Randall Feenstra
The research activities of my group deal with structural and electronic properties of semiconductor materials and devices. A major tool used in the studies is the scanning tunneling microscope, which allows one to image the atomic structure of a surface and to perform spectroscopic measurements of the electronic energy levels. Many of the studies deal with semiconductor heterostructures consisting of multiple layers of different types of material, with the goal of understanding how the structure of the device (including imperfections and defects) determines its electronic properties. Growth of semiconductor heterostructures has been performed in my laboratory using molecular beam epitaxy, for GaN in particular (a semiconductor with a relatively large band gap, used for blue light-emitting devices and for microwave transistor applications).
Most recently we have focused on the study of two-dimensional (2D) materials, including graphene and hexagonal boron nitride (h-BN). We prepare these materials by growth at high temperatures, and we characterize them using both scanning tunneling microscopy and low-energy electron microscopy. The latter permits both diffraction and imaging of the surfaces, with nm-scale resolution. Additionally, spectroscopic observation of energy levels above the vacuum level is performed, which is particularly useful for these 2D materials. Heterostructures consisting of alternating layers of graphene and h-BN are being studied, because of the unique current-voltage characteristic for tunneling in such structures.
The research activities of my group deal with structural and electronic properties of semiconductor materials and devices. A major tool used in the studies is the scanning tunneling microscope, which allows one to image the atomic structure of a surface and to perform spectroscopic measurements of the electronic energy levels. Many of the studies deal with semiconductor heterostructures consisting of multiple layers of different types of material, with the goal of understanding how the structure of the device (including imperfections and defects) determines its electronic properties. Growth of semiconductor heterostructures has been performed in my laboratory using molecular beam epitaxy, for GaN in particular (a semiconductor with a relatively large band gap, used for blue light-emitting devices and for microwave transistor applications).
Most recently we have focused on the study of two-dimensional (2D) materials, including graphene and hexagonal boron nitride (h-BN). We prepare these materials by growth at high temperatures, and we characterize them using both scanning tunneling microscopy and low-energy electron microscopy. The latter permits both diffraction and imaging of the surfaces, with nm-scale resolution. Additionally, spectroscopic observation of energy levels above the vacuum level is performed, which is particularly useful for these 2D materials. Heterostructures consisting of alternating layers of graphene and h-BN are being studied, because of the unique current-voltage characteristic for tunneling in such structures.
Students
Title | Position | |
---|---|---|
Vineetha Bheemarasetty | Undergraduate Student | vbheemar@andrew.cmu.edu |
Jun Li | Graduate Student | junl2@andrew.cmu.edu |
Dacen Waters | Graduate Student | dwaters@andrew.cmu.edu |
Andrew Ye | Undergraduate Student | andrewy@andrew.cmu.edu |
Andrew Ye | Undergraduate Student | andrewy@andrew.cmu.edu |
"Atom-selective imaging of the GaAs(110) surface," R. M. Feenstra, Joseph A. Stroscio, J. Tersoff, and A. P. Fein, Phys. Rev. Lett. 58, 1192 (1987)
"Tunneling spectroscopy of the Si(111)2 × 1 surface," R.M. Feenstra, Joseph A. Stroscio, A.P. Fein, Surface Science 181, 295 (1987)
"Electronic Structure of the Si(111)2 × 1 Surface by Scanning-Tunneling Microscopy," Joseph A. Stroscio, R. M. Feenstra, and A. P. Fein, Phys. Rev. Lett. 57, 2579 (1986)
"Tunneling spectroscopy of the GaAs(110) surface," R. M. Feenstra and Joseph A. Stroscio, J. Vac. Sci. Technol. B 5, 923 (1987)
"Tunneling spectroscopy of the (110) surface of direct-gap III-V semiconductors," R. M. Feenstra, Phys. Rev. B 50, 4561 (1994)
Lüpke, F., Waters, D., Sergio, C., Widom, M., Mandrus, D. G., Yan, J., ... & Hunt, B. M. (2020). Proximity-induced superconducting gap in the quantum spin Hall edge state of monolayer WTe 2. Nature Physics, 16(5), 526-530.
Waters, D., Nie, Y., Lüpke, F., Pan, Y., Fölsch, S., Lin, Y. C., ... & Cho, K. (2020). Flat Bands and Mechanical Deformation Effects in the Moiré Superlattice of MoS2-WSe2 Heterobilayers. ACS Nano.
Waters, D., Lüpke, F., Hunt, B., & Feenstra, R. (2020). Quantum spin Hall effect in twisted bilayer WTe 2 measured with STM. Bulletin of the American Physical Society, 65.
"Formation of Graphene atop a Si adlayer on the C-face of SiC," J Li, Q Wang, G He, M Widom, L Nemec, V Blum, M Kim, P Rinke, and RM Feenstra. arXiv (2019)
"Coexistence of quantum spin hall edge state and proximity-induced superconducting gap in monolayer 1T'-WTe2," F Lupke, D Waters, SC de la Barrera, M Widom, DG Mandrus, J Yan, RM Feenstra, and BM Hunt. arXiv (2019)