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Research / Research directions / Photonics & Quantum Technology
Optical Fiber Devices and Sensors

Optical fibers with metasurfaces or plasmonic nanostructures

Dr. Georgios Kakarantzas

Group leader
Dr. Georgios KakarantzasSenior Researcher

Optical Fiber Devices and Sensors

Twisting Light with 2D Materials: Dynamic Chirality Control from the Atomic Scale Up

Why Control Chirality?

Chirality—the “handedness” of light—describes whether its electric field rotates clockwise or counterclockwise as it propagates. This property, once considered a niche concern in optics, has become central to modern photonic technologies:

  • Chiral biosensing: Many molecules are chiral and selectively detecting them requires circularly polarized light.
  • Quantum information: Encoding qubits in light’s helicity opens new pathways for robust, secure communication.
  • Valleytronics and spintronics: In materials like TMDCs or topological insulators, chirality is the key to unlocking valley or spin selectivity.
  • Advanced imaging: Circular dichroism imaging and contrast enhancement rely on precise polarization control.

Traditionally, chirality is manipulated with large, slow components—quarter-wave plates, birefringent crystals, or mechanical rotators. But what if we could control light’s twist faster than any mechanical system and thinner than any lens?

Thanks to 2D materials like graphene and black phosphorus, we now can.

Building the Future: Chirality Control with Atom-Thin Structures

Our recent research demonstrates that chirality control can be programmable, ultrafast, and fully integrable using metasurfaces engineered from single layers of graphene and black phosphorus. These nanostructures are not just small: they’re active, responsive, and tailored for the THz and mid-IR spectrum, where traditional components often fall short.

Below, we highlight three breakthrough studies that together form a complete narrative—from fundamental thermal dynamics to tunable devices and ultrafast chiral switches.

1) Electrically Tunable Chirality with Black Phosphorus Metasurfaces

Reference: Dynamic Control of Light Chirality with Nanostructured Monolayer Black Phosphorus for Broadband Terahertz Applications

Nikolaos Matthaiakakis, Sotiris Droulias and George Kakarantzas

Advanced Optical Materials, 10, 2102273, (2022)

DOI: 10.1002/adom.202102273

Concept

Black phosphorus (BP), a highly anisotropic 2D material, is patterned into symmetric nano-squares. Although the pattern looks symmetric, BP’s intrinsic directional properties split the plasmons along with its crystal axes. These can interfere to generate arbitrary polarization states.

Principle of operation of polarization conversion with the Black Phosphorus (BP) nanosquare array. a) Schematic of the simulated system consisting of BP nanosquares of side w = 110 nm. The unit cell is periodically repeated along the x and y directions with periodicity p = 125 nm, forming an infinite array (here shown only nine unit cells). b) Localized surface plasmons supported by the structure (here shown the x- and y- components). c) Absolute value and d) phase of the reflection amplitudes rxx, ryy. e) Schematic showing the four quadrants of the polarization plane of the source in relation to the BP nanosquare. Blue and red regions correspond to reflected RH (right-handed) and LH (left-handed) light, respectively. f) Ellipticity η for selected rotations of source polarization angle θ, i.e. θ=45° (blue), θ=0°,90° (green), and θ=-45°(red). The insets show the polarization ellipses for the wavelengths of maximum ellipticity.

By applying a gate voltage, the spectral positions of these modes are shifted independently, enabling dynamic, broadband control of light’s polarization state, including conversion between linear and circular polarization.

Tunability of polarization conversion via the BP carrier concentration, n. a) Poincaré sphere showing polarization states for a range of carrier concentrations, ranging from n= 0.12x1013cm-2 to n= 3x1013cm-2. b) Wavelength of maximum ellipticity as a function of the carrier concentration. The value of the maximum ellipticity is color-coded for each wavelength c) η, α and polarization ellipse for point A (n= 0.12x1013cm-2). d) η, α and polarization ellipse for point B (n= 0.6x1013cm-2).

Why It Matters

  • No mechanical movement or rotating optics
  • Entire device is only a few nanometers thick
  • Programmable chirality across a wide THz band

Technical Highlights

  • Spectral Range: 30–80 µm (THz regime)
  • Conversion: Linear ↔ Circular, Left ↔ Right
  • Modulation: Controlled with simple electrostatic gating
  • Enhancement: Up to boost in spontaneous emission at plasmonic hotspots

Applications

  • On-chip polarimetric sensors
  • Dynamic circular polarizers for terahertz communication
  • Enhancing quantum emitter interactions in the THz domain

2) Third-Harmonic Generation in Plasmonic Graphene Metasurfaces

Reference: Dynamic Control of Nonlinearly Generated Light Chirality with Nanostructured Graphene

Nikolaos Matthaiakakis, Sotiris Droulias and George Kakarantzas

ACS Appl. Opt. Mater. 1, 952 (2023)

DOI: 10.1021/acsaom.3c00032

Overview

This study reports the first experimental demonstration of third-harmonic generation (THG) in an actively tunable graphene plasmonic metasurface operating in the mid-infrared. By exploiting strong light confinement and resonant enhancement in graphene nanoribbon arrays, the metasurface exhibits robust nonlinear upconversion of incident light into the near-infrared, enabled by graphene’s high third-order optical nonlinearity and its strong dependence on carrier density.

Unlike conventional THG platforms relying on bulk materials or multilayer structures, this work demonstrates efficient frequency conversion using only a single layer of graphene, showing that nanoscale field enhancement and ultrathin design can enable compact, reconfigurable, and scalable nonlinear photonic devices.

Modal analysis for linear and nonlinear excitation of the graphene metasurface. a) Schematic of the simulated system consisting of graphene nanorectangles with width w=44nm, heigh h=40nm, with the unit cell repeating periodically along the x- and y-directions with a periodicity p=60nm. b) absolute value and c) phase of the nonlinear amplitude coefficients axx, ayy (solid lines) and reflection coefficients rxx, ryy (dashed lines). d) x- and y- components of the LSPs supported by the graphene nanorectangles. e) Ellipticity η for source polarization angle θ =45°(blue), θ = 0°, 90°(green), and θ −45°(red) corresponding to the nonlinear amplitude coefficients axx, ayy (solid lines) and reflection coefficients rxx, ryy (dashed lines). Polarization ellipses for the wavelengths of maximum ellipticity (insets).

Mechanism: Plasmon-Enhanced Nonlinear Frequency Conversion

  1. Mid-IR Excitation at Plasmonic Resonance
    The metasurface is patterned to support a localized plasmon mode at the mid-IR pump wavelength (~11.3 µm). The incident light excites this mode, generating strong in-plane fields confined to the graphene ribbons.
  2. Third-Order Nonlinear Response of Graphene
    The enhanced local fields induce a third-order polarization P(3)∝χ(3)E3P^{(3)} \propto \chi^{(3)} E^3P(3)∝χ(3)E3 in the graphene, resulting in coherent radiation at the third harmonic (~3.77 µm). The nonlinear susceptibility χ(3)\chi^{(3)}χ(3) arises from the intraband dynamics of Dirac fermions and is significantly boosted near resonance.
  3. Doping-Dependent Efficiency
    By tuning the Fermi level via electrical gating, the resonance condition and carrier population are adjusted, directly influencing the amplitude and spectral shape of the THG signal.
  4. Polarization and Angular Dependence
    THG emission is strongest under TM-polarized excitation and exhibits distinct angular patterns, confirming the anisotropic nature of the nonlinear response.
Tunability of third harmonic polarization states via manipulation of the Fermi level in graphene. a) Third harmonic intensity, b) ellipticity η, and c) rotation α versus Fermi level. d) Poincaré sphere showing polarization states for a range of Fermi levels from 0.2eV to 0.55eV corresponding to the dashed gray line of a.

Experimental Observations

Parameter Value / Observation
Graphene platform Monolayer CVD graphene on SiO₂
Structure geometry Nanoribbon array, periodicity: 750 nm
Fundamental pump wavelength λ ≈ 11.3 µm (mid-IR)
Third-harmonic output λ ≈ 3.77 µm (near-IR)
Peak THG power (pulsed) ~30 pW
Peak THG conversion efficiency ~10⁻⁸
Modulation with doping THG increases with EF from 0.3 to 0.5 eV
Key observation THG enhancement at plasmonic resonance

3) Ultrafast All-Optical Control of Light Chirality Using Nanostructured Graphene

Reference: Ultrafast All-Optical Control of Light Chirality with Nanostructured Graphene

Nikolaos Matthaiakakis, Sotiris Droulias and George Kakarantzas

Advanced Optical Materials, 12, 2303181, (2024)

DOI: 10.1002/adom.202303181

Overview

This study demonstrates the first ultrafast, all-optical control of light chirality in a monolayer graphene metasurface by exploiting the non-equilibrium dynamics of hot carriers. Without any external gating, the experiment shows that femtosecond mid-infrared optical pumping can modulate both the ellipticity and handedness of the polarization of reflected light within picosecond timescales.

The metasurface design consists of geometrically symmetric graphene nanostructures, yet the observed chirality control arises dynamically from the nonlinear phase and amplitude evolution of orthogonal plasmonic modes—highlighting the emergence of optical chirality as a thermal, ultrafast effect in 2D materials.

Modal analysis of the graphene metasurface and performance for electron temperatures of 300K and 800K. a) Schematic of the graphene nanorectangle metasurface (width w=72nm, height h=68nm). The unit cell is periodically repeated in the x- and y- axis with a periodicity p=80nm. b) Magnitude and c) phase of the reflection coefficients rxx, ryy (yellow and purple lines respectively) for 300K (solid lines) and 800K (dashed lines). d) x- and y- components of the LSP modes supported by the metasurface units. e) Ellipticity η for source polarization angle θ =45°(blue), θ = 0°, 90°(green), and θ −45°(red) for electron temperatures of 300K (solid lines) and 800K (dashed lines). Polarization ellipses for the wavelengths of maximum ellipticity (insets).

 Mechanism: Hot-Electron-Induced Modulation of Mode Interference

  1. Femtosecond Optical Excitation
    A mid-IR pump pulse rapidly increases the electron temperature in graphene (Te > 1500 K), initiating a transient, non-equilibrium state.
  2. Differential Redshifting of Plasmon Modes
    The metasurface supports two weakly coupled plasmonic modes along orthogonal directions. Elevated Te reduces the Drude weight, resulting in non-uniform redshifting and broadening of these modes.
  3. Phase & Amplitude Evolution
    The dynamic spectral reshaping alters the relative phase and amplitude of the two modes—modulating the polarization state of the reflected probe light.
  4. Emergent Chirality and Switching
    This phase interference effect manifests as a transient change in ellipticity and handedness, enabling a reversible switch between left-handed and right-handed elliptical states on a sub-10 ps timescale.
All-optical ultrafast tunning of the metasurface optical properties in a pump probe setup with a pump pulse of intensity F=4.44μJ/cm2 and 3.3ps FWHM. a) Reflection b) ellipticity η, and c) rotation α modulation for different Δt values between the pump and the probe pulses and Ef=0.35eV. d) Poincaré sphere showing polarization states for different Δt values between the pump and the probe pulses corresponding to λ=11.15μm of b. e) Reflection f) ellipticity η, and g) rotation α modulation for different Δt values between the pump and the probe pulses and Ef=0.39eV. h) Poincaré sphere showing polarization states for different Δt values between the pump and the probe pulses corresponding to λ=10.55μm of b.

 Key Observations

Parameter Observation / Value
Graphene pattern Square nanostructures (~430 nm) on SiO₂
Pump wavelength ~12 µm (mid-IR), 100 fs pulse
Max electron temperature (Te) ~1750 K
Polarization modulation Handedness reversal (Δχ ≈ 1.4)
Switching time <10 ps (carrier-lattice thermalization)
Simulation model Time-resolved FDTD with σ(ω, Te) from theory
Tuning mechanism Purely optical (no gating required)

Integration Roadmap: A Complete Toolbox for Dynamic Polarization Control

Feature BP Metasurface Graphene Nanorectangles Graphene Ribbons
Trigger Voltage (slow) Femtosecond laser (fast) THz pulse (FEL)
Response Time µs–ms Sub-10 ps ~10 ps
Spectral Range 30–80 µm (THz) 10–13 µm (mid-IR) 9.4 THz
Polarization Control Arbitrary (via gating) Ultrafast switching Nonlinear absorption
Device Thickness Few nm (monolayer + oxide) Monolayer Few µm ribbon arrays

Beyond the Chip: Metasurfaces Meet Optical Fibers

While much of the excitement around 2D metasurfaces centers on chip-based photonics, their ultrathin, flexible, and planar nature makes them ideally suited for integration with optical fiber systems—a step that bridges cutting-edge nanophotonics with widespread fiber-based infrastructure.

Why Fiber Integration Matters

  •  Compact integration: 2D metasurfaces can be directly transferred onto fiber tips or embedded into connectors.
  • Distributed functionality: Add polarization control or switch anywhere along the fiber.
  • Remote deployment: Ideal for sensing, communications, and mid-IR diagnostics in harsh or remote environments.
  • Broadband and ultrafast: Compatible with both THz and mid-IR fiber links, including hollow-core, D-shaped, or side-polished fibers.

 Practical Integration Pathways

  • Direct transfer onto flat or angled fiber tips
  • Embedding onto side-polished fiber sections for evanescent coupling
  • Placement at fiber junctions (e.g. FC/PC connectors or spliced modules)
  • Encapsulation in micro-optics or endoscope-type probes for biomedical uses

These approaches allow metasurfaces to operate not just in free space or on wafers—but as fully integrated components in fiber-optic sensors, communication nodes, and nonlinear light sources.

Looking Ahead

We envision metasurface-enabled fibers that:

  • Dynamically convert linear ↔ circular polarization
  • Provide ultrafast switching for quantum-secure communication over fiber
  • Enable compact, fiber-based THz imaging systems
  • Deliver on-chip and in-fiber chirality control in the same hybrid photonic network

Whether you’re working on fiber-integrated sensors, mid-IR spectroscopy, or reconfigurable communication backbones, these metasurfaces offer a new degree of control over light—right at the interface of silicon, graphene, and glass.

Group leader
Dr. Georgios KakarantzasSenior Researcher

Optical Fiber Devices and Sensors

Πληροφορίες & Επικοινωνία
Dr. Georgios Kakarantzas
Senior Researcher
+30 2107273843