Crossover from Nonthermal to Thermal Photoluminescence from Metals Excited by Ultrashort Light Pulses

Sivan, Yonatan; Un, Ieng-Wai; Kalyan, Imon; Lin, Kai-Qiang; Lupton, John M.; Bange, Sebastian

doi:10.1021/acsnano.3c01016

Cited by 13 publications

(7 citation statements)

References 90 publications

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“…While the assumptions of the phenomenological description of the plasmon-to-photon transduction and some standard approximations in the near-field simulation model may partially account for these differences, they underline the still lacunary knowledge of the mechanism of the remote generation of NPL photons in spite of recent theoretical advances. 25,26 Generalization of Holistic Arithmetic and Logic Units. The design, identification, and location of ALU functions with increasing Boolean complexity implemented within plasmonic cavities is a tedious and time-consuming task.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Nevertheless, in contrast to confocal map simulations, , some minor differences are visible in the relative intensities at the apexes. While the assumptions of the phenomenological description of the plasmon-to-photon transduction and some standard approximations in the near-field simulation model may partially account for these differences, they underline the still lacunary knowledge of the mechanism of the remote generation of NPL photons in spite of recent theoretical advances. , …”

Section: Resultsmentioning

confidence: 99%

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Compact Implementation of a 1-Bit Adder by Coherent 2-Beam Excitation of a Single Plasmonic Cavity

Dell’Ova,

Brûlé,

Gros

et al. 2024

ACS Photonics

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We demonstrate experimentally the dual beam optical drive of an interconnect-free 2-input, 2-output 1-bit adder implemented inside a single gold plasmonic cavity, focused ion milled in an ultrathin single crystalline gold microplate. To obtain this result, we have set a coherent 2-beam excitation scheme up that allows us to independently and arbitrarily choose the intensity, polarization, and relative phase shift of two femtosecond-pulsed laser spots. The spots are focused on any chosen location of the micrometer-sized plasmonic cavity. The nonlinear photoluminescence (NPL) response of the cavity encodes the Boolean output, while the Boolean inputs are borne by the linear polarizations of the excitation. A generic map analysis tool is developed to pinpoint the realized Boolean functions and to assess their robustness. This tool is used to demonstrate the experimental implementation of the elusive XOR gate and its combination with an AND gate in the same cavity to perform the full 1-bit adder. The analysis of 160,000 instances of the 1-bit adder clearly shows the soundness of our approach and reveals some underlying mechanistic features of the remotely generated NPL. These results establish the first practical step of a general approach to cascade-free all-optical arithmetic and logic units.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Compact Implementation of a 1-Bit Adder by Coherent 2-Beam Excitation of a Single Plasmonic Cavity

Dell’Ova,

Brûlé,

Gros

et al. 2024

ACS Photonics

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“…1 d 12 , 50 . To the best of our knowledge, precise numerical modeling of the PLE lineshape for such non-Fermi distributions has not yet been attempted, although several studies have investigated the spectral character of emission with a non-Fermi term 22 , 30 .…”

Section: Resultsmentioning

confidence: 99%

“…An isolated single nanostructure avoids ensemble averaging that can obscure the intrinsic mechanisms of NPL, which has motivated the studies of broadband emission from single nanoparticles, dimers, and few-particle aggregates 13 – 22 . These studies showed that the hot-electron intraband model, while accounting for the PL emission from rough films, may not provide a good approximation for isolated nanostructures.…”

Section: Introductionmentioning

confidence: 99%

Non-thermal emission in gap-mode plasmon photoluminescence

Lemasters,

Manjare,

Freeman

et al. 2024

Nat Commun

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Photoluminescence from spatially inhomogeneous plasmonic nanostructures exhibits fascinating wavelength-dependent nonlinear behaviors due to the intraband recombination of hot electrons excited into the conduction band of the metal. The properties of the excited carrier distribution and the role of localized plasmonic modes are subjects of debate. In this work, we use plasmonic gap-mode resonators with precise nanometer-scale confinement to show that the nonlinear photoluminescence behavior can become dominated by non-thermal contributions produced by the excited carrier population that strongly deviates from the Fermi-Dirac distribution due to the confinement-induced large-momentum free carrier absorption beyond the dipole approximation. These findings open new pathways for controllable light conversion using nonequilibrium electron states at the nanoscale.

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“…The illumination of metallic nanostructures by ultrashort laser pulses at near-IR wavelengths induces a broadband upconverted emission spanning the visible spectral regime. Under high-intensity femtosecond excitation, this nonlinear signal has been shown to be dominated by a thermal luminescence continuum emitted by out-of-equilibrium surface electrons with transiently elevated temperatures. − Indeed, following the absorption of the light pulse, the temperature of the electron gas at the surface of the metal can reach thousands of kelvins for about a picosecond , and radiates before equilibrating with the phonons. − This nonlinear photoluminescence (N-PL) has been studied on a wide range of plasmonic geometries and materials. ,− An important feature is the dramatic signal enhancement observed from hot-spots favored by the presence of localized resonances (e.g., at nanoparticles , ). Such local signal enhancements are observed because the luminescence emanates from hot thermal electrons generated at the surface of the metal. ,, Further, in structures sustaining surface plasmon propagation (e.g., nanowires, cavities), N-PL has been shown to be spatially distributed throughout the modal landscape. , Hence, N-PL has been a key observable to unlock ultrafast light–matter interactions, and this response has found numerous usages.…”

Section: Introductionmentioning

confidence: 99%

Memristive Control of Plasmon-Mediated Nonlinear Photoluminescence in Au Nanowires

Sharma,

Agreda,

Dell’Ova

et al. 2024

ACS Nano

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Nonlinear photoluminescence (N-PL) is a broadband photon emission arising from a nonequilibrium heated electron distribution generated at the surface of metallic nanostructures by ultrafast pulsed laser illumination. N-PL is sensitive to surface morphology, local electromagnetic field strength, and electronic band structure, making it relevant to probe optically excited nanoscale plasmonic systems. It also has been key to accessing the complex multiscale time dynamics ruling electron thermalization. Here, we show that plasmon-mediated N-PL emitted by a gold nanowire can be modified by an electrical architecture featuring a nanogap. Upon voltage activation, we observe that N-PL becomes dependent on the electrical transport dynamics and can thus be locally modulated. This finding brings an electrical leverage to externally control the photoluminescence generated from metal nanostructures and constitutes an asset for the development of emerging nanoscale interface devices managing photons and electrons.

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Crossover from Nonthermal to Thermal Photoluminescence from Metals Excited by Ultrashort Light Pulses

Cited by 13 publications

References 90 publications

Compact Implementation of a 1-Bit Adder by Coherent 2-Beam Excitation of a Single Plasmonic Cavity

Compact Implementation of a 1-Bit Adder by Coherent 2-Beam Excitation of a Single Plasmonic Cavity

Non-thermal emission in gap-mode plasmon photoluminescence

Memristive Control of Plasmon-Mediated Nonlinear Photoluminescence in Au Nanowires

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