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Your search keyword '"Kapteyn, Henry C."' showing total 311 results
Start Over Author "Kapteyn, Henry C." Publication Type Academic Journals
311 results on '"Kapteyn, Henry C."'

1. Direct Observation of Enhanced Electron-Phonon Coupling in Copper Nanoparticles in the Warm-Dense Matter Regime

Author

Nguyen, Quynh LD, Simoni, Jacopo, Dorney, Kevin M, Shi, Xun, Ellis, Jennifer L, Brooks, Nathan J, Hickstein, Daniel D, Grennell, Amanda G, Yazdi, Sadegh, Campbell, Eleanor EB, Tan, Liang Z, Prendergast, David, Daligault, Jerome, Kapteyn, Henry C, and Murnane, Margaret M

Subjects
Physical Sciences, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences
Abstract

Warm dense matter (WDM) represents a highly excited state that lies at the intersection of solids, plasmas, and liquids and that cannot be described by equilibrium theories. The transient nature of this state when created in a laboratory, as well as the difficulties in probing the strongly coupled interactions between the electrons and the ions, make it challenging to develop a complete understanding of matter in this regime. In this work, by exciting isolated ∼8  nm copper nanoparticles with a femtosecond laser below the ablation threshold, we create uniformly excited WDM. Using photoelectron spectroscopy, we measure the instantaneous electron temperature and extract the electron-ion coupling of the nanoparticle as it undergoes a solid-to-WDM phase transition. By comparing with state-of-the-art theories, we confirm that the superheated nanoparticles lie at the boundary between hot solids and plasmas, with associated strong electron-ion coupling. This is evidenced both by a fast energy loss of electrons to ions, and a strong modulation of the electron temperature induced by strong acoustic breathing modes that change the nanoparticle volume. This work demonstrates a new route for experimental exploration of the exotic properties of WDM.

Published
2023

2. Three-dimensional topological magnetic monopoles and their interactions in a ferromagnetic meta-lattice

Author

Rana, Arjun, Liao, Chen-Ting, Iacocca, Ezio, Zou, Ji, Pham, Minh, Lu, Xingyuan, Subramanian, Emma-Elizabeth Cating, Lo, Yuan Hung, Ryan, Sinéad A., Bevis, Charles S., Karl, Jr, Robert M., Glaid, Andrew J., Rable, Jeffrey, Mahale, Pratibha, Hirst, Joel, Ostler, Thomas, Liu, William, O’Leary, Colum M., Yu, Young-Sang, Bustillo, Karen, Ohldag, Hendrik, Shapiro, David A., Yazdi, Sadegh, Mallouk, Thomas E., Osher, Stanley J., Kapteyn, Henry C., Crespi, Vincent H., Badding, John V., Tserkovnyak, Yaroslav, Murnane, Margaret M., and Miao, Jianwei

Published
2023
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3. A General and Predictive Understanding of Thermal Transport from 1D- and 2D-Confined Nanostructures: Theory and Experiment

Author

Beardo, Albert, Knobloch, Joshua L, Sendra, Lluc, Bafaluy, Javier, Frazer, Travis D, Chao, Weilun, Hernandez-Charpak, Jorge N, Kapteyn, Henry C, Abad, Begoña, Murnane, Margaret M, Alvarez, F Xavier, and Camacho, Juan

Subjects
Physical Sciences, Classical Physics, high-order harmonic generation, non-Fourier heat transport, phonon hydrodynamics, pump−probe spectroscopy, silicon, Nanoscience & Nanotechnology
Abstract

Heat management is crucial in the design of nanoscale devices as the operating temperature determines their efficiency and lifetime. Past experimental and theoretical works exploring nanoscale heat transport in semiconductors addressed known deviations from Fourier's law modeling by including effective parameters, such as a size-dependent thermal conductivity. However, recent experiments have qualitatively shown behavior that cannot be modeled in this way. Here, we combine advanced experiment and theory to show that the cooling of 1D- and 2D-confined nanoscale hot spots on silicon can be described using a general hydrodynamic heat transport model, contrary to previous understanding of heat flow in bulk silicon. We use a comprehensive set of extreme ultraviolet scatterometry measurements of nondiffusive transport from transiently heated nanolines and nanodots to validate and generalize our ab initio model, that does not need any geometry-dependent fitting parameters. This allows us to uncover the existence of two distinct time scales and heat transport mechanisms: an interface resistance regime that dominates on short time scales and a hydrodynamic-like phonon transport regime that dominates on longer time scales. Moreover, our model can predict the full thermomechanical response on nanometer length scales and picosecond time scales for arbitrary geometries, providing an advanced practical tool for thermal management of nanoscale technologies. Furthermore, we derive analytical expressions for the transport time scales, valid for a subset of geometries, supplying a route for optimizing heat dissipation.

Published
2021

4. X-ray linear dichroic ptychography

Author

Lo, Yuan Hung, Zhou, Jihan, Rana, Arjun, Morrill, Drew, Gentry, Christian, Enders, Bjoern, Yu, Young-Sang, Sun, Chang-Yu, Shapiro, David A, Falcone, Roger W, Kapteyn, Henry C, Murnane, Margaret M, Gilbert, Pupa UPA, and Miao, Jianwei

Subjects
Nanotechnology, Bioengineering, Animals, Anisotropy, Anthozoa, Biomimetics, Biomineralization, Calcium Carbonate, Crystallins, Microscopy, Electron, Scanning Transmission, Minerals, Radiography, Tissue Engineering, X-Rays, coherent diffractive imaging, ptychography, X-ray linear dichroism, biominerals, 4D scanning transmission electron microscopy
Abstract

Biominerals such as seashells, coral skeletons, bone, and tooth enamel are optically anisotropic crystalline materials with unique nanoscale and microscale organization that translates into exceptional macroscopic mechanical properties, providing inspiration for engineering new and superior biomimetic structures. Using Seriatopora aculeata coral skeleton as a model, here, we experimentally demonstrate X-ray linear dichroic ptychography and map the c-axis orientations of the aragonite (CaCO3) crystals. Linear dichroic phase imaging at the oxygen K-edge energy shows strong polarization-dependent contrast and reveals the presence of both narrow (35°) c-axis angular spread in the coral samples. These X-ray ptychography results are corroborated by four-dimensional (4D) scanning transmission electron microscopy (STEM) on the same samples. Evidence of co-oriented, but disconnected, corallite subdomains indicates jagged crystal boundaries consistent with formation by amorphous nanoparticle attachment. We expect that the combination of X-ray linear dichroic ptychography and 4D STEM could be an important multimodal tool to study nano-crystallites, interfaces, nucleation, and mineral growth of optically anisotropic materials at multiple length scales.

Published
2021

5. Full characterization of ultrathin 5-nm low-k dielectric bilayers: Influence of dopants and surfaces on the mechanical properties

Author

Frazer, Travis D, Knobloch, Joshua L, Hernández-Charpak, Jorge N, Hoogeboom-Pot, Kathleen M, Nardi, Damiano, Yazdi, Sadegh, Chao, Weilun, Anderson, Erik H, Tripp, Marie K, King, Sean W, Kapteyn, Henry C, Murnane, Margaret M, and Abad, Begoña

Abstract

Ultrathin films and multilayers, with controlled thickness down to single atomic layers, are critical for advanced technologies ranging from nanoelectronics to spintronics to quantum devices. However, for thicknesses less than 10 nm, surfaces and dopants contribute significantly to the film properties, which can differ dramatically from that of bulk materials. For amorphous films being developed as low dielectric constant interfaces for nanoelectronics, the presence of surfaces or dopants can soften films and degrade their mechanical performance. Here we use coherent short-wavelength light to fully and nondestructively characterize the mechanical properties of individual films as thin as 5 nm within a bilayer. In general, we find that the mechanical properties depend both on the amount of doping and the presence of surfaces. In very thin (5-nm) silicon carbide bilayers with low hydrogen doping, surface effects induce a substantial softening - by almost an order of magnitude - compared with the same doping in thicker (46-nm) bilayers. These findings are important for informed design of ultrathin films for a host of nano- and quantum technologies, and for improving the switching speed and efficiency of next-generation electronics.

Published
2020

7. Engineering Nanoscale Thermal Transport: Size- and Spacing-Dependent Cooling of Nanostructures

Author

Frazer, Travis D, Knobloch, Joshua L, Hoogeboom-Pot, Kathleen M, Nardi, Damiano, Chao, Weilun, Falcone, Roger W, Murnane, Margaret M, Kapteyn, Henry C, and Hernandez-Charpak, Jorge N

Subjects
Physical Sciences, Engineering, Nanotechnology, Physical sciences
Abstract

Nanoscale thermal transport is becoming ever more technologically important with the development of next-generation nanoelectronics, nanomediated thermal therapies, and high efficiency thermoelectric devices. However, direct experimental measurements of nondiffusive heat flow in nanoscale systems are challenging, and first-principle models of real geometries are not yet computationally feasible. In recent work, we used ultrafast pulses of short-wavelength light to uncover a previously-unobserved regime of nanoscale thermal transport that occurs when the width and separation of heat sources are comparable to the mean free paths of the dominant heat-carrying phonons in the substrate. We now systematically compare thermal transport from gratings of metallic nanolines with different periodicities, on both silicon and fused-silica substrates, to map the entire nanoscale thermal transport landscape - from closely spaced through increasingly isolated to fully isolated heat-transfer regimes. By monitoring the surface profile dynamics with subangstrom sensitivity, we directly measure thermal transport from the nanolines into the substrate. This allows us to quantify for the first time how the nanoline separation significantly impacts thermal transport into the substrate, making it possible to reach efficiencies that are within a factor of 2 of the diffusive (i.e., thin-film) limit. We also show that partially isolated nanolines perform significantly worse, because cooling occurs in a regime that is intermediate between close-packed and fully isolated heat sources. This work thus confirms the surprising prediction that closely spaced nanoscale heat sources can cool more quickly than when far apart. These results show that our predictive model is validated by experiment over a broad parameter space, which is important for benchmarking theories that go beyond the Fourier model of heat diffusion, and for informed design of nanoengineered systems.

Published
2019

9. Ionization-assisted spatiotemporal localization in gas-filled capillaries.

Author

Gao, Xiaohui, Patwardhan, Gauri, Shim, Bonggu, Popmintchev, Tenio, Kapteyn, Henry C, Murnane, Margaret M, and Gaeta, Alexander L

Subjects
Optical Physics, Quantum Physics, Electrical and Electronic Engineering, Optics
Abstract

We demonstrate numerically and experimentally that intense pulses propagating in gas-filled capillaries can undergo localization in space and time due to strong plasma defocusing. This phenomenon can occur below or above the self-focusing threshold Pcr as a result of ionization-induced refraction that excites higher-order modes. The constructive interference of higher-order modes leads to spatiotemporal localization and resurgence of the intensity. Simulations show that this confinement is more prominent at shorter wavelength pulses and for smaller capillary diameters. Experiments with ultraviolet pulses show evidence that this ionization-induced refocusing appears below Pcr and thus represents a mechanism for spatiotemporal confinement without self-focusing.

Published
2018

10. Single-shot 3D coherent diffractive imaging of core-shell nanoparticles with elemental specificity.

Author

Pryor, Alan, Rana, Arjun, Xu, Rui, Rodriguez, Jose A, Yang, Yongsoo, Gallagher-Jones, Marcus, Jiang, Huaidong, Kanhaiya, Krishan, Nathanson, Michael, Park, Jaehyun, Kim, Sunam, Kim, Sangsoo, Nam, Daewoong, Yue, Yu, Fan, Jiadong, Sun, Zhibin, Zhang, Bosheng, Gardner, Dennis F, Dias, Carlos Sato Baraldi, Joti, Yasumasa, Hatsui, Takaki, Kameshima, Takashi, Inubushi, Yuichi, Tono, Kensuke, Lee, Jim Yang, Yabashi, Makina, Song, Changyong, Ishikawa, Tetsuya, Kapteyn, Henry C, Murnane, Margaret M, Heinz, Hendrik, and Miao, Jianwei

Abstract

We report 3D coherent diffractive imaging (CDI) of Au/Pd core-shell nanoparticles with 6.1 nm spatial resolution with elemental specificity. We measured single-shot diffraction patterns of the nanoparticles using intense x-ray free electron laser pulses. By exploiting the curvature of the Ewald sphere and the symmetry of the nanoparticle, we reconstructed the 3D electron density of 34 core-shell structures from these diffraction patterns. To extract 3D structural information beyond the diffraction signal, we implemented a super-resolution technique by taking advantage of CDI's quantitative reconstruction capabilities. We used high-resolution model fitting to determine the Au core size and the Pd shell thickness to be 65.0 ± 1.0 nm and 4.0 ± 0.5 nm, respectively. We also identified the 3D elemental distribution inside the nanoparticles with an accuracy of 3%. To further examine the model fitting procedure, we simulated noisy diffraction patterns from a Au/Pd core-shell model and a solid Au model and confirmed the validity of the method. We anticipate this super-resolution CDI method can be generally used for quantitative 3D imaging of symmetrical nanostructures with elemental specificity.

Published
2018

11. Near- and Extended-Edge X-Ray-Absorption Fine-Structure Spectroscopy Using Ultrafast Coherent High-Order Harmonic Supercontinua

Author

Popmintchev, Dimitar, Galloway, Benjamin R, Chen, Ming-Chang, Dollar, Franklin, Mancuso, Christopher A, Hankla, Amelia, Miaja-Avila, Luis, O'Neil, Galen, Shaw, Justin M, Fan, Guangyu, Ališauskas, Skirmantas, Andriukaitis, Giedrius, Balčiunas, Tadas, Mücke, Oliver D, Pugzlys, Audrius, Baltuška, Andrius, Kapteyn, Henry C, Popmintchev, Tenio, and Murnane, Margaret M

Subjects
Mathematical Sciences, Physical Sciences, Engineering, General Physics
Abstract

Recent advances in high-order harmonic generation have made it possible to use a tabletop-scale setup to produce spatially and temporally coherent beams of light with bandwidth spanning 12 octaves, from the ultraviolet up to x-ray photon energies >1.6  keV. Here we demonstrate the use of this light for x-ray-absorption spectroscopy at the K- and L-absorption edges of solids at photon energies near 1 keV. We also report x-ray-absorption spectroscopy in the water window spectral region (284-543 eV) using a high flux high-order harmonic generation x-ray supercontinuum with 10^{9}  photons/s in 1% bandwidth, 3 orders of magnitude larger than has previously been possible using tabletop sources. Since this x-ray radiation emerges as a single attosecond-to-femtosecond pulse with peak brightness exceeding 10^{26}  photons/s/mrad^{2}/mm^{2}/1% bandwidth, these novel coherent x-ray sources are ideal for probing the fastest molecular and materials processes on femtosecond-to-attosecond time scales and picometer length scales.

Published
2018

12. Phase matching of noncollinear sum and difference frequency high harmonic generation above and below the critical ionization level.

Author

Ellis, Jennifer L, Dorney, Kevin M, Durfee, Charles G, Hernández-García, Carlos, Dollar, Franklin, Mancuso, Christopher A, Fan, Tingting, Zusin, Dmitriy, Gentry, Christian, Grychtol, Patrik, Kapteyn, Henry C, Murnane, Margaret M, and Hickstein, Daniel D

Subjects
Atomic, Molecular and Optical Physics, Physical Sciences, Optical Physics, Electrical and Electronic Engineering, Communications Technologies, Optics, Communications engineering, Electronics, sensors and digital hardware, Atomic, molecular and optical physics
Abstract

We investigate the macroscopic physics of noncollinear high harmonic generation (HHG) at high pressures. We make the first experimental demonstration of phase matching of noncollinear high-order-difference-frequency generation at ionization fractions above the critical ionization level, which normally sets an upper limit on the achievable cutoff photon energies. Additionally, we show that noncollinear high-order-sum-frequency generation requires much higher pressures for phase matching than single-beam HHG does, which mitigates the short interaction region in this geometry. We also dramatically increase the experimentally realized cutoff energy of noncollinear circularly polarized HHG, reaching photon energies of 90 eV. Finally, we achieve complete angular separation of high harmonic orders without the use of a spectrometer.

Published
2017

13. Picosecond ionization dynamics in femtosecond filaments at high pressures

Author

Gao, Xiaohui, Patwardhan, Gauri, Schrauth, Samuel, Zhu, Daiwei, Popmintchev, Tenio, Kapteyn, Henry C, Murnane, Margaret M, Romanov, Dmitri A, Levis, Robert J, and Gaeta, Alexander L

Subjects
Physical Sciences, Chemical Sciences, Atomic, Molecular and Optical Physics, Physical Chemistry, Chemical sciences, Mathematical sciences, Physical sciences
Abstract

We investigate the plasma dynamics inside a femtosecond-pulse-induced filament generated in an argon gas for a wide range of pressures up to 60 bar. At higher pressures, we observe ionization immediately following a pulse, with up to a threefold increase in the electron density within 30 ps after the filamentary propagation of a femtosecond pulse. Our study suggests that this picosecond evolution can be attributed to collisional ionization including Penning and associative ionizations and electron-impact ionization of excited atoms generated during the pulse. The dominance of excited atoms over ionized atoms at the end of the pulse also indicates an intrapulse inhibition of avalanche ionization. This delayed ionization dynamics provides evidence for diagnosing atomic and molecular excitation and ionization in intense laser interaction with high-pressure gases.

Published
2017

15. Lorentz drift compensation in high harmonic generation in the soft and hard X-ray regions of the spectrum.

Author

Galloway, Benjamin R, Popmintchev, Dimitar, Pisanty, Emilio, Hickstein, Daniel D, Murnane, Margaret M, Kapteyn, Henry C, and Popmintchev, Tenio

Subjects
Astronomical Sciences, Physical Sciences, Optical Physics, Electrical and Electronic Engineering, Communications Technologies, Optics, Communications engineering, Electronics, sensors and digital hardware, Atomic, molecular and optical physics
Abstract

We present a semi-classical study of the effects of the Lorentz force on electrons during high harmonic generation in the soft and hard X-ray regions driven by near- and mid-infrared lasers with wavelengths from 0.8 to 20 μm, and at intensities below 1015 W/cm2. The transverse extent of the longitudinal Lorentz drift is compared for both Gaussian focus and waveguide geometries. Both geometries exhibit a longitudinal electric field component that cancels the magnetic Lorentz drift in some regions of the focus, once each full optical cycle. We show that the Lorentz force contributes a super-Gaussian scaling which acts in addition to the dominant high harmonic flux scaling of λ-(5-6) due to quantum diffusion. We predict that the high harmonic yield will be reduced for driving wavelengths > 6 μm, and that the presence of dynamic spatial mode asymmetries results in the generation of both even and odd harmonic orders. Remarkably, we show that under realistic conditions, the recollision process can be controlled and does not shut off completely even for wavelengths >10 μm and recollision energies greater than 15 keV.

Published
2016

16. Ultraviolet surprise: Efficient soft x-ray high-harmonic generation in multiply ionized plasmas

Author

Popmintchev, Dimitar, Hernández-García, Carlos, Dollar, Franklin, Mancuso, Christopher, Pérez-Hernández, Jose A, Chen, Ming-Chang, Hankla, Amelia, Gao, Xiaohui, Shim, Bonggu, Gaeta, Alexander L, Tarazkar, Maryam, Romanov, Dmitri A, Levis, Robert J, Gaffney, Jim A, Foord, Mark, Libby, Stephen B, Jaron-Becker, Agnieszka, Becker, Andreas, Plaja, Luis, Murnane, Margaret M, Kapteyn, Henry C, and Popmintchev, Tenio

Subjects
Quantum Physics, Atomic, Molecular and Optical Physics, Physical Sciences, General Science & Technology
Abstract

High-harmonic generation is a universal response of matter to strong femtosecond laser fields, coherently upconverting light to much shorter wavelengths. Optimizing the conversion of laser light into soft x-rays typically demands a trade-off between two competing factors. Because of reduced quantum diffusion of the radiating electron wave function, the emission from each species is highest when a short-wavelength ultraviolet driving laser is used. However, phase matching--the constructive addition of x-ray waves from a large number of atoms--favors longer-wavelength mid-infrared lasers. We identified a regime of high-harmonic generation driven by 40-cycle ultraviolet lasers in waveguides that can generate bright beams in the soft x-ray region of the spectrum, up to photon energies of 280 electron volts. Surprisingly, the high ultraviolet refractive indices of both neutral atoms and ions enabled effective phase matching, even in a multiply ionized plasma. We observed harmonics with very narrow linewidths, while calculations show that the x-rays emerge as nearly time-bandwidth-limited pulse trains of ~100 attoseconds.

Published
2015

17. Bright circularly polarized soft X-ray high harmonics for X-ray magnetic circular dichroism

Author

Fan, Tingting, Grychtol, Patrik, Knut, Ronny, Hernández-García, Carlos, Hickstein, Daniel D, Zusin, Dmitriy, Gentry, Christian, Dollar, Franklin J, Mancuso, Christopher A, Hogle, Craig W, Kfir, Ofer, Legut, Dominik, Carva, Karel, Ellis, Jennifer L, Dorney, Kevin M, Chen, Cong, Shpyrko, Oleg G, Fullerton, Eric E, Cohen, Oren, Oppeneer, Peter M, Milošević, Dejan B, Becker, Andreas, Jaroń-Becker, Agnieszka A, Popmintchev, Tenio, Murnane, Margaret M, and Kapteyn, Henry C

Subjects
Atomic, Molecular and Optical Physics, Physical Sciences, X-rays, high harmonics generation, magnetic material, ultrafast light science, phase matching
Abstract

We demonstrate, to our knowledge, the first bright circularly polarized high-harmonic beams in the soft X-ray region of the electromagnetic spectrum, and use them to implement X-ray magnetic circular dichroism measurements in a tabletop-scale setup. Using counterrotating circularly polarized laser fields at 1.3 and 0.79 µm, we generate circularly polarized harmonics with photon energies exceeding 160 eV. The harmonic spectra emerge as a sequence of closely spaced pairs of left and right circularly polarized peaks, with energies determined by conservation of energy and spin angular momentum. We explain the single-atom and macroscopic physics by identifying the dominant electron quantum trajectories and optimal phase-matching conditions. The first advanced phase-matched propagation simulations for circularly polarized harmonics reveal the influence of the finite phase-matching temporal window on the spectrum, as well as the unique polarization-shaped attosecond pulse train. Finally, we use, to our knowledge, the first tabletop X-ray magnetic circular dichroism measurements at the N4,5 absorption edges of Gd to validate the high degree of circularity, brightness, and stability of this light source. These results demonstrate the feasibility of manipulating the polarization, spectrum, and temporal shape of high harmonics in the soft X-ray region by manipulating the driving laser waveform.

Published
2015

18. A new regime of nanoscale thermal transport: Collective diffusion increases dissipation efficiency

Author

Hoogeboom-Pot, Kathleen M, Hernandez-Charpak, Jorge N, Gu, Xiaokun, Frazer, Travis D, Anderson, Erik H, Chao, Weilun, Falcone, Roger W, Yang, Ronggui, Murnane, Margaret M, Kapteyn, Henry C, and Nardi, Damiano

Subjects
Affordable and Clean Energy, nanoscale thermal transport, nondiffusive transport, mean free path spectroscopy, high harmonic generation, ultrafast X-rays
Abstract

Understanding thermal transport from nanoscale heat sources is important for a fundamental description of energy flow in materials, as well as for many technological applications including thermal management in nanoelectronics and optoelectronics, thermoelectric devices, nanoenhanced photovoltaics, and nanoparticle-mediated thermal therapies. Thermal transport at the nanoscale is fundamentally different from that at the macroscale and is determined by the distribution of carrier mean free paths and energy dispersion in a material, the length scales of the heat sources, and the distance over which heat is transported. Past work has shown that Fourier's law for heat conduction dramatically overpredicts the rate of heat dissipation from heat sources with dimensions smaller than the mean free path of the dominant heat-carrying phonons. In this work, we uncover a new regime of nanoscale thermal transport that dominates when the separation between nanoscale heat sources is small compared with the dominant phonon mean free paths. Surprisingly, the interaction of phonons originating from neighboring heat sources enables more efficient diffusive-like heat dissipation, even from nanoscale heat sources much smaller than the dominant phonon mean free paths. This finding suggests that thermal management in nanoscale systems including integrated circuits might not be as challenging as previously projected. Finally, we demonstrate a unique capability to extract differential conductivity as a function of phonon mean free path in materials, allowing the first (to our knowledge) experimental validation of predictions from the recently developed first-principles calculations.

Published
2015

19. Solvents Effects on Charge Transfer from Quantum Dots

Author

Ellis, Jennifer L, Hickstein, Daniel D, Schnitzenbaumer, Kyle J, Wilker, Molly B, Palm, Brett B, Jimenez, Jose L, Dukovic, Gordana, Kapteyn, Henry C, Murnane, Margaret M, and Xiong, Wei

Subjects
Chemical Sciences, General Chemistry
Abstract

To predict and understand the performance of nanodevices in different environments, the influence of the solvent must be explicitly understood. In this Communication, this important but largely unexplored question is addressed through a comparison of quantum dot charge transfer processes occurring in both liquid phase and in vacuum. By comparing solution phase transient absorption spectroscopy and gas-phase photoelectron spectroscopy, we show that hexane, a common nonpolar solvent for quantum dots, has negligible influence on charge transfer dynamics. Our experimental results, supported by insights from theory, indicate that the reorganization energy of nonpolar solvents plays a minimal role in the energy landscape of charge transfer in quantum dot devices. Thus, this study demonstrates that measurements conducted in nonpolar solvents can indeed provide insight into nanodevice performance in a wide variety of environments.

Published
2015

20. Generation of bright isolated attosecond soft X-ray pulses driven by multicycle midinfrared lasers

Author

Chen, Ming-Chang, Mancuso, Christopher, Hernández-García, Carlos, Dollar, Franklin, Galloway, Ben, Popmintchev, Dimitar, Huang, Pei-Chi, Walker, Barry, Plaja, Luis, Jaroń-Becker, Agnieszka A, Becker, Andreas, Murnane, Margaret M, Kapteyn, Henry C, and Popmintchev, Tenio

Subjects
Algorithms, Chemistry, Physical, Lasers, Models, Theoretical, Photons, Spectroscopy, Fourier Transform Infrared, Time Factors, X-Rays, ultrafast, coherent, nonlinear optics, physics.optics, physics.atom-ph
Abstract

High harmonic generation driven by femtosecond lasers makes it possible to capture the fastest dynamics in molecules and materials. However, to date the shortest subfemtosecond (attosecond, 10(-18) s) pulses have been produced only in the extreme UV region of the spectrum below 100 eV, which limits the range of materials and molecular systems that can be explored. Here we experimentally demonstrate a remarkable convergence of physics: when midinfrared lasers are used to drive high harmonic generation, the conditions for optimal bright, soft X-ray generation naturally coincide with the generation of isolated attosecond pulses. The temporal window over which phase matching occurs shrinks rapidly with increasing driving laser wavelength, to the extent that bright isolated attosecond pulses are the norm for 2-µm driving lasers. Harnessing this realization, we experimentally demonstrate the generation of isolated soft X-ray attosecond pulses at photon energies up to 180 eV for the first time, to our knowledge, with a transform limit of 35 attoseconds (as), and a predicted linear chirp of 300 as. Most surprisingly, advanced theory shows that in contrast with as pulse generation in the extreme UV, long-duration, 10-cycle, driving laser pulses are required to generate isolated soft X-ray bursts efficiently, to mitigate group velocity walk-off between the laser and the X-ray fields that otherwise limit the conversion efficiency. Our work demonstrates a clear and straightforward approach for robustly generating bright isolated attosecond pulses of electromagnetic radiation throughout the soft X-ray region of the spectrum.

Published
2014

21. Observation and Control of Shock Waves in Individual Nanoplasmas

Author

Hickstein, Daniel D, Dollar, Franklin, Gaffney, Jim A, Foord, Mark E, Petrov, George M, Palm, Brett B, Keister, K Ellen, Ellis, Jennifer L, Ding, Chengyuan, Libby, Stephen B, Jimenez, Jose L, Kapteyn, Henry C, Murnane, Margaret M, and Xiong, Wei

Subjects
Hydrodynamics, Lasers, Nanoparticles, Nanotechnology, Nitrates, Plasma Gases, physics.plasm-ph, physics.atm-clus, Mathematical Sciences, Physical Sciences, Engineering, General Physics
Abstract

Using an apparatus that images the momentum distribution of individual, isolated 100-nm-scale plasmas, we make the first experimental observation of shock waves in nanoplasmas. We demonstrate that the introduction of a heating pulse prior to the main laser pulse increases the intensity of the shock wave, producing a strong burst of quasimonoenergetic ions with an energy spread of less than 15%. Numerical hydrodynamic calculations confirm the appearance of accelerating shock waves and provide a mechanism for the generation and control of these shock waves. This observation of distinct shock waves in dense plasmas enables the control, study, and exploitation of nanoscale shock phenomena with tabletop-scale lasers.

Published
2014

22. High flux coherent super-continuum soft X-ray source driven by a single-stage, 10mJ, Ti:sapphire amplifier-pumped OPA.

Author

Ding, Chengyuan, Xiong, Wei, Fan, Tingting, Hickstein, Daniel D, Popmintchev, Tenio, Zhang, Xiaoshi, Walls, Mike, Murnane, Margaret M, and Kapteyn, Henry C

Subjects
physics.optics, Optical Physics, Electrical and Electronic Engineering, Communications Technologies, Optics
Abstract

We demonstrate the highest flux tabletop source of coherent soft X-rays to date, driven by a single-stage 10 mJ Ti:sapphire regenerative amplifier at 1 kHz. We first down-convert the laser to 1.3 µm using a parametric amplifier, before up-converting it to soft X-rays using high harmonic generation in a high-pressure, phase matched, hollow waveguide geometry. The resulting optimally phase matched broadband spectrum extends to 200 eV, with a soft X-ray photon flux of > 10(6) photons/pulse/1% bandwidth at 1 kHz, corresponding to > 10(9) photons/s/1% bandwidth, or approximately a three order-of-magnitude increase compared with past work. Finally, using this broad bandwidth X-ray source, we demonstrate X-ray absorption spectroscopy of multiple elements and transitions in molecules in a single spectrum, with a spectral resolution of 0.25 eV, and with the ability to resolve the near edge fine structure.

Published
2014

25. Supercontinuum generation in the enhanced frequency chirp regime in multipass cells

Author

Segundo Staels Víctor W., Conejero Jarque Enrique, Carlson Daniel, Hemmer Michaël, Kapteyn Henry C., Murnane Margaret M., and San Roman Julio

Subjects
Physics, QC1-999
Abstract

We identify, via numerical simulations, the regime of enhanced frequency chirp during nonlinear propagation in multipass cell. This regime - used before the dawn of chirped pulse amplification to generate ultrashort pulses - paves the way for the generation of temporally clean few-cycle pulses. Here, we demonstrate numerically that the spectra of pulses from an Yb-based laser system can be broadened into a flat supercontinuum with a smooth spectral phase compatible with a clean few-cycle pulse with temporal secondary structures with peak intensity below 0.5% that of the main peak.

Published
2022
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28. Tabletop extreme ultraviolet reflectometer for quantitative nanoscale reflectometry, scatterometry, and imaging.

Author

Esashi, Yuka, Jenkins, Nicholas W., Shao, Yunzhe, Shaw, Justin M., Park, Seungbeom, Murnane, Margaret M., Kapteyn, Henry C., and Tanksalvala, Michael

Subjects
REFLECTOMETRY, REFLECTOMETER, MATERIALS science, SEMICONDUCTOR materials, SPATIAL resolution
Abstract

Imaging using coherent extreme-ultraviolet (EUV) light provides exceptional capabilities for the characterization of the composition and geometry of nanostructures by probing with high spatial resolution and elemental specificity. We present a multi-modal tabletop EUV imaging reflectometer for high-fidelity metrology of nanostructures. The reflectometer is capable of measurements in three distinct modes: intensity reflectometry, scatterometry, and imaging reflectometry, where each mode addresses different nanostructure characterization challenges. We demonstrate the system's unique ability to quantitatively and non-destructively measure the geometry and composition of nanostructures with tens of square microns field of view and sub-nanometer precision. Parameters such as surface and line edge roughness, density, nanostructure linewidth, and profile, as well as depth-resolved composition, can be quantitatively determined. The results highlight the applicability of EUV metrology to address a wide range of semiconductor and materials science challenges. [ABSTRACT FROM AUTHOR]

Published
2023
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30. Polarization control of isolated high-harmonic pulses

Author

Huang, Pei-Chi, Hernández-García, Carlos, Huang, Jen-Ting, Huang, Po-Yao, Lu, Chih-Hsuan, Rego, Laura, Hickstein, Daniel D., Ellis, Jennifer L., Jaron-Becker, Agnieszka, Becker, Andreas, Yang, Shang-Da, Durfee, Charles G., Plaja, Luis, Kapteyn, Henry C., Murnane, Margaret M., Kung, A. H., and Chen, Ming-Chang

Published
2018
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34. Bright Coherent Ultrahigh Harmonics in the keV X-ray Regime from Mid-Infrared Femtosecond Lasers

Author

Popmintchev, Tenio, Chen, Ming-Chang, Popmintchev, Dimitar, Arpin, Paul, Brown, Susannah, Ališauskas, Skirmantas, Andriukaitis, Giedrius, Balčiunas, Tadas, Mücke, Oliver D., Pugzlys, Audrius, Baltuška, Andrius, Shim, Bonggu, Schrauth, Samuel E., Gaeta, Alexander, Hernández-García, Carlos, Plaja, Luis, Becker, Andreas, Jaron-Becker, Agnieszka, Murnane, Margaret M., and Kapteyn, Henry C.

Published
2012
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35. Probing the timescale of the exchange interaction in a ferromagnetic alloy

Author

Mathias, Stefan, La-O-Vorakiat, Chan, Grychtol, Patrik, Granitzka, Patrick, Turgut, Emrah, Shaw, Justin M., Adam, Roman, Nembach, Hans T., Siemens, Mark E., Eich, Steffen, Schneider, Claus M., Silva, Thomas J., Aeschlimann, Martin, Murnane, Margaret M., and Kapteyn, Henry C.

Published
2012

43. LASER PHYSICS: Ultraviolet surprise: Efficient soft x-ray high-harmonic generation in multiply ionized plasmas

Author

Popmintchev, Dimitar, Hernández-García, Carlos, Dollar, Franklin, Mancuso, Christopher, Pérez-Hernández, Jose A., Chen, Ming-Chang, Hankla, Amelia, Gao, Xiaohui, Shim, Bonggu, Gaeta, Alexander L., Tarazkar, Maryam, Romanov, Dmitri A., Levis, Robert J., Gaffney, Jim A., Foord, Mark, Libby, Stephen B., Jaron-Becker, Agnieszka, Becker, Andreas, Plaja, Luis, Murnane, Margaret M., Kapteyn, Henry C., and Popmintchev, Tenio

Published
2015
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46. Structural and Elastic Properties of Empty-Pore Metalattices Extracted via Nondestructive Coherent Extreme UV Scatterometry and Electron Tomography.

Author

Knobloch, Joshua L., McBennett, Brendan, Bevis, Charles S., Yazdi, Sadegh, Frazer, Travis D., Adak, Amitava, Nelson, Emma E., Hernández-Charpak, Jorge N., Cheng, Hiu Y., Grede, Alex J., Mahale, Pratibha, Nova, Nabila Nabi, Giebink, Noel C., Mallouk, Thomas E., Badding, John V., Kapteyn, Henry C., Abad, Begoña, and Murnane, Margaret M.

Published
2022
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49. Phase-matching techniques for coherent soft x-ray generation

Author

Paul, Ariel, Gibson, Emily A., Christov, Ivan P., Xiaoshi Zhang, Murnane, Margaret M., Lytle, Amy, Xibin Zhou, Popmintchev, Tenio, and Kapteyn, Henry C.

Subjects
Coherent states -- Research, Optical waveguides -- Design and construction, Optics -- Research, Business, Computers, Electronics, Electronics and electrical industries
Abstract

Extreme nonlinear optics obtained by focusing an intense laser into a gas can be used to generate coherent beams at soft X-ray (SXR) wavelengths. Phase-matching and quasi-phase-matching techniques that use gas-filled modulated waveguides to enhance the frequency conversion process leads to the generation of SXR beams that are both spatially and temporally coherent.

Published
2006

50. Creation of a novel inverted charge density wave state.

Author

Zhang, Yingchao, Shi, Xun, Guan, Mengxue, You, Wenjing, Zhong, Yigui, Kafle, Tika R., Huang, Yaobo, Ding, Hong, Bauer, Michael, Rossnagel, Kai, Meng, Sheng, Kapteyn, Henry C., and Murnane, Margaret M.

Subjects
CHARGE density waves, TIME-dependent density functional theory, DENSITY of states, PHOTOEMISSION, SUPERCONDUCTING transitions, PHOTOELECTRON spectroscopy, TIME-resolved spectroscopy
Abstract

Charge density wave (CDW) order is an emergent quantum phase that is characterized by periodic lattice distortion and charge density modulation, often present near superconducting transitions. Here, we uncover a novel inverted CDW state by using a femtosecond laser to coherently reverse the star-of-David lattice distortion in 1T-TaSe2. We track the signature of this novel CDW state using time- and angle-resolved photoemission spectroscopy and the time-dependent density functional theory to validate that it is associated with a unique lattice and charge arrangement never before realized. The dynamic electronic structure further reveals its novel properties that are characterized by an increased density of states near the Fermi level, high metallicity, and altered electron–phonon couplings. Our results demonstrate how ultrafast lasers can be used to create unique states in materials by manipulating charge-lattice orders and couplings. [ABSTRACT FROM AUTHOR]

Published
2022
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