Deterministic inverse design of Tamm plasmon thermal emitters with multi-resonant control

He, Mingze; Nolen, J. Ryan; Nordlander, Josh; Cleri, Angela; McIlwaine, Nathaniel S.; Tang, Yucheng; Lu, Guanyu; Folland, Thomas G.; Landman, Bennett A.; Maria, Jon Paul; Caldwell, Joshua D.

doi:10.1038/s41563-021-01094-0

Cited by 49 publications

(44 citation statements)

References 44 publications

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“…Importantly, due to the unique low-loss nature of the topological transition, it was possible to visualize intermediate propagating states, which permits the unveiling of the topological origin of the transition. The general and fundamental characters of these findings extend the unique possibilities of twisted polaritons discussed above to develop optical applications requiring propagation of the electromagnetic energy flow along specific directions, for example, directional coupling between molecules or quantum emitters or directional thermal management. − …”

Section: Engineering Polariton Anisotropy Through Hybrid Materialsmentioning

confidence: 70%

Anisotropy and Modal Hybridization in Infrared Nanophotonics Using Low-Symmetry Materials

Folland

Duan

et al. 2022

ACS Photonics

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Anisotropy has been a key property employed in the design of optical components for hundreds of years. However, in recent years there has been growing interest in polaritons supported within anisotropic (low crystal symmetry) materials for their ability to compress light to smaller, deeply subwavelength dimensions. While historically the first anisotropic polaritons probed were hyperbolic modes, research into anisotropic materials has recently turned toward hybrid materials and optical modes, employing phenomena such as phonon confinement, polaritonic strong coupling, and Moiré structures to design the optical properties. In this Perspective, we will briefly introduce the physics and theories of polariton anisotropy, review recently investigated anisotropic and two-dimensional materials, and then move on to a discussion of approaches toward realizing hybrid modes and identifying new materials. Based on the results from the past few years, we extend these discussions to highlight outstanding challenges and outline what we perceive as promising paths to further explore the potential for polariton anisotropy and hybrid systems in future nanophotonic optical devices.

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Section: Engineering Polariton Anisotropy Through Hybrid Materialsmentioning

confidence: 70%

Anisotropy and Modal Hybridization in Infrared Nanophotonics Using Low-Symmetry Materials

Folland

Duan

et al. 2022

ACS Photonics

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“…This gap-dependent SEIRA not only shows the benefits of quantum mechanical effects of plasmonic nanocavities for the plasmonic enhanced optical process at mid-infrared frequencies but also indicates SEIRA as an ideal probe for examining the field enhancement of mid-infrared plasmonic nanocavities with precision as high as ∼1 Å. Moreover, the pronounced SEIRA, especially the case with a subnanometer gap, shows CdO as a promising mid-infrared plasmonic material, which recently has also been used for the design of mid-infrared thermal emitters with a narrow band . Our work demonstrates the new possibility of elevating the field enhancement and SEIRA sensitivity of mid-infrared plasmonic nanocavities and paves the way for novel design of plasmonic nanocavities with elevated SEIRA sensitivity.…”

mentioning

confidence: 85%

“…The semiconducting CdO nanocrystal was chosen because of its prominent mid-infrared plasmonic responses (Supporting Information section S1). ,− Meanwhile, the plasmonic resonance of CdO nanocrystals could be readily tuned over a large frequency range via the particle size, based on the inverse scaling relationship between the carrier concentration and size . The gold nanoparticle was introduced to couple to the CdO nanocrystal in order to facilitate the immobilization of molecules.…”

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confidence: 99%

Elevating Surface-Enhanced Infrared Absorption with Quantum Mechanical Effects of Plasmonic Nanocavities

et al. 2022

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Plasmonic nanocavities, with the ability to localize and concentrate light into nanometer-scale dimensions, have been widely used for ultrasensitive spectroscopy, biosensing, and photodetection. However, as the nanocavity gap approaches the subnanometer length scale, plasmonic enhancement, together with plasmonic enhanced optical processes, turns to quenching because of quantum mechanical effects. Here, instead of quenching, we show that quantum mechanical effects of plasmonic nanocavities can elevate surface-enhanced infrared absorption (SEIRA) of molecular moieties. The plasmonic nanocavities, nanojunctions of gold and cadmium oxide nanoparticles, support prominent mid-infrared plasmonic resonances and enable SEIRA of an alkanethiol monolayer (CH 3 (CH 2 ) n−1 SH, n = 3−16). With a subnanometer cavity gap (n < 6), plasmonic resonances turn to blue shift and the SEIRA signal starts a pronounced increase, benefiting from the quantum tunneling effect across the plasmonic nanocavities. Our findings demonstrate the new possibility of optimizing the field enhancement and SEIRA sensitivity of mid-infrared plasmonic nanocavities.

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“…Furthermore, the angular dependency with varying polarization was compared, which shows less dispersive properties under s-polarization, otherwise p-polarization light affects typically more dispersive (Figure S13, Supporting Information). [13,25,38] As exhibited in Figure S14 designed structure shows great angular dependency even under p-polarized light, which offers a promising applicability as a photo detection device (see Supporting Information). The angle insensitive performance could be explained by the fact that phase shift accumulated during the propagation through the DBR layers is relatively insignificant due to the small optical thickness of the DBR layers which originated from the high refractive indices of a-Ge/P r -75%.…”

Section: Numerical Comparison For Each Configurationmentioning

confidence: 98%

“…Creating strongly coupled narrow absorption in the near infrared region is a critical requisite for investigating highly DBR and metal layer, they represented higher Q factor and thinner configuration than conventional case. [25][26][27] Nevertheless, the material selection limitation and the fact that N is tunable within an only integer range make perfect matching of Z difficult. Further, owing to the residual parasitic absorption that occurs in dielectric materials, increased N reduces the radiative loss and increases the nonradiative loss.…”

Section: Introductionmentioning

confidence: 99%

Single‐Material, Near‐Infrared Selective Absorber Based on Refractive Index‐Tunable Tamm Plasmon Structure

Kim

Yoo

et al. 2022

Advanced Optical Materials

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efficient photonic applications such as near infrared spectra analysis, [1] telecommunications, [2] biomedical and chemical sensing. [3] Rapidly advancing plasmonics are of particular interest, along with their selective light-trapping with strongly localized photon energy, surface plasmons (SPs) have attracted attention due to their potential applications in medicine and chemistry, [4,5] as well as optical switching and near-field photonics. [6][7][8] However, many studies still rely on the Kretschmann-Raether excitation method, [9] requiring additional equipment to couple external light to surface modes at high angles of incidence (such as prisms), [10] or demand a metal/dielectric hybrid systems with delicately designed nanostructures to localize the photon energy in a deep-subwavelength region. [11] Unlike SPs, Tamm plasmons (TPs) can be directly observed with direct incidence without prism couplers and/or nanostructure. Also, the TPs structure can support surface waves dispersed within the light cone. [12] Optical TPs can form at the interfaces between distributed Bragg reflectors (DBRs) and with layers having optical thicknesses (t opt ) close to half the wavelength of light, similar to the electronic states that can occur in the energy bandgap of a crystal surface. [13,14] Because of their scalability and spectral tunability with a high quality (Q)-factor, and as sophisticated patterning is not required, TPs can be exploited in high-efficiency photonic applications; e.g., for photodetection, photocatalysis, biomedical diagnostics, and industrial process monitoring. [9,[15][16][17][18] Based on these theoretical advantages, the design and fabrication of real TP structures for practical applications have been studied. Recent approaches utilizing cavity-layer coupling, additional layers such as metasurfaces, [19] topological insulators, [20] and two-dimensional (2D) materials, including graphene and transition metal dichalcogenides, [21][22][23][24] have enhanced the available TP modes through adjustment of additional coupling. However, although these attempts successfully enhanced the resonator performance, they diminished the manufacturing advantages of the TP and planar structure. From the design point of view for satisfying both performance and manufacturing issues, DBR layers were stacked onto the metal reflector as a reversed structure from conventional TP structure. With reduced pairs of periodic layers (N) and by matching the impedance (Z) between As a powerful planar plasmonics, Tamm plasmon (TP) structures open up new possibilities for high-efficiency photonic applications demanding high quality (Q)-factor with scalability and spectral tunability. Despite the theoretical advantages of TP structures, TP configurations alternately stacked within limited materials and integer ranges result in thicker device sizes and still struggle to achieve ideal designs. Here, by introducing a computational model with varying design parameters, the configurations of highperformance TPs are presented within thin scal...

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Deterministic inverse design of Tamm plasmon thermal emitters with multi-resonant control

Cited by 49 publications

References 44 publications

Anisotropy and Modal Hybridization in Infrared Nanophotonics Using Low-Symmetry Materials

Anisotropy and Modal Hybridization in Infrared Nanophotonics Using Low-Symmetry Materials

Elevating Surface-Enhanced Infrared Absorption with Quantum Mechanical Effects of Plasmonic Nanocavities

Single‐Material, Near‐Infrared Selective Absorber Based on Refractive Index‐Tunable Tamm Plasmon Structure

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