachelor's degree in chemical engineering in 1919. In the fall of 1922, matriculated to MIT where he began graduate studies under the direction of Professor Robert T. Haslam; he earned is M.S. degree in 1923 and a doctoral degree in 1925 with a thesis on steam-carbon reactions.

Career

Before starting his graduate degree at MIT, Thiele worked for six months for Swift and Company in Chicago and later in Baltimore as a process analyst, before being employed with Peoples Gas Light and Coke Company as a chemical engineer from 1920 to 1922. After completing his doctoral thesis on steam-carbon reactions, he developed (jointly with McCabe) a graphical method of design for fractionating (i.e., distillation) columns as a transformational publication in Industrial and Engineering Chemistry in 1925. This approach to the design of distillation columns was rapidly adopted in undergraduate textbooks and has remained the traditional approach to teaching distillation to undergraduate chemical engineers for almost a century.[1]

Thiele joined the Standard Oil Company of Indiana (then Amoco, now BP) as a chemical engineer in 1925.[2] He continued with this company for 35 years becoming an assistant director for research in 1935 and associate director for research in 1950. During the period of World War II, he contributed to numerous technologies related to nuclear materials processing and atomic energy including a heavy water extraction facility, the Lexington Project for the design of nuclear-powered aircraft, and as a consultant to the Congressional Joint Committee on Atomic Energy.[3]

During 35 years at Standard Oil, Thiele exhibited remarkable creativity and produced 17 landmark publications, and 27 U.S. patents that served as the foundation of chemical engineering.[4] Classic engineering papers include his breakthrough paper on the efficient design of distillation systems via computational methods with co-authr R.L. Geddes published in 1933 in Industrial and Engineering Chemistry. Further work led to the development of solvent extraction of lubricating oils. Another landmark contribution was the 1939 Industrial & Engineering Chemistry paper that described the Thile modulus, a dimensionless quantity describing the boundary between reaction-controlled and transport-controlled catalytic particles.[5]

Following retirement from Standard Oil, Thiele became a professor of chemical engineering at Notre Dame where he taught courses in thermodynamics, reactions, instrumentation, process control, and simulation. Following 10 years at Notre Dame, Thiele returned to Chicago and lived the next 27 years in the Skokie-Evanston area. Thiele died Nov. 29 1993 in the Presbyterian Home in Evanston.

Honors

Thiele was awarded the Founders Award by the American Institute of Chemical Engineers in 1966 and elected to the National Academy of Engineering (NAE) in 1980.[6] In 1971, the University of Notre Dame awarded Thiele an honorary doctorate for his many contributions to chemical engineering. He was a member of the Chicago Chemists Club and the American Chemical Society, in addition to being a fellow of the American Institute of Chemical Engineers (AIChE).

In 1986, the Chemical Engineering Department of the University of Notre Dame established the Thiele Lectureship in Chemical Engineering.[7] The lectureship recognizes excellent contributions to chemical engineering by young members of the chemical engineering profession. The first Thiele lecture was presented by Professor Douglas Lauffenburger, with Ernest Thiele in attendance. The lectureship is given every year, with the presenter selected by the faculty of Chemical Engineering of Notre Dame University.

Key publications

Ernest Thiele has authored numerous journal articles describing significant advances in chemical reaction engineering which includes but is not limited to:

  • W.L. McCabe, E.W. Thiele, "Graphical Design of Fractionating Columns", Industrial & Engineering Chemistry 17, 605, (1925).[8]
  • E.W. Thiele, "Prediction of Flash Point of Blends of Lubricating Oils" , Industrial & Engineering Chemistry 19, 259, (1927).[9]
  • E.W. Thiele, R.L. Geddes, "Computation of Distillation Apparatus for Hydrocarbon Mixtures", Industrial & Engineering Chemistry 25, 289 (1933).[10]
  • E.W. Thiele, W.B. Kay "Densities of Hydrocarbon Mixtures", Industrial & Engineering Chemistry 25, 894 (1933).[11]
  • M.C. Rogers, E.W. Thiele, "Pressure Drop in Bubble-Cap Columns", Industrial & Engineering Chemistry 26, 524 (1934).[12]
  • E.W. Thiele, "Application of Graphical Method of Ponchon to Distillation and Extraction", Industrial & Engineering Chemistry 27, 392 (1935).[13]
  • M.C. Rogers, E.W. Thiele, "Bubble-Cap Column as a Liquid-Liquid Contact Apparatus", Industrial & Engineering Chemistry 29, 529 (1937).[14]
  • E.W. Thiele, "Relation Between Catalytic Activity and Size of Particle", Industrial & Engineering Chemistry 31, 916 (1939).[15]
  • E.W. Thiele, "Material and Heat Transfer between a Granular Solid and Flowing Fluid", Industrial & Engineering Chemistry 38, 646 (1946).[16]

References

  1. ^ "McCabe-Thiele Graphical Method Example". Retrieved 28 December 2017.
  2. ^ "Ernest W. Thiele". Retrieved 28 December 2017.
  3. ^ "Standard Oil Engineer Ernest Thiele". tribunedigital-chicagotribune. Retrieved 2017-12-29.
  4. ^ "Memorial Tributes: National Academy of Engineering, Vol. 8". Retrieved 28 December 2017.
  5. ^ "Ernest W. Thiele: His Impact on Chemical Engineering". Retrieved 28 December 2017.
  6. ^ "National Academy of Engineering". Retrieved 28 December 2017.
  7. ^ "Thiele Lectureship". Retrieved 28 December 2017.
  8. ^ "Graphical Design of Fractionating Columns". Retrieved 28 December 2017. {{cite journal}}: Cite journal requires |journal= (help)
  9. ^ "{Prediction of Flash Point of Blends of Lubricating Oils". Retrieved 28 December 2017. {{cite journal}}: Cite journal requires |journal= (help)
  10. ^ "Computation of Distillation Apparatus for Hydrocarbon Mixtures". Retrieved 28 December 2017. {{cite journal}}: Cite journal requires |journal= (help)
  11. ^ "Densities of Hydrocarbon Mixtures". Retrieved 28 December 2017. {{cite journal}}: Cite journal requires |journal= (help)
  12. ^ "Pressure Drop in Bubble-Cap Columns". Retrieved 28 December 2017.
  13. ^ "Application of Graphical Method of Ponchon to Distillation and Extraction". Retrieved 28 December 2017.
  14. ^ "Bubble-Cap Column as a Liquid-Liquid Contact Apparatus". Industrial and Engineering Chemistry. 29: 529. doi:10.1021/ie50329a010. Retrieved 28 December 2017.
  15. ^ "Relation Between Catalytic Activity and Size of Particle". Industrial and Engineering Chemistry. 31: 916. doi:10.1021/ie50355a027. Retrieved 28 December 2017.
  16. ^ "Material and Heat Transfer between a Granular Solid and Flowing Fluid". Retrieved 28 December 2017.