Non-Moiré Graphene Structures: Theory

ORAL · MAR-P35 · ID: MAR-P35








Presentations

  • Oral-In-person

    Presenters

    • Sandesh Kalantre

      • Stanford University

    Authors

    • Sandesh Kalantre

      • Stanford University
    • Chaitrali Duse

      • Stanford University
    • Ke Huang

      • Stanford University
    • Kenji Watanabe

      • National Institute for Materials Science
    • Takashi Taniguchi

      • National Institute for Materials Science
    • Charlotte Boettcher

    • David Goldhaber-Gordon

      • Stanford University
    • Aaron Sharpe

      • Stanford University

    View abstract →

  • Oral-In-person

    Presenters

    • Chaitrali Duse

      • Stanford University

    Authors

    • Chaitrali Duse

      • Stanford University
    • Sandesh Kalantre

      • Stanford University
    • Ke Huang

      • Stanford University
    • Kenji Watanabe

      • National Institute for Materials Science
    • Takashi Taniguchi

      • National Institute for Materials Science
    • Charlotte Boettcher

    • David Goldhaber-Gordon

      • Stanford University
    • Aaron Sharpe

    View abstract →

  • Oral-In-person

    Publication: [1] Yijing Liu, DaVonne Henry, Taylor Terrones, Alexis J. Demirjian, Alexey Suslov, Valery Ortiz Jimenez, Ngoc Thanh Mai Tran, Curt A. Richter, Albert F. Rigosi, Amy Y. Liu, Nikolai G. Kalugin, and Paola Barbara. Gate-assisted programmable molecular doping of epitaxial graphene devices. Submitted, 2025.

    Presenters

    • Alexis Demirjian

      • Georgetown University

    Authors

    • Alexis Demirjian

      • Georgetown University
    • DaVonne Henry

      • Georgetown University
    • Yijing Liu

      • Georgetown University
    • Taylor Terrones

      • New Mexico Institute of Mining and Technology
    • Alexey Suslov

      • National High Magnetic Field Laboratory
    • Valery Ortiz Jimenez

      • National Institute of Standards and Technology (NIST)
    • Ngoc Thanh Mai Tran

      • University of Maryland College Park
    • Curt Richter

      • National Institute of Standards and Technology (NIST)
    • Albert Rigosi

    • Nikolai Kalugin

      • New Mexico Institute of Mining and Technology
    • Paola Barbara

    • Amy Liu

      • Georgetown University

    View abstract →

  • Oral-In-person

    Publication: [1] J. J. Prías-Barragán, et al., Phys. Status Solidi A 2016, 213, 85.
    [2] K. Gross, et al., Nanotechnology 2016, 27, 365708.
    [3] J. J. Prías-Barragán, et al., IEEE 2019, 1, 61.
    [4] J. J. Prías-Barragán, et al., Journal of Magnetism and Magnetic Materials 2021, 524, 167664.
    [5] J. J. Prías-Barragán, et al., Journal of Magnetism and Magnetic Materials 2022, 541, 168506.
    [6] D. J. Sánchez‐Trujillo, et al., Nature: Scientific Reports 2023, 13, 4810.
    [7] F. A. Hoyos-Ariza, et al., Materials Today Communications 2023, 36, 106861.
    [8] B. E. Arango Hoyos, et al. Nature: Sci Rep 2023, 13, 14476.
    [9] J. J. Prías-Barragán, C. Minoli, and E. Calderón. Nature: Physics. In process (2025).

    Presenters

    • J. J. Prias-Barragan

      • Universidad del Quindio

    Authors

    • J. J. Prias-Barragan

      • Universidad del Quindio
    • C. Minoli

    • E. Calderon

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  • Oral-In-person

    Publication: Bloch theory and the tight-binding method for single-walled carbon nanotubes (to be submitted).

    Presenters

    • Yuri Antipov

      • Louisiana State University

    Authors

    • Yuri Antipov

      • Louisiana State University

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  • Oral-In-person

    Publication: [1] A. Denisov et.al., Nature Nanotechnology, 20, 494, (2025).
    [2] A.Shandilya, S. Kapila et.al., ACS App. Nano Mat., 8, 14949, (2025).

    Presenters

    • Sundeep Kapila

      • 9820441957

    Authors

    • Sundeep Kapila

      • 9820441957
    • Aparajita Modak

      • Indian Institute of Technology - Bombay (IIT)
    • Guido Burkard

      • University Konstanz
    • Bhaskaran Muralidharan

      • Indian Institute of Technology Bombay

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  • Oral-In-person

    Publication: (*) M.A. Novotny, Energy-independent total quantum transmission of electrons through nanodevices with correlated disorder, Phys. Rev. B 90, 165103 [14 pages] (2014).
    (*) M.A. Novotny, Materials and devices that provide total transmission of electrons without ballistic propagation and methods of devising same, US Patent, #US-11605794-B2 (2023).
    (*) Mark A. Novotny, G. Inkoom and Tomáš Novotný, Order amidst disorder for two-dimensional nanoribbons with various boundary conditions, EuroPhysics Letters 143, 26005 [6 pages] (2023).
    (*) M.A. Novotny and T. Novotný, Universal scaling of electron transmission for nearly ballistic and quantum dragon nanodevices, Chaos, Fractals, & Solitons, 199 (2025).

    Presenters

    • Mark Novotny

      • Mississippi State University

    Authors

    • Mark Novotny

      • Mississippi State University
    • M. Yusf

      • Mississippi State University
    • Bhola Devkota

    • Gautam Rupak

      • Mississippi State University
    • Tomas Novotny

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  • Oral-In-person

    Publication: [1] Zhou, et al. Science 375.6582 (2022): 774-778.

    [2] Koh, et al. arXiv:2407.09612 (2024).

    [3] Banszerus, et al. Nano letters 18.8 (2018): 4785-4790.

    Presenters

    • Moe Jalilvand

      • Ohio State University

    Authors

    • Pengcheng Luan

      • Ohio State University
    • Nicholas Mazzucca

    • Kenji Watanabe

      • National Institute for Materials Science
    • Takashi Taniguchi

      • National Institute for Materials Science
    • Fan Zhang

      • University of Texas at Dallas
    • Marc Bockrath

      • Ohio State University
    • Moe Jalilvand

      • Ohio State University

    View abstract →