Mikhail Katsnelson

This name uses Eastern Slavic naming customs; the patronymic is Iosifovich and the family name is Katsnelson.
Mikhail Katsnelson
Born (1957-08-10) August 10, 1957
Magnitogorsk, Russia
Fields Physics
Institutions Radboud University Nijmegen
Alma mater Ural State University
Institute of Metal Physics
Notable awards Spinoza Prize (2013)

Mikhail Iosifovich Katsnelson (Russian: Михаил Иосифович Кацнельсон; born August 10, 1957) is a Dutch professor of theoretical physics of Russian descent. He works at Radboud University Nijmegen where he specializes in graphene ripples.[1]

Early life

Katsnelson was born in Magnitogorsk, Russia. From 1972-1977 he attended and then graduated from the Ural State University in Sverdlovsk. In 1980 he obtained his Ph.D. from Institute of Metal Physics in the same place where his advisor was Serghey V. Vonsovsky. In 1985 he defended his thesis for his Doctor of Science degree called Strong electron correlations in transition metals, their alloys and compounds and from 1990 to 1998 became Max-Planck-Institute visiting professor.[2]

Career

From 2004 to 2007 Katsnelson worked with many Russian and Dutch physicists on the nitrogen dioxide and discovered that by combining it with tetraoxygen it creates only weak doping which is also known as density of states in a grapheme. He also discovered that density of states is ideal for chemical sensoring and explained its single molecule detection.[3] On September 23, 2007 he along with Annalisa Fasolino have proven that chemical bonding in carbon is caused by setting ripples' thermal fluctuations to 80 angstrom.[4] In 2010 Katsnelson worked with physicists from India such as Rashid Jalil, Rahul R. Nair, and nanotechnologist Fredrik Schedin of University of Manchester and have discovered that fluorine atoms are attached to the carbon of the graphene therefore creating a new version called fluorographene that can be stable in the air with a temperature of 400 °C (752 °F).[5] In 2012 he and his colleagues have used prototype device which contained graphene heterojunctions which was combined with either thin boron nitride or molybdenum disulfide which was used as a vertical transport barrier. During the experiment, the room temperature was set from ≈50 and ≈10,000 and they prove that using such prototypes is beneficial for high-frequency operations and large-scale integrations.[6]

Since 2014 Katsnelson is member of the Royal Netherlands Academy of Arts and Sciences.[7]

Awards

References

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