Emergence of tunable intersubband-plasmon-polaritons in graphene superlattices

Fig. 1. Engineering of SL electric potential in graphene. (a) Physical realization: field-effect carrier density modulation using a metagate/backgate combination. Inset: SL potential $U_{E} (x)$ on a schematically exposed graphene plane ( $V_{B} = - 9 V$ ). (b) Electrostatic simulation of (a): $E_{z}$ (color-coded) and the electric field lines in the $x - z$ plane. (c) The doped carrier density $n (x)$ (top), the Fermi level $E_{F} (x)$ (middle), and the SL electric potential $U_{E} (x)$ (bottom) for three backgate voltages: $V_{B} = 12 V$ (dotted red), $V_{B} = - 6 V$ (dashed blue), and $V_{B} = - 9 V$ (solid green). Backgate/metagate parameters for (a)–(c): $h_{t} = 5 nm$ , $h_{b} = 10 nm$ , $h_{g} = 10 nm$ , $h_{0} = 150 nm$ , $L = 300 nm$ , $S = 80 nm$ , and $V_{M} = 1 V$ .

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Fig. 2. The TIREDD mechanism is responsible for flat subbands of graphene electrons in SL electric potentials. (a) Left: no intersubband gaps for $k_{y} = 0$ Dirac electrons due to Klein tunneling. Filled bands ( $E$ < $μ_{0} = 0$ ): blue, unoccupied bands $E$ > $0$ : green. Green dots: original Dirac crossing points prior to band folding. Right: emergence of intersubband gaps for large- $k_{y}$ electrons, strongly modulated SL potential. (b) Top, dashed lines: energy levels of several examples of bound states located right below the Fermi surface (i) at the lowest energy of the conduction-band TIREDD and (ii) at the highest energy of the valence band TIREDD. The energy levels are defined relative to the SL potential landscape ( $V_{B} = - 9 V$ ). Solid green line: SL electric potential $U_{E} (x)$ . Bottom three: wave function amplitudes $ψ^{†} ψ$ of (i)–(iii). Negligible tunneling between the adjacent SL periods: emergence of the flat subbands. (c) TIREDD of (top) conduction and (bottom) valence band Dirac electrons. Circles: iso-energy contours in the momentum space at the centers of the EW and EC regions. Dashed lines: energy levels, green lines: the SL potential. SL parameters: same as in Fig. 1.

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Fig. 3. The massless dispersion of Dirac electrons makes the ISBT energy be nearly uniform over a broad region of the Fermi surface ( $E = 0$ ). The electronic subband structure ( $V_{B} = - 9 V$ case) is shown along $k_{y}$ at a fixed $k_{x} = 0$ ; any choice of $k_{x}$ value would produce similar subband dispersions along $k_{y}$ , since the subbands at moderately high $k_{y}$ become flat in $k_{x}$ direction, as shown in Fig. 2(a). Each vertical black bar is given as a guide to the eye for denoting a vertical transition ( $Δ j = 1$ ) from an occupied state below the Fermi surface to a state above the Fermi surface, and all bars have the same length. In this case, the ISBT energy appears as very uniform roughly within $6 π / L < | k_{y} | < 15 π / L$ , which is almost 45% of the whole area of the Fermi surface $| k_{y} | < 20 π / L$ .

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Fig. 4. Optical conductivity and ISBT resonances for SL-modulated graphene electrons. (a) Real part of the conductivity $Re [σ_{x x} (q = q \hat{x}, q^{'} = q^{'} \hat{x}; ω)]$ calculated for $q = q^{'}$ . With strongly modulated SL potentials ( $V_{B} = - 6 V$ , $- 9 V$ ), ISBTs are manifested as Lorenzian peaks in $σ$ . (b) Both real (left) and imaginary (right) parts of the conductivity calculated at $q = q^{'} = 0$ (top) and $q = q^{'} = \frac{π}{2 L}$ (bottom); solid thin black: no modulation ( $E_{F} = 0.15 eV$ ), dotted red: $V_{B} = 12 V$ , dashed blue: $- 6 V$ , and solid thick green: $- 9 V$ .

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Fig. 5. HIPP dispersion with USC and far-field detection of HIPPs. (a) Density of states or $- Im [Tr ({[ϵ (q, ω)]}^{- 1})]$ for visualizing the polaritonic dispersion, calculated with Drude conductivity model that cannot capture the ISBT features. (b) Reflection spectra (light polarized along the $x$ axis and normal incidence) at low frequency (below the first plasmonic bandgap) calculated with Drude conductivity model; dotted red: $V_{B} = 12 V$ , dashed blue: $- 6 V$ , and solid green: $- 9 V$ . (c) Density of states calculated with Kubo conductivity as given in Eq. (3); the white dashed lines in $V_{B} = - 9 V$ panel are denoting the same frequencies of the ISBT resonances ( $Δ j = 1, 2, \dots$ ) shown in Fig. 4(a), and the corresponding (d) reflection spectra. (e) The same results as in panel (c) zoomed at a low-frequency and low-momentum window; the star markers refer to the HIPP modes at $q = 0$ that appear as resonant peaks in the reflection spectra in (d), and the white dotted lines are guides to the eye for the lowest and the second lowest HIPP bands.