Rainer Waser

Rainer Waser (born September 16, 1955, in Frankfurt)[1] is a German professor of Electrical Engineering[2] at RWTH Aachen University (Aachen). He is also director of the section Electronic Materials at the Peter Grünberg Institute which is located on the campus of Jülich Research Center (Forschungszentrum Jülich). His research and teaching is on solid-state chemistry and defect chemistry to electronic properties and modelling, the technology of new materials and the physical properties of construction components.

Important findings include insights in the functioning of the so-called memristors.[3]

Waser grew up in Heusenstamm near Frankfurt.[4] He studied Physical Chemistry at Darmstadt University of Technology where he received a diploma degree in 1979. Then he went to the University of Southampton to conduct research at the Institute of Electrochemistry. After that he turned to Darmstadt and worked as scientific assistant until he completed his PhD.

Career

Waser joined the Philips research laboratories (research group Electronic Ceramics) at Aachen.

In 1992, Waser accepted a Chair for Electronic Materials in the Faculty of Electrical Science and Information Technology at RWTH Aachen University.

In 2012, Waser was elected to the post of Speaker of the Department of Electrical Engineering and Information Technology at Aachen university.

Waser was awarded the renowned Gottfried Wilhelm Leibniz Prize in 2014.[5]

Awards and honors

A comprehensive list can be found in the cv on the institute's website.[6]

Fellowships and Academy Membership

  • Fellow of the North-Rhine Westphalian Academy of Sciences, Humanities and the Arts.[9]
  • Spokesperson of the section Future information technology (FIT) within the Helmholtz-Zentrum Berlin[10]

Other Functions

  • Executive Advisory Board Member of the journal Advanced Functional Materials[11]

Selected works

  • with I. Valov, E. Linn, S. Tappertzhofen, S. Schmelzer, J. van den Hurk, F. Lentz: Nanobatteries in redox-based resistive switches require extension of memristor theory, in: Nature Communications. 23. April 2013, DOI: 10.1038/ncomms2784
  • R. Waser (ed.): Nanoelectronics and Information Technology. Advanced Electronic Materials and Novel Devices, 3. complete new revised edition, Weinheim 2012, Wiley
  • with S. Menzel, M. Waters, A. Marchewka, U. Böttger, R. Dittmann: Origin of the ultra-nonlinear switching kinetics in oxide-based resistive switches, in: Advanced functional materials 21, 4487 - 4492 (2011)
  • with S. Tappertzhofen, E. Linn, L. Nielen, R. Rosezin, F. Lentz, R. Bruchhaus, I. Valov, U. Böttger: Capacity based nondestructive readout for complementary resistive switches, in: Nanotechnology 22, 395203 (2011)
  • R. Waser (ed.): Nanotechnology, vol. 3 and 4, Weinheim 2009, Wiley
gollark: C++ is more complicated and weirder, and it may be bad teaching.
gollark: Or learn to program. I think basically everyone is *capable* of it.
gollark: I'm also not entirely sure why you would want, specifically, a command to view your capacitor bank's stored energy, and not a graph or % value or something.
gollark: If you want, for some bizarre reason, a way to run commands like `getrf`, you'll have to program your own program for that using the lower-level component APIs.
gollark: Roughly. Something like that.

References

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