Exciton‐Dominated Ultrafast Optical Response in Atomically Thin PtSe<sub>2</sub>

Bae, Seongkwang; Nah, Sanghee; Lee, Doeon; Sajjad, Muhammad; Singh, Nirpendra; Kang, Ku; Kim, Sang-Hoon; Kim, Jaekyun; Baik, Hionsuck; Sim, Sangwan

doi:10.1002/smll.202103400

Cited by 20 publications

(25 citation statements)

References 61 publications

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“…The overall sign of the differential reflection signal is negative, agreeing with a previous study . Considering that most of the differential transmission measurements on few-layer PtSe 2 have observed photoinduced bleaching (PB) over broadband ranges near the 800 nm probe wavelength, − the observed negative sign of the differential reflection can be interpreted as PB. Note that PB has exhibited negative signs in differential reflection measurements of various 2D materials on transparent substrates, − such as sapphire used in this work.…”

Section: Resultssupporting

confidence: 90%

“…Note that, while the previous study observed an additional standing wave CP mode in chemical vapor-deposited PtSe 2 , 44 it was not identified in our experiment, probably due to the relatively weak PtSe 2 − substrate coupling of the mechanically exfoliated flake sample 54,55 (see the extended discussion in the Supporting Information, Figure S3). The decaying background in the −ΔR/R 0 trace corresponds to the dynamics of the pumpgenerated carriers at the 800 nm probe wavelength, as demonstrated in previous studies 45,47,48,56 (see the extended discussion and associated broadband transient responses in the Supporting Information, Figure S4). The full −ΔR/R 0 trace can be modeled by the following function,…”

Section: ■ Results and Discussionsupporting

confidence: 71%

“…The oscillating part is due to the layer-breathing CP mode that arises from the strong interlayer lattice coupling. 44,45,47,53 This assignment is confirmed by the fact that the thickness dependence of the CP frequency agrees well with the 1D chain model of the layer-breathing mode (Supporting Information, Figure S2). Note that, while the previous study observed an additional standing wave CP mode in chemical vapor-deposited PtSe 2 , 44 it was not identified in our experiment, probably due to the relatively weak PtSe 2 − substrate coupling of the mechanically exfoliated flake sample 54,55 (see the extended discussion in the Supporting Information, Figure S3).…”

Section: ■ Results and Discussionsupporting

confidence: 67%

“…57 The second term denotes the biexponential decay dynamics of the carriers (blue line in Figure 1c), where A 1 and A 2 are the amplitudes, and τ 1 = 1. in previous ultrafast studies on 2D PtSe 2 . These studies found that the fast component is due to the carrier trapping by defects, 47,48,58 and the slow component is caused by the defectassisted carrier−carrier scattering or carrier−phonon scattering. 49,56,58,59 The full curve from eq 1 well reproduces the −ΔR/R 0 trace (green line in Figure 1c).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

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Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

et al. 2022

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Ultrafast spatiotemporal responses to laser pulses are important for understanding fundamental processes in solids, such as diffusion of carriers and coherent vibrations of lattices. Here, we present anomalous spatiotemporal dynamics in atomically thin PtSe 2 , a new rising two-dimensional material in electronics and optoelectronics. We utilize transient absorption scanning microscopy to investigate the carrier diffusion dynamics. Interestingly, the observed spatial width of the optical response shows oscillations with picosecond periods, in contrast to ordinary systems in which the spatial distribution monotonically broadens with time. We find that this anomalous oscillating behavior arises from the dynamic superposition between the hot carrier diffusion and coherent layer-breathing lattice vibrations. Further, we obtain the thickness-dependent diffusivities of hot/cooled carriers and carrier cooling time constants, which are critical factors for designing 2D PtSe 2 -based ultrafast devices. This work provides novel observation and understanding of ultrafast spatiotemporal hot carrier dynamics and its interplay with coherent phonons.

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Section: Resultssupporting

confidence: 90%

Section: ■ Results and Discussionsupporting

confidence: 71%

Section: ■ Results and Discussionsupporting

confidence: 67%

Section: ■ Results and Discussionmentioning

confidence: 99%

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Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

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“…While the transport and catalytic properties of PtX 2 have been thoroughly investigated, its electronic excitation spectrum, including the collective excitations (excitons and plasmons), remains largely unexplored. Understanding these excitations − is the key to controlling the optical properties of the material and for future photonic or optoelectronic applications. ,− The optical excitations in the MoX 2 and WX 2 semiconducting TMDs have been intensely studied during the past years because of the unique exciton physics found in their mono- and few-layer structures. , In comparison, the optical properties of few-layer PtX 2 have only recently gained attention, and only the most basic properties of their excitons have so far been addressed. − The plasmon excitations of bulk and thin layers of PtTe 2 were reported by Ghosh et al However, in these measurements the samples were not atomically thin and substrate–sample interactions could not be ruled out. To date, the electronic excitation spectrum of freestanding few-layer PtX 2 remains unexplored, and it is unclear how it depends on the number of layers and the metal–semiconductor transition taking place as the thickness decreases to the monolayer limit.…”

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confidence: 99%

Momentum-Dependent Oscillator Strength Crossover of Excitons and Plasmons in Two-Dimensional PtSe₂

et al. 2022

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The 1T-phase layered PtX2 chalcogenide has attracted widespread interest due to its thickness dependent metal–semiconductor transition driven by strong interlayer coupling. While the ground state properties of this paradigmatic material system have been widely explored, its fundamental excitation spectrum remains poorly understood. Here we combine first-principles calculations with momentum (q) resolved electron energy loss spectroscopy (q-EELS) to study the collective excitations in 1T-PtSe2 from the monolayer limit to the bulk. At finite momentum transfer, all the spectra are dominated by two distinct interband plasmons that disperse to higher energy with increasing q. Interestingly, the absence of long-range screening in the two-dimensional (2D) limit inhibits the formation of long wavelength plasmons. Consequently, in the small-q limit, excitations in monolayer PtSe2 are exclusively of excitonic nature, and the loss spectrum coincides with the optical spectrum. The qualitatively different momentum dependence of excitons and plasmons enables us to unambiguously disentangle their spectral fingerprints in the excited state spectrum of layered 1T-PtSe2. This will help to discern the charge carrier plasmon and locally map the optical conductivity and trace the layer-dependent semiconductor to metal transition in 1T-PtSe2 and other 2D materials.

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Completely Anisotropic Ultrafast Optical Switching and Direction‐Dependent Photocarrier Diffusion in Layered ZrTe₅

Seo

Nah

Sajjad

et al. 2022

Advanced Optical Materials

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In particular, their optical anisotropy has enabled novel light-polarization-driven applications, such as highly polarizationsensitive light detectors and emitters [3,[10][11][12][13][14][15][16][17] and optical information encryption. [18] Recently, the ultrafast control of the anisotropic optical properties of 2D materials has become a topic of interest, since it not only enables high-speed, polarizationcontrolled optical switches but also offers novel physical insights into anisotropic light-matter interactions and quantum coherences. [19][20][21][22][23][24][25][26][27][28][29] Moreover, their ultrafast spatiotemporal dynamics exhibit unique quasi-1D behavior of photocarriers with direction-dependent mobilities and diffusivities, offering essential information for improving the anisotropic devices. [30,31] However, despite the continuous emergence of novel anisotropic 2D materials, [6][7][8][9] ultrafast optical anisotropy has so far been explored for only a very limited class of materials.ZrTe 5 is a transition metal pentatelluride that has been extensively studied since the 1980s owing to its unique physical properties, such as resistivity anomaly (Figure S1, Supporting information), [32,33] large thermoelectric power, [34,35] and pressure-induced superconductivity. [36] In particular, ZrTe 5 exhibits different topological phases (weak and strong topological insulators and Dirac semimetal) in diverse experiments, its topological nature has been a topic of active debate in the last decade. [37][38][39][40][41][42][43] Further, recent studies demonstrated that transitions between these topological Layered nanomaterials with in-plane anisotropy exhibit unique orientationdependent responses to external stimuli, enabling the development of novel devices with additional degrees of freedom. In particular, their anisotropic optical properties enable ultrafast nanophotonic modulators to be controlled by light polarization. However, achieving high controllability is still challenging due to incomplete optical anisotropy in most materials. Here, this work presents a completely anisotropic, ultrafast optical modulation in zirconium pentatelluride (ZrTe 5 ), a layered nanomaterial that has recently attracted renewed attention. The transient absorption (TA) microscopy reveals anisotropic ultrafast picosecond optical modulation in a broad range of 1.2-2.2 eV. In particular, at a certain photon-energy of 1.62 eV, complete on/off switching with a near-unity degree of anisotropy is achieved solely by changing the light polarization, suggesting that ZrTe 5 is a promising material for polarization-selective high-speed optical modulators. The theoretical analysis of the transition dipole moments attributes this sharp anisotropy to strongly polarization-dependent excited-state absorption. Furthermore, this work directly observes direction-dependent photocarrier transport using scanning TA microscopy. It yields the anisotropic diffusivity, mobility, and diffusion lengths of the photocarriers, which are essential parameters for de...

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Exciton‐Dominated Ultrafast Optical Response in Atomically Thin PtSe₂

Cited by 20 publications

References 61 publications

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

Momentum-Dependent Oscillator Strength Crossover of Excitons and Plasmons in Two-Dimensional PtSe₂

Completely Anisotropic Ultrafast Optical Switching and Direction‐Dependent Photocarrier Diffusion in Layered ZrTe₅

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Exciton‐Dominated Ultrafast Optical Response in Atomically Thin PtSe2

Cited by 20 publications

References 61 publications

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe2

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe2

Momentum-Dependent Oscillator Strength Crossover of Excitons and Plasmons in Two-Dimensional PtSe2

Completely Anisotropic Ultrafast Optical Switching and Direction‐Dependent Photocarrier Diffusion in Layered ZrTe5

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Resources

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Exciton‐Dominated Ultrafast Optical Response in Atomically Thin PtSe₂

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

Anomalous Oscillating Behavior of Ultrafast Spatiotemporal Hot Carrier Diffusion in Two-Dimensional PtSe₂

Momentum-Dependent Oscillator Strength Crossover of Excitons and Plasmons in Two-Dimensional PtSe₂

Completely Anisotropic Ultrafast Optical Switching and Direction‐Dependent Photocarrier Diffusion in Layered ZrTe₅