Philip Egberts

Dr. Philip Egberts, PhD, PEng

Pronouns: he/him/his

Positions

Full Professor

Schulich School of Engineering, Department of Mechanical and Manufacturing Engineering

Contact information

Web presence

Phone number

Office: 403-220-7678

Location

Office: MEB517

For media enquiries, contact

Joe McFarland
Media Relations and Communications Specialist

Cell: +1.403.671.2710
Email: Joe.Mcfarland@ucalgary.ca

Background

Educational Background

BASc Nanoengineering Option, Division of Engineering Science, University of Toronto, 2004

MASc Department of Materials Science and Engineering, University of Toronto, 2006

PhD Department of Physics, McGill University, 2011

Biography

Philip Egberts obtained his Ph.D. in 2011 from the McGill University in Montreal, Canada specializing in Experimental Condensed Matter Physics. During this time, he spent most of his research at the INM-Leibniz Institute for New Materials in Saarbrücken, Germany. Following his PhD studies, he joined the Carpick Research Group in the Mechanical Engineering and Applied Mechanics department at the University of Pennsylvania as a Natural Sciences and Engineering Research Council (NSERC) of Canada Postdoctoral Fellow (PDF).

Currently, he is a faculty member at the University of Calgary in the Department of Mechanical and Manufacturing Engineering. More recently, Dr. Egberts was Associate Head Graduate Studies in Mechanical and Manufacturing Engineering and Associate Professor in from 2015-2018. He was also a visiting professor and Humboldt Fellow at the University of Hamburg in the Department of Physics from 2019-2020.

His current research interests range atomic and nanoscale investigation of adhesion, friction, and wear, as well as nanoenhanced lubricant development and tribocorrosion. The overarching goal of his work is to link experimental findings of friction and wear with theory, eventually to make physical and predictive models of friction and wear.

Research

Areas of Research

Tribology

Our research focuses on the study friction, plasticity and wear at the nanoscale using atomic force microscopy (AFM). We investigate these problems using simple materials and determine the fundamental physical mechanisms by which they occur. By approaching these complex engineering problems at the atomic-length scale, we can reduce the complexity of the problems.

We are also able to take advantage of other modes of AFM to obtain true atomic resolution of surfaces. For example, the true atomic resolution of the (100) surface of potassium bromide (KBr). We can identify the high resolution capability of the AFM by observing single atomic vacancies at the surface. With these experiments, we hope to be able to predictively determine material parameters such as friction coefficients, plasticity/hardness and wear rates, which will be critical in the development of next generation materials and lubricants. for, example, when we image atomic stick-slip friction on an alkanethiol self-assembled monolayer grown on a Au(111) substrate, atomic lattice resolution is achieved. However, single atomic defects cannot be observed due to the "large" multi-atom contact between the AFM tip and the surface. Using AFM, we are able to resolve forces much less than 1 nN, which approaches the strength of single atomic bonds.

Materials Science

Metallurgy

Tribochemistry

Publications

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