Hello there 👋
My investigation focus involves attaining macroscopic superlubricity (extremely low friction) through the utilization of 2D substances like graphene. My advisor is Dr. Peter Schall at UvA, and I'm a part of the SSLiP group. In the past, I've worked on projects related to soft matter physics, quantum computation, and machine learning. Additionally, I'm an imaginative, entertaining individual who has recently taken up playing the guitar.
Hello there 👋
My investigation focus involves attaining macroscopic superlubricity (extremely low friction) through the utilization of 2D substances like graphene. My advisor is Dr. Peter Schall at UvA, and I'm a part of the SSLiP group. In the past, I've worked on projects related to soft matter physics, quantum computation, and machine learning. Additionally, I'm an imaginative, entertaining individual who has recently taken up playing the guitar.
Hello there 👋
My investigation focus involves attaining macroscopic superlubricity (extremely low friction) through the utilization of 2D substances like graphene. My advisor is Dr. Peter Schall at UvA, and I'm a part of the SSLiP group. In the past, I've worked on projects related to soft matter physics, quantum computation, and machine learning. Additionally, I'm an imaginative, entertaining individual who has recently taken up playing the guitar.
Integrate the principles of structural lubricity observed in 2D materials with the disciplines of granular physics and tribochemistry to achieve ultra low friction
The SSLiP consortium consists of 7 participants from 6 countries: Ireland, Germany, Norway, Netherlands, France, and Ukraine. Trinity College Dublin, Ireland, serves as the coordinating institution for the project and University of Amsterdam is one of participating institutes.
The SSLiP consortium consists of 7 participants from 6 countries: Ireland, Germany, Norway, Netherlands, France, and Ukraine. Trinity College Dublin, Ireland, serves as the coordinating institution for the project.
The science-to-technology breakthrough of SSLiP is to create a persistent network of superlubricious contacts that function as a macroscale superlubricious lubrication system.
Integrate the principles of structural lubricity observed in 2D materials with the disciplines of granular physics and tribochemistry to achieve ultra low friction
The SSLiP consortium consists of 7 participants from 6 countries: Ireland, Germany, Norway, Netherlands, France, and Ukraine. Trinity College Dublin, Ireland, serves as the coordinating institution for the project and University of Amsterdam is one of participating institutes.
The science-to-technology breakthrough of SSLiP is to create a persistent network of superlubricious contacts that function as a macroscale superlubricious lubrication system.
Poster presentation at NWO conference in Veldhoven in April, 2023.
Blog:
In Progress :
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