Your search keyword '"Tamara-Isaza, Jeyson"' showing total 3 results

1. Diamond Micro-Chip for Quantum Microscopy

Author

Asif, Shahidul, Chen, Hang, Cremer, Johannes, Ravan, Shantam, Tamara-Isaza, Jeyson, Lamsal, Saurabh, Ebadi, Reza, Li, Yan, Zhou, Ling-Jie, Chang, Cui-Zu, Xiao, John Q., Yacoby, Amir, Walsworth, Ronald L., and Ku, Mark J. H.

Subjects

Physics - Applied Physics, Condensed Matter - Materials Science, Quantum Physics

Abstract

The nitrogen vacancy (NV) center in diamond is an increasingly popular quantum sensor for microscopy of electrical current, magnetization, and spins. However, efficient NV-sample integration with a robust, high-quality interface remains an outstanding challenge to realize scalable, high-throughput microscopy. In this work, we characterize a diamond micro-chip (DMC) containing a (111)-oriented NV ensemble; and demonstrate its utility for high-resolution quantum microscopy. We perform strain imaging of the DMC and find minimal detrimental strain variation across a field-of-view of tens of micrometer. We find good ensemble NV spin coherence and optical properties in the DMC, suitable for sensitive magnetometry. We then use the DMC to demonstrate wide-field microscopy of electrical current, and show that diffraction-limited quantum microscopy can be achieved. We also demonstrate the deterministic transfer of DMCs with multiple materials of interest for next-generation electronics and spintronics. Lastly, we develop a polymer-based technique for DMC placement. This work establishes the DMC's potential to expand the application of NV quantum microscopy in materials, device, geological, biomedical, and chemical sciences., Comment: Includes supplementary materials section

Published

2024

2. Microscopic Green's function approach for generalized Dirac Hamiltonians

Author

Támara-Isaza, Jeyson, Burset, Pablo, and Herrera, William J.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The rising interest in Dirac materials, condensed matter systems where low-energy electronic excitations are described by the relativistic Dirac Hamiltonian, entails a need for microscopic effective models to analytically describe their transport properties. Specifically, for the study of quantum transport, these effective models must take into account the effect of atomic-scale interfaces and the presence of well-defined edges while reproducing the correct band structure. We develop a general method to analytically compute the microscopic Green's function of Dirac materials valid for infinite, semi-infinite, and finite two-dimensional layers with zigzag or armchair edge orientations. We test our method by computing the density of states and scattering probabilities of germanene and some transition metal dichalcogenides, obtaining simple analytical formulas. Our results provide a useful analytical tool for the interpretation of transport experiments on Dirac materials and could be extended to describe additional degrees of freedom like extra layers, superconductivity, etc., Comment: 17 pages, 15 figures

Published

2023

3. Revealing room temperature ferromagnetism in exfoliated Fe$_5$GeTe$_2$ flakes with quantum magnetic imaging

Author

Chen, Hang, Asif, Shahidul, Whalen, Matthew, Tamara-Isaza, Jeyson, Luetke, Brennan, Wang, Yang, Wang, Xinhao, Ayako, Millicent, Lamsal, Saurabh, May, Andrew F., McGuire, Michael A., Chakraborty, Chitraleema, Xiao, John Q., and Ku, Mark J. H.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Van der Waals material Fe$_5$GeTe$_2$, with its long-range ferromagnetic ordering near room temperature, has significant potential to become an enabling platform for implementing novel spintronic and quantum devices. To pave the way for applications, it is crucial to determine the magnetic properties when the thickness of Fe5GeTe2 reaches the few-layers regime. However, this is highly challenging due to the need for a characterization technique that is local, highly sensitive, artifact-free, and operational with minimal fabrication. Prior studies have indicated that Curie temperature TC can reach up to close to room temperature for exfoliated Fe$_5$GeTe$_2$ flakes, as measured via electrical transport; there is a need to validate these results with a measurement that reveals magnetism more directly. In this work, we investigate the magnetic properties of exfoliated thin flakes of van der Waals magnet Fe$_5$GeTe$_2$ via a quantum magnetic imaging technique based on nitrogen vacancy diamond. Through imaging the stray fields, we confirm room-temperature magnetic order in Fe$_5$GeTe$_2$ thin flakes with thickness down to 7 units cell. The stray field patterns and their response to magnetizing fields with different polarities point to a perpendicular easy-axis anisotropy. Furthermore, we perform imaging at different temperatures and determine the Curie temperature of the flakes at Tc~300 K. These results provide the basis for realizing a room-temperature monolayer ferromagnet with Fe$_5$GeTe$_2$. This work also demonstrates that the imaging technique enables a rapid screening of multiple flakes simultaneously, thereby paving the way towards high throughput characterization of potential 2D magnets near room temperature.

Published

2021