Fun Projetcs
Description
I enjoy teaching and breaking down complex problems to simpler terms. This has led me to make teaching videos, intuitive animations and some fun python projects. I have provided here link to my youTube channel. Repository links to some fun and unpublished projects are also included.
Related Links
- "Three-Dimensional Atomically Resolved Analytical Imaging with a Field Ion Microscope" - Microscopy and Microanalysis July. 2021. View Publication
The research showcases a hybrid experimental method combining atom probe tomography (APT) and field ion microscopy (FIM) to achieve atomic resolution with elemental discrimination, a feat neither technique can fully accomplish on its own. By utilizing two atom probe instruments—one with a straight flight path and another with a reflectron lens—for time-of-flight mass spectrometry alongside FIM, the study establishes protocols to distinguish field-evaporated signals from a large field-ionized background. This approach, termed analytical field ion microscopy (aFIM), addresses the challenges of accurately detecting and identifying individual ions, offering a unique solution for linking nanoscale chemical variations to physical properties.
- "Revealing atomic-scale vacancy-solute interaction in nickel" - Scripta Materialia May. 2021. View Publication
The study focuses on the impact of crystalline imperfections on the physical and mechanical properties of materials, highlighting the challenge of imaging individual vacancies and their atomic surroundings. Using a creep-deformed binary Ni-2 at.% Ta alloy, the research employs atom probe tomography and field ion microscopy, enhanced by density-functional theory and time-of-flight mass spectrometry, to reveal a random Ta distribution and its positive correlation with vacancies. This supports the previously predicted positive solute-vacancy interactions through atomistic simulations.
- "Imaging individual solute atoms at crystalline imperfections in metals" - New Journal of Physics Nov. 2019. View Publication
The study introduces an advanced method for chemistry-sensitive field-ion microscopy (FIM) by integrating it with time-of-flight mass-spectrometry (tof-ms) and data mining, termed analytical-FIM (A-FIM). This approach enables elemental identification and correlates it to FIM images, offering true atomic resolution and the ability to directly image individual atoms and crystalline defects that significantly influence material properties. A-FIM's capabilities are demonstrated through the identification of individual rhenium (Re) atoms within crystalline defects in Ni–Re alloys, aiding in understanding how Re enhances the durability of Ni-based superalloys at high temperatures.
- "Impact of local electrostatic field rearrangement on field ionization" - Journal of Physics D. Feb. 2018. View Publication
Field ion microscopy (FIM) achieves true atomic resolution imaging by utilizing the high charge density on surfaces to ionize gas atoms, a process enhanced by field evaporation. This study introduces a novel image processing algorithm that tracks individual atoms on the surface, allowing for quantitative analysis of atomic position shifts. Through a combination of experimental work and molecular dynamics simulations, it was confirmed that these shifts are tied to electrostatic field rearrangements affecting the ionization zone of imaging gas. The findings underscore significant implications for the advancement of 3D FIM data reconstruction, particularly for the precise quantification of lattice strains and the characterization of crystalline defects at the atomic level.
