Experimental and 
<i>Ab Initio</i>
 Ultrafast Carrier Dynamics in Plasmonic Nanoparticles

Brown, Ana M.; Sundararaman, Ravishankar; Narang, Prineha; Schwartzberg, Adam M.; Goddard, William A.; Atwater, Harry A.

doi:10.1103/physrevlett.118.087401

Cited by 132 publications

(166 citation statements)

References 48 publications

(135 reference statements)

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“…Experimentally, this spatial inhomogeneity on the tens to hundreds of nanometers is vital to understand hot carrier imaging, photodetection, photovoltaic and photochemical energy conversion, which all involve carrier collection into a semiconductor or molecule. [54,55] However, optical probes of the carrier response (which we can predict quantitatively using our first-principles framework as shown previously [53]) cannot sense this inhomogeneity due to the diffraction limit, Aluminum is less efficient at collecting low energy carriers due to a shorter electron-phonon scattering mean free path, but enhances high-energy electron collection compared to gold because of increased generation of (and comparable mean free paths for) high-energy electrons. and instead measure a spatially-averaged result.…”

Section: Resultsmentioning

confidence: 88%

Transport of hot carriers in plasmonic nanostructures

Jermyn

Tagliabue

Atwater

et al. 2019

Phys. Rev. Materials

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Plasmonic hot carrier devices extract excited carriers from metal nanostructures before equilibration, and have the potential to surpass semiconductor light absorbers. However their efficiencies have so far remained well below theoretical limits, which necessitates quantitative prediction of carrier transport and energy loss in plasmonic structures to identify and overcome bottlenecks in carrier harvesting. Here, we present a theoretical and computational framework, Non-Equilibrium Scattering in Space and Energy (NESSE), to predict the spatial evolution of carrier energy distributions that combines the best features of phase-space (Boltzmann) and particle-based (Monte Carlo) methods. Within the NESSE framework, we bridge first-principles electronic structure predictions of plasmon decay and carrier collision integrals at the atomic scale, with electromagnetic field simulations at the nano-to mesoscale. Finally, we apply NESSE to predict spatially-resolved energy distributions of photo-excited carriers that impact the surface of experimentally realizable plasmonic nanostructures at length scales ranging from tens to several hundreds of nanometers, enabling first-principles design of hot carrier devices.Surface plasmon resonances shrink optics to the nano scale, facilitating strong focusing and localized absorption of light [1][2][3][4][5]. Decay of plasmons generates energetic electrons and holes in the material that can be exploited for applications including photodetection, imaging and spectroscopy [6-12], photonic energy conversion, and photocatalysis [13][14][15][16][17][18]. However, these applications require carriers that retain a significant fraction of their energy absorbed from the plasmon, which is typically two orders of magnitude larger than the thermal energy scale. Experimentally, the energy distributions of hot carriers that critically impact their efficiency of collection cannot be measured directly, but must instead be inferred indirectly from optical response in pump-probe measurements, [19][20][21] from photo-current measurements, [22,23] or from redox-reaction chemical markers.[24] This critically necessitates theoretical prediction of charge transport in metal nanostructures far from equilibrium, which presents a major challenge for current computational methods [25][26][27][28].In extremely small nano-scale systems, electron dynamics require a full quantum mechanical treatment, and several classes of techniques have been developed for quantum transport simulations. In diagrammatic many-body perturbation theory, quantum transport can be described using the non-equilibrium Greens function (NEGF) formalism [29], which has been applied extensively to electron transport in molecular junctions [30]. atoms in rarefied gases [31], nanoscale metal interconnects [32], and small plasmonic nanoparticles [33]. Open quantum system approaches applied to photons have simi- * prineha@seas.harvard.edu † sundar@rpi.edu larly enabled efficient prediction of retardation and radiative effects on plasmon resonance...

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Section: Resultsmentioning

confidence: 88%

Transport of hot carriers in plasmonic nanostructures

Jermyn

Tagliabue

Atwater

et al. 2019

Phys. Rev. Materials

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“…[23] With an ab initio framework for calculating optical response and electronphonon interactions, we previously evaluated mechanisms of hot carrier generation and relaxation in plasmonic metals, [24,25] and identified their signatures in ultrafast pump-probe measurements. [26,27] In particular, the small mean free paths of higher energy carriers helped elucidate the efficiency limits in plasmonic energy conversion devices and potential strategies to overcome them. [13] Here, we investigate the dynamics of hot carriers in graphene and in graphene-derived vdW heterostructures to explore their potential for efficient hot carrier extraction.…”

mentioning

confidence: 99%

Effects of Interlayer Coupling on Hot‐Carrier Dynamics in Graphene‐Derived van der Waals Heterostructures

Narang

Zhao

Claybrook

et al. 2017

Advanced Optical Materials

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CommuniCation(1 of 5) 1600914 2D materials exhibit a diverse array of optical and electronic properties, ranging from insulating hexagonal boron nitride and semiconducting transition metal dichalcogenides to semimetallic graphene. [1][2][3][4][5] Stacked 2D materials, or van der Waals (vdW) heterostructures, [6][7][8] have generated considerable recent interest as designer plasmonic, photonic, and optoelectronic materials. Combining 2D layers in different arrangements makes it possible to realize a variety of new optical phenomena and nanophotonic devices, covering spectral ranges from the microwave to the ultraviolet. [9][10][11] Simultaneously, the field of utilizing the energetic 'hot' carriers generated by surface plasmon decay for photodetection Graphene exhibits promise as a plasmonic material with high mode confinement that could enable efficient hot carrier extraction. The lifetimes and mean free paths of energetic carriers have been investigated in free-standing graphene, graphite, and a heterostructure consisting of alternating graphene and hexagonal boron nitride layers using ab initio calculations of electron-electron and electron-phonon scattering in these materials. It is found that the extremely high lifetimes (3 ps) of low-energy carriers near the Dirac point in graphene, which are a 100 times larger than that in noble metals, are reduced by an order of magnitude due to interlayer coupling in graphite, but enhanced in the heterostructure due to phonon mode clamping. However, these lifetimes drop precipitously with increasing carrier energy and are smaller than those in noble metals at energies exceeding 0.5 eV. By analyzing the contribution of different scattering mechanisms and interlayer interactions, desirable spacer layer characteristics-high dielectric constant and heavy atoms-that could pave the way for plasmonic heterostructures with improved hot carrier transport have been identified. and solar energy conversion has grown rapidly. [12][13][14] Hot carrier extraction has also been demonstrated in graphene, [15,16] with experimental techniques such as pump-probe spectroscopy [17] and 4D electron microscopy [18,19] used to explore the energy relaxation dynamics. [20,21] However, these techniques conventionally provide indirect signatures of the response of a large number of thermalizing carriers, [22] and extensive theoretical modeling is necessary to extract information about the sub-picosecond nonequilibrium carrier dynamics of interest. [23] With an ab initio framework for calculating optical response and electronphonon interactions, we previously evaluated mechanisms of hot carrier generation and relaxation in plasmonic metals, [24,25] and identified their signatures in ultrafast pump-probe measurements. [26,27] In particular, the small mean free paths of higher energy carriers helped elucidate the efficiency limits in plasmonic energy conversion devices and potential strategies to overcome them. [13] Here, we investigate the dynamics of hot carriers in graphene and in graphene-derived v...

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“…[35]). This takes into account the detailed electronic structure effects such as the response of electrons far from the Dirac point, as well as scattering against both acoustic and optical phonons, including umklapp and intervalley processes [35][36][37][38]. Doping, that is, a change in the position of the Fermi level E F changes the value of τ , and hence calculations were carried out for several different values of E F ranging from the neutral (undoped) value to 1.5 eV above it (see the Supplemental Material [34] for details of formulation and [35] for values of τ ).…”

Section: Methodsmentioning

confidence: 99%

Quantum plasmons with optical-range frequencies in doped few-layer graphene

et al. 2018

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Although plasmon modes exist in doped graphene, the limited range of doping achieved by gating restricts the plasmon frequencies to a range that does not include the visible and infrared. Here we show, through the use of first-principles calculations, that the high levels of doping achieved by lithium intercalation in bilayer and trilayer graphene shift the plasmon frequencies into the visible range. To obtain physically meaningful results, we introduce a correction of the effect of plasmon interaction across the vacuum separating periodic images of the doped graphene layers, consisting of transparent boundary conditions in the direction perpendicular to the layers; this represents a significant improvement over the exact Coulomb cutoff technique employed in earlier works. The resulting plasmon modes are due to local field effects and the nonlocal response of the material to external electromagnetic fields, requiring a fully quantum mechanical treatment. We describe the features of these quantum plasmons, including the dispersion relation, losses, and field localization. Our findings point to a strategy for fine-tuning the plasmon frequencies in graphene and other two-dimensional materials.

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Experimental and Ab Initio Ultrafast Carrier Dynamics in Plasmonic Nanoparticles

Cited by 132 publications

References 48 publications

Transport of hot carriers in plasmonic nanostructures

Transport of hot carriers in plasmonic nanostructures

Effects of Interlayer Coupling on Hot‐Carrier Dynamics in Graphene‐Derived van der Waals Heterostructures

Quantum plasmons with optical-range frequencies in doped few-layer graphene

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