Vernier Spectrum and Isospin State Control in Carbon Nanotube Quantum Dots
Commensurability phenomena abound in nature and are typically associated with mismatched lengths, as can occur in quasiperiodic systems. However, not all commensuration effects are spatial in nature. In finite-sized Dirac systems, an intriguing example arises in tilted or warped Dirac cones wherein...
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| creator | Berg, Jameson Lotfizadeh, Neda Nichols, Dublin Senger, Mitchell J De Gottardi, Wade Minot, Ethan D Deshpande, Vikram V |
| description | Commensurability phenomena abound in nature and are typically associated with
mismatched lengths, as can occur in quasiperiodic systems. However, not all
commensuration effects are spatial in nature. In finite-sized Dirac systems, an
intriguing example arises in tilted or warped Dirac cones wherein the
degeneracy in the speed of right- and left-moving electrons within a given
Dirac cone or valley is lifted. Bound states can be purely fast-moving or
purely slow-moving, giving rise to incommensurate energy level spacings and a
vernier spectrum. In this work, we present evidence for this vernier spectrum
in Coulomb blockade measurements of ultraclean suspended carbon nanotube
quantum dots. The addition-energy spectrum of the quantum dots reveals an
energy-level structure that oscillates between aligned and misaligned energy
levels. Our data suggest that the fast- and slow-moving bound states hybridize
at certain gate voltages. Thus, gate-voltage tuning can select states with
varying degrees of hybridization, suggesting numerous applications based on
accessing this isospin-like degree of freedom. |
| doi_str_mv | 10.48550/arxiv.2311.12332 |
| format | Article |
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mismatched lengths, as can occur in quasiperiodic systems. However, not all
commensuration effects are spatial in nature. In finite-sized Dirac systems, an
intriguing example arises in tilted or warped Dirac cones wherein the
degeneracy in the speed of right- and left-moving electrons within a given
Dirac cone or valley is lifted. Bound states can be purely fast-moving or
purely slow-moving, giving rise to incommensurate energy level spacings and a
vernier spectrum. In this work, we present evidence for this vernier spectrum
in Coulomb blockade measurements of ultraclean suspended carbon nanotube
quantum dots. The addition-energy spectrum of the quantum dots reveals an
energy-level structure that oscillates between aligned and misaligned energy
levels. Our data suggest that the fast- and slow-moving bound states hybridize
at certain gate voltages. Thus, gate-voltage tuning can select states with
varying degrees of hybridization, suggesting numerous applications based on
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mismatched lengths, as can occur in quasiperiodic systems. However, not all
commensuration effects are spatial in nature. In finite-sized Dirac systems, an
intriguing example arises in tilted or warped Dirac cones wherein the
degeneracy in the speed of right- and left-moving electrons within a given
Dirac cone or valley is lifted. Bound states can be purely fast-moving or
purely slow-moving, giving rise to incommensurate energy level spacings and a
vernier spectrum. In this work, we present evidence for this vernier spectrum
in Coulomb blockade measurements of ultraclean suspended carbon nanotube
quantum dots. The addition-energy spectrum of the quantum dots reveals an
energy-level structure that oscillates between aligned and misaligned energy
levels. Our data suggest that the fast- and slow-moving bound states hybridize
at certain gate voltages. Thus, gate-voltage tuning can select states with
varying degrees of hybridization, suggesting numerous applications based on
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mismatched lengths, as can occur in quasiperiodic systems. However, not all
commensuration effects are spatial in nature. In finite-sized Dirac systems, an
intriguing example arises in tilted or warped Dirac cones wherein the
degeneracy in the speed of right- and left-moving electrons within a given
Dirac cone or valley is lifted. Bound states can be purely fast-moving or
purely slow-moving, giving rise to incommensurate energy level spacings and a
vernier spectrum. In this work, we present evidence for this vernier spectrum
in Coulomb blockade measurements of ultraclean suspended carbon nanotube
quantum dots. The addition-energy spectrum of the quantum dots reveals an
energy-level structure that oscillates between aligned and misaligned energy
levels. Our data suggest that the fast- and slow-moving bound states hybridize
at certain gate voltages. Thus, gate-voltage tuning can select states with
varying degrees of hybridization, suggesting numerous applications based on
accessing this isospin-like degree of freedom.</abstract><doi>10.48550/arxiv.2311.12332</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Mesoscale and Nanoscale Physics |
| title | Vernier Spectrum and Isospin State Control in Carbon Nanotube Quantum Dots |
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