Your search keyword '"Kapteyn HC"' showing total 23 results

1. Non-Equilibrium Dynamics in Two-Color, Few-Photon Dissociative Excitation and Ionization of D$_2$

Author

Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, Weber, Th, Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, and Weber, Th

Abstract

D$_2$ molecules, excited by linearly cross-polarized femtosecond extreme ultraviolet (XUV) and near-infrared (NIR) light pulses, reveal highly structured D$^+$ ion fragment momenta and angular distributions that originate from two different 4-step dissociative ionization pathways after four photon absorption (1 XUV + 3 NIR). We show that, even for very low dissociation kinetic energy release $\le$~240~meV, specific electronic excitation pathways can be identified and isolated in the final ion momentum distributions. With the aid of {\it ab initio} electronic structure and time-dependent Schr\"odinger equation calculations, angular momentum, energy, and parity conservation are used to identify the excited neutral molecular states and molecular orientations relative to the polarization vectors in these different photoexcitation and dissociation sequences of the neutral D$_2$ molecule and its D$_2^+$ cation. In one sequential photodissociation pathway, molecules aligned along either of the two light polarization vectors are excluded, while another pathway selects molecules aligned parallel to the light propagation direction. The evolution of the nuclear wave packet on the intermediate \Bstate electronic state of the neutral D$_2$ molecule is also probed in real time.

Published

2021

2. Nonequilibrium dissociative dynamics of D2 in two-color, few-photon excitation and ionization

Author

Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, Weber, T, Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, and Weber, T

Abstract

D2 molecules, excited by linearly cross-polarized femtosecond extreme ultraviolet (XUV) and near-infrared (NIR) light pulses, reveal highly structured D+ ion fragment momenta and angular distributions that originate from two different four-step dissociative ionization pathways after four-photon absorption (one XUV + three NIR). We show that, even for very low dissociation kinetic energy release ≤ 240 meV, specific electronic excitation pathways can be identified and isolated in the final ion momentum distributions. With the aid of ab initio electronic structure and time-dependent Schrödinger equation calculations, angular momentum, energy, and parity conservation are used to identify the excited neutral molecular states and molecular orientations relative to the polarization vectors in these different photoexcitation and dissociation sequences of the neutral D2 molecule and its D2+ cation. In one sequential photodissociation pathway, molecules aligned along either of the two light polarization vectors are excluded, while another pathway selects molecules aligned parallel to the light propagation direction. The evolution of the nuclear wave packet on the intermediate B1ςu+ electronic state of the neutral D2 molecule is also probed in real time.

Published

2021

3. Non-Equilibrium Dynamics in Two-Color, Few-Photon Dissociative Excitation and Ionization of D$_2$

Author

Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, Weber, Th, Slaughter, DS, Slaughter, DS, Sturm, FP, Bello, RY, Larsen, KA, Shivaram, N, McCurdy, CW, Lucchese, RR, Martin, L, Hogle, CW, Murnane, MM, Kapteyn, HC, Ranitovic, P, and Weber, Th

Abstract

D$_2$ molecules, excited by linearly cross-polarized femtosecond extreme ultraviolet (XUV) and near-infrared (NIR) light pulses, reveal highly structured D$^+$ ion fragment momenta and angular distributions that originate from two different 4-step dissociative ionization pathways after four photon absorption (1 XUV + 3 NIR). We show that, even for very low dissociation kinetic energy release $\le$~240~meV, specific electronic excitation pathways can be identified and isolated in the final ion momentum distributions. With the aid of {\it ab initio} electronic structure and time-dependent Schr\"odinger equation calculations, angular momentum, energy, and parity conservation are used to identify the excited neutral molecular states and molecular orientations relative to the polarization vectors in these different photoexcitation and dissociation sequences of the neutral D$_2$ molecule and its D$_2^+$ cation. In one sequential photodissociation pathway, molecules aligned along either of the two light polarization vectors are excluded, while another pathway selects molecules aligned parallel to the light propagation direction. The evolution of the nuclear wave packet on the intermediate \Bstate electronic state of the neutral D$_2$ molecule is also probed in real time.

Published

2021

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

Author

Frazer, TD, Frazer, TD, Knobloch, JL, Hernández-Charpak, JN, Hoogeboom-Pot, KM, Nardi, D, Yazdi, S, Chao, W, Anderson, EH, Tripp, MK, King, SW, Kapteyn, HC, Murnane, MM, Abad, B, Frazer, TD, Frazer, TD, Knobloch, JL, Hernández-Charpak, JN, Hoogeboom-Pot, KM, Nardi, D, Yazdi, S, Chao, W, Anderson, EH, Tripp, MK, King, SW, Kapteyn, HC, Murnane, MM, and Abad, B

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

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

Author

Frazer, TD, Frazer, TD, Knobloch, JL, Hernández-Charpak, JN, Hoogeboom-Pot, KM, Nardi, D, Yazdi, S, Chao, W, Anderson, EH, Tripp, MK, King, SW, Kapteyn, HC, Murnane, MM, Abad, B, Frazer, TD, Frazer, TD, Knobloch, JL, Hernández-Charpak, JN, Hoogeboom-Pot, KM, Nardi, D, Yazdi, S, Chao, W, Anderson, EH, Tripp, MK, King, SW, Kapteyn, HC, Murnane, MM, and Abad, B

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

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

Author

Frazer, TD, Frazer, TD, Knobloch, JL, Hoogeboom-Pot, KM, Nardi, D, Chao, W, Falcone, RW, Murnane, MM, Kapteyn, HC, Hernandez-Charpak, JN, Frazer, TD, Frazer, TD, Knobloch, JL, Hoogeboom-Pot, KM, Nardi, D, Chao, W, Falcone, RW, Murnane, MM, Kapteyn, HC, and Hernandez-Charpak, JN

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

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

Author

Frazer, TD, Frazer, TD, Knobloch, JL, Hoogeboom-Pot, KM, Nardi, D, Chao, W, Falcone, RW, Murnane, MM, Kapteyn, HC, Hernandez-Charpak, JN, Frazer, TD, Frazer, TD, Knobloch, JL, Hoogeboom-Pot, KM, Nardi, D, Chao, W, Falcone, RW, Murnane, MM, Kapteyn, HC, and Hernandez-Charpak, JN

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

8. Revealing the role of electron-electron correlations by mapping dissociation of highly excited D2+ using ultrashort XUV pulses

Author

Martin, L, Martin, L, Bello, RY, Hogle, CW, Palacios, A, Tong, XM, Sanz-Vicario, JL, Jahnke, T, Schöffler, M, Dörner, R, Weber, T, Martín, F, Kapteyn, HC, Murnane, MM, Ranitovic, P, Martin, L, Martin, L, Bello, RY, Hogle, CW, Palacios, A, Tong, XM, Sanz-Vicario, JL, Jahnke, T, Schöffler, M, Dörner, R, Weber, T, Martín, F, Kapteyn, HC, Murnane, MM, and Ranitovic, P

Abstract

Understanding electron-electron correlations in matter ranging from atoms to solids represents a grand challenge for both experiment and theory. These correlations occur on attosecond timescales and have only recently become experimentally accessible. In the case of highly excited systems, the task of understanding and probing correlated interactions is even greater. In this work, we combine state-of-the-art light sources and advanced detection techniques with ab initio calculations to unravel the role of electron-electron correlation in D2 photoionization by mapping the dissociation of a highly excited D2+ molecule. Correlations between the two electrons dictate the pathways along which the molecule dissociates and lead to a superposition of excited ionic states. Using 3D Coulomb explosion imaging and electron-ion coincidence techniques, we assess the relative contribution of competing parent ion states to the dissociation process for different orientations of the molecule with respect to the laser polarization, which is consistent with a shake-up ionization process. As a step toward observing coherent superposition experimentally, we map the relevant nuclear potentials using Coulomb explosion imaging and show theoretically that such an experiment could confirm this coherence via two-path interference.

Published

2018

9. Revealing the role of electron-electron correlations by mapping dissociation of highly excited D2+ using ultrashort XUV pulses

Author

Martin, L, Martin, L, Bello, RY, Hogle, CW, Palacios, A, Tong, XM, Sanz-Vicario, JL, Jahnke, T, Schöffler, M, Dörner, R, Weber, T, Martín, F, Kapteyn, HC, Murnane, MM, Ranitovic, P, Martin, L, Martin, L, Bello, RY, Hogle, CW, Palacios, A, Tong, XM, Sanz-Vicario, JL, Jahnke, T, Schöffler, M, Dörner, R, Weber, T, Martín, F, Kapteyn, HC, Murnane, MM, and Ranitovic, P

Abstract

Understanding electron-electron correlations in matter ranging from atoms to solids represents a grand challenge for both experiment and theory. These correlations occur on attosecond timescales and have only recently become experimentally accessible. In the case of highly excited systems, the task of understanding and probing correlated interactions is even greater. In this work, we combine state-of-the-art light sources and advanced detection techniques with ab initio calculations to unravel the role of electron-electron correlation in D2 photoionization by mapping the dissociation of a highly excited D2+ molecule. Correlations between the two electrons dictate the pathways along which the molecule dissociates and lead to a superposition of excited ionic states. Using 3D Coulomb explosion imaging and electron-ion coincidence techniques, we assess the relative contribution of competing parent ion states to the dissociation process for different orientations of the molecule with respect to the laser polarization, which is consistent with a shake-up ionization process. As a step toward observing coherent superposition experimentally, we map the relevant nuclear potentials using Coulomb explosion imaging and show theoretically that such an experiment could confirm this coherence via two-path interference.

Published

2018

10. Picosecond ionization dynamics in femtosecond filaments at high pressures

Author

Gao, X, Gao, X, Patwardhan, G, Schrauth, S, Zhu, D, Popmintchev, T, Kapteyn, HC, Murnane, MM, Romanov, DA, Levis, RJ, Gaeta, AL, Gao, X, Gao, X, Patwardhan, G, Schrauth, S, Zhu, D, Popmintchev, T, Kapteyn, HC, Murnane, MM, Romanov, DA, Levis, RJ, and Gaeta, AL

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

11. Isolated broadband attosecond pulse generation with near- and mid-infrared driver pulses via time-gated phase matching.

Author

Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, Jaron-Becker, A, Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, and Jaron-Becker, A

Abstract

We present a theoretical analysis of the time-gated phase matching (ionization gating) mechanism in high-order harmonic generation for the isolation of attosecond pulses at near-infrared and mid-infrared driver wavelengths, for both few-cycle and multi-cycle driving laser pulses. Results of our high harmonic generation and three-dimensional propagation simulations show that broadband isolated pulses spanning from the extreme-ultraviolet well into the soft X-ray region of the spectrum can be generated for both few-cycle and multi-cycle laser pulses. We demonstrate the key role of absorption and group velocity matching for generating bright, isolated, attosecond pulses using long wavelength multi-cycle pulses. Finally, we show that this technique is robust against carrier-envelope phase and peak intensity variations.

Published

2017

12. Isolated broadband attosecond pulse generation with near- and mid-infrared driver pulses via time-gated phase matching.

Author

Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, Jaron-Becker, A, Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, and Jaron-Becker, A

Abstract

We present a theoretical analysis of the time-gated phase matching (ionization gating) mechanism in high-order harmonic generation for the isolation of attosecond pulses at near-infrared and mid-infrared driver wavelengths, for both few-cycle and multi-cycle driving laser pulses. Results of our high harmonic generation and three-dimensional propagation simulations show that broadband isolated pulses spanning from the extreme-ultraviolet well into the soft X-ray region of the spectrum can be generated for both few-cycle and multi-cycle laser pulses. We demonstrate the key role of absorption and group velocity matching for generating bright, isolated, attosecond pulses using long wavelength multi-cycle pulses. Finally, we show that this technique is robust against carrier-envelope phase and peak intensity variations.

Published

2017

13. Picosecond ionization dynamics in femtosecond filaments at high pressures

Author

Gao, X, Gao, X, Patwardhan, G, Schrauth, S, Zhu, D, Popmintchev, T, Kapteyn, HC, Murnane, MM, Romanov, DA, Levis, RJ, Gaeta, AL, Gao, X, Gao, X, Patwardhan, G, Schrauth, S, Zhu, D, Popmintchev, T, Kapteyn, HC, Murnane, MM, Romanov, DA, Levis, RJ, and Gaeta, AL

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

14. Group velocity matching in high-order harmonic generation driven by mid-infrared lasers

Author

Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, Jaron-Becker, A, Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, and Jaron-Becker, A

Abstract

We analyze the role of group-velocity matching (GVM) in the macroscopic build up of the high-harmonic signal generated in gas targets at high pressures. A definition of the walk-off length, associated with GVM, in the non-perturbative intensity regime of high-harmonic generation is given. Semiclassical predictions based on this definition are in excellent agreement with full quantum simulations. We demonstrate that group velocity matching is a relevant factor in high harmonic generation and the isolation of attosecond pulses driven by long wavelength lasers and preferentially selects contributions from the short quantum trajectories.

Published

2016

15. Schemes for generation of isolated attosecond pulses of pure circular polarization

Author

Hernández-García, C, Hernández-García, C, Durfee, CG, Hickstein, DD, Popmintchev, T, Meier, A, Murnane, MM, Kapteyn, HC, Sola, IJ, Jaron-Becker, A, Becker, A, Hernández-García, C, Hernández-García, C, Durfee, CG, Hickstein, DD, Popmintchev, T, Meier, A, Murnane, MM, Kapteyn, HC, Sola, IJ, Jaron-Becker, A, and Becker, A

Abstract

We propose and analyze two schemes capable of generating isolated attosecond pulses of pure circular polarization, based on results of numerical simulations. Both schemes utilize the generation of circularly polarized high-order-harmonics by crossing two circularly polarized counter-rotating pulses in a noncollinear geometry. Our results show that in this setup isolation of a single attosecond pulse can be achieved either by restricting the driver pulse duration to a few cycles or by temporally delaying the two crossed driver pulses. We further propose to compensate the temporal walk-off between the pulses across the focal spot and increasing the conversion efficiency by using angular spatial chirp to provide perfectly matched pulse fronts. The isolation of pure circularly polarized attosecond pulses, along with the opportunity to select their central energy and helicity in the noncollinear technique, opens new perspectives from which to study ultrafast dynamics in chiral systems and magnetic materials.

Published

2016

16. Self-amplified photo-induced gap quenching in a correlated electron material.

Author

Mathias, S, Mathias, S, Eich, S, Urbancic, J, Michael, S, Carr, AV, Emmerich, S, Stange, A, Popmintchev, T, Rohwer, T, Wiesenmayer, M, Ruffing, A, Jakobs, S, Hellmann, S, Matyba, P, Chen, C, Kipp, L, Bauer, M, Kapteyn, HC, Schneider, HC, Rossnagel, K, Murnane, MM, Aeschlimann, M, Mathias, S, Mathias, S, Eich, S, Urbancic, J, Michael, S, Carr, AV, Emmerich, S, Stange, A, Popmintchev, T, Rohwer, T, Wiesenmayer, M, Ruffing, A, Jakobs, S, Hellmann, S, Matyba, P, Chen, C, Kipp, L, Bauer, M, Kapteyn, HC, Schneider, HC, Rossnagel, K, Murnane, MM, and Aeschlimann, M

Abstract

Capturing the dynamic electronic band structure of a correlated material presents a powerful capability for uncovering the complex couplings between the electronic and structural degrees of freedom. When combined with ultrafast laser excitation, new phases of matter can result, since far-from-equilibrium excited states are instantaneously populated. Here, we elucidate a general relation between ultrafast non-equilibrium electron dynamics and the size of the characteristic energy gap in a correlated electron material. We show that carrier multiplication via impact ionization can be one of the most important processes in a gapped material, and that the speed of carrier multiplication critically depends on the size of the energy gap. In the case of the charge-density wave material 1T-TiSe2, our data indicate that carrier multiplication and gap dynamics mutually amplify each other, which explains-on a microscopic level-the extremely fast response of this material to ultrafast optical excitation.

Published

2016

17. Group velocity matching in high-order harmonic generation driven by mid-infrared lasers

Author

Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, Jaron-Becker, A, Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, and Jaron-Becker, A

Abstract

We analyze the role of group-velocity matching (GVM) in the macroscopic build up of the high-harmonic signal generated in gas targets at high pressures. A definition of the walk-off length, associated with GVM, in the non-perturbative intensity regime of high-harmonic generation is given. Semiclassical predictions based on this definition are in excellent agreement with full quantum simulations. We demonstrate that group velocity matching is a relevant factor in high harmonic generation and the isolation of attosecond pulses driven by long wavelength lasers and preferentially selects contributions from the short quantum trajectories.

Published

2016

18. Self-amplified photo-induced gap quenching in a correlated electron material.

Author

Mathias, S, Mathias, S, Eich, S, Urbancic, J, Michael, S, Carr, AV, Emmerich, S, Stange, A, Popmintchev, T, Rohwer, T, Wiesenmayer, M, Ruffing, A, Jakobs, S, Hellmann, S, Matyba, P, Chen, C, Kipp, L, Bauer, M, Kapteyn, HC, Schneider, HC, Rossnagel, K, Murnane, MM, Aeschlimann, M, Mathias, S, Mathias, S, Eich, S, Urbancic, J, Michael, S, Carr, AV, Emmerich, S, Stange, A, Popmintchev, T, Rohwer, T, Wiesenmayer, M, Ruffing, A, Jakobs, S, Hellmann, S, Matyba, P, Chen, C, Kipp, L, Bauer, M, Kapteyn, HC, Schneider, HC, Rossnagel, K, Murnane, MM, and Aeschlimann, M

Abstract

Capturing the dynamic electronic band structure of a correlated material presents a powerful capability for uncovering the complex couplings between the electronic and structural degrees of freedom. When combined with ultrafast laser excitation, new phases of matter can result, since far-from-equilibrium excited states are instantaneously populated. Here, we elucidate a general relation between ultrafast non-equilibrium electron dynamics and the size of the characteristic energy gap in a correlated electron material. We show that carrier multiplication via impact ionization can be one of the most important processes in a gapped material, and that the speed of carrier multiplication critically depends on the size of the energy gap. In the case of the charge-density wave material 1T-TiSe2, our data indicate that carrier multiplication and gap dynamics mutually amplify each other, which explains-on a microscopic level-the extremely fast response of this material to ultrafast optical excitation.

Published

2016

19. Schemes for generation of isolated attosecond pulses of pure circular polarization

Author

Hernández-García, C, Hernández-García, C, Durfee, CG, Hickstein, DD, Popmintchev, T, Meier, A, Murnane, MM, Kapteyn, HC, Sola, IJ, Jaron-Becker, A, Becker, A, Hernández-García, C, Hernández-García, C, Durfee, CG, Hickstein, DD, Popmintchev, T, Meier, A, Murnane, MM, Kapteyn, HC, Sola, IJ, Jaron-Becker, A, and Becker, A

Abstract

We propose and analyze two schemes capable of generating isolated attosecond pulses of pure circular polarization, based on results of numerical simulations. Both schemes utilize the generation of circularly polarized high-order-harmonics by crossing two circularly polarized counter-rotating pulses in a noncollinear geometry. Our results show that in this setup isolation of a single attosecond pulse can be achieved either by restricting the driver pulse duration to a few cycles or by temporally delaying the two crossed driver pulses. We further propose to compensate the temporal walk-off between the pulses across the focal spot and increasing the conversion efficiency by using angular spatial chirp to provide perfectly matched pulse fronts. The isolation of pure circularly polarized attosecond pulses, along with the opportunity to select their central energy and helicity in the noncollinear technique, opens new perspectives from which to study ultrafast dynamics in chiral systems and magnetic materials.

Published

2016

20. Group velocity matching in high-order harmonic generation driven by mid-infrared lasers

Author

Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, Jaron-Becker, A, Hernández-García, C, Hernández-García, C, Popmintchev, T, Murnane, MM, Kapteyn, HC, Plaja, L, Becker, A, and Jaron-Becker, A

Abstract

We analyze the role of group-velocity matching (GVM) in the macroscopic build up of the high-harmonic signal generated in gas targets at high pressures. A definition of the walk-off length, associated with GVM, in the non-perturbative intensity regime of high-harmonic generation is given. Semiclassical predictions based on this definition are in excellent agreement with full quantum simulations. We demonstrate that group velocity matching is a relevant factor in high harmonic generation and the isolation of attosecond pulses driven by long wavelength lasers and preferentially selects contributions from the short quantum trajectories.

Published

2016

21. Time- and angle-resolved photoemission spectroscopy with optimized high-harmonic pulses using frequency-doubled Ti:Sapphire lasers

Author

Eich, S, Eich, S, Stange, A, Carr, AV, Urbancic, J, Popmintchev, T, Wiesenmayer, M, Jansen, K, Ruffing, A, Jakobs, S, Rohwer, T, Hellmann, S, Chen, C, Matyba, P, Kipp, L, Rossnagel, K, Bauer, M, Murnane, MM, Kapteyn, HC, Mathias, S, Aeschlimann, M, Eich, S, Eich, S, Stange, A, Carr, AV, Urbancic, J, Popmintchev, T, Wiesenmayer, M, Jansen, K, Ruffing, A, Jakobs, S, Rohwer, T, Hellmann, S, Chen, C, Matyba, P, Kipp, L, Rossnagel, K, Bauer, M, Murnane, MM, Kapteyn, HC, Mathias, S, and Aeschlimann, M

Abstract

Time- and angle-resolved photoemission spectroscopy (trARPES) using femtosecond extreme ultraviolet high harmonics has recently emerged as a powerful tool for investigating ultrafast quasiparticle dynamics in correlated-electron materials. However, the full potential of this approach has not yet been achieved because, to date, high harmonics generated by 800 nm wavelength Ti:Sapphire lasers required a trade-off between photon flux, energy and time resolution. Photoemission spectroscopy requires a quasi-monochromatic output, but dispersive optical elements that select a single harmonic can significantly reduce the photon flux and time resolution. Here we show that 400 nm driven high harmonic extreme-ultraviolet trARPES is superior to using 800 nm laser drivers since it eliminates the need for any spectral selection, thereby increasing photon flux and energy resolution to < 150 meV while preserving excellent time resolution of about 30 fs. © 2014 The Authors.

Published

2014

22. Time- and angle-resolved photoemission spectroscopy with optimized high-harmonic pulses using frequency-doubled Ti:Sapphire lasers

Author

Eich, S, Eich, S, Stange, A, Carr, AV, Urbancic, J, Popmintchev, T, Wiesenmayer, M, Jansen, K, Ruffing, A, Jakobs, S, Rohwer, T, Hellmann, S, Chen, C, Matyba, P, Kipp, L, Rossnagel, K, Bauer, M, Murnane, MM, Kapteyn, HC, Mathias, S, Aeschlimann, M, Eich, S, Eich, S, Stange, A, Carr, AV, Urbancic, J, Popmintchev, T, Wiesenmayer, M, Jansen, K, Ruffing, A, Jakobs, S, Rohwer, T, Hellmann, S, Chen, C, Matyba, P, Kipp, L, Rossnagel, K, Bauer, M, Murnane, MM, Kapteyn, HC, Mathias, S, and Aeschlimann, M

Abstract

Time- and angle-resolved photoemission spectroscopy (trARPES) using femtosecond extreme ultraviolet high harmonics has recently emerged as a powerful tool for investigating ultrafast quasiparticle dynamics in correlated-electron materials. However, the full potential of this approach has not yet been achieved because, to date, high harmonics generated by 800 nm wavelength Ti:Sapphire lasers required a trade-off between photon flux, energy and time resolution. Photoemission spectroscopy requires a quasi-monochromatic output, but dispersive optical elements that select a single harmonic can significantly reduce the photon flux and time resolution. Here we show that 400 nm driven high harmonic extreme-ultraviolet trARPES is superior to using 800 nm laser drivers since it eliminates the need for any spectral selection, thereby increasing photon flux and energy resolution to < 150 meV while preserving excellent time resolution of about 30 fs. © 2014 The Authors.

Published

2014

23. Probing Thermomechanics at the Nanoscale: Impulsively Excited Pseudosurface Acoustic Waves in Hypersonic Phononic Crystals.

Author

Nardi, Damiano, Travagliati, Marco, Siemens, Me, Li, Q, Murnane, Mm, Kapteyn, Hc, Ferrini, Gabriele, Parmigiani, Fulvio, Banfi, Francesco, Ferrini, Gabriele (ORCID:0000-0002-5062-9099), Banfi, Francesco (ORCID:0000-0002-7465-8417), Nardi, Damiano, Travagliati, Marco, Siemens, Me, Li, Q, Murnane, Mm, Kapteyn, Hc, Ferrini, Gabriele, Parmigiani, Fulvio, Banfi, Francesco, Ferrini, Gabriele (ORCID:0000-0002-5062-9099), and Banfi, Francesco (ORCID:0000-0002-7465-8417)

Abstract

High-frequency surface acoustic waves can be generated by ultrafast laser excitation of nanoscale patterned surfaces. Here we study this phenomenon in the hypersonic frequency limit. By modeling the thermomechanics from first-principles, we calculate the system's initial heat-driven impulsive response and follow its time evolution. A scheme is introduced to quantitatively access frequencies and lifetimes of the composite system's excited eigenmodes. A spectral decomposition of the calculated response on the eigemodes of the system reveals asymmetric resonances that result from the coupling between surface and bulk acoustic modes. This finding allows evaluation of impulsively excited pseudosurface acoustic wave frequencies and lifetimes and expands our understanding of the scattering of surface waves in mesoscale metamaterials. The model is successfully benchmarked against time-resolved optical diffraction measurements performed on one dimensional and two-dimensional surface phononic crystals, probed using light at extreme ultraviolet and near-infrared wavelengths.

Published

2011