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Your search keyword '"Haglund, Richard F."' showing total 22 results
Start Over Author "Haglund, Richard F." Publisher american chemical society
22 results on '"Haglund, Richard F."'

3. Enhanced Broadband and Harmonic Upconversion from Coupled Semiconductor and Metal Nanoparticle Films.

Author

Spear, Nathan J., Hallman, Kent A., Hernández-Pagán, Emil A., Davidson II, Roderick B., Arrowood, Summer L., Wistuba, Amanda L., Tan, Wenze, Haglund, Richard F., and Macdonald, Janet E.

Abstract

The enhancement of the nonlinear optical properties of hybrid nanoparticle films by coupling between metallic and plasmonic semiconducting nanoparticles is shown. A heterostructure comprising CuS and Au nanoparticle films separated by a thin layer of insulating ligands enhanced the yield of second-harmonic light by a factor of 3.3 compared with the sum of the constituent nanoparticles on their own. Heterostructures were fabricated with scalable solution-processing techniques that can create devices of arbitrary geometry. In addition to harmonic generation, the multiple-photon photoluminescence response of Au, CuS, and heterostructured films is also explored. [ABSTRACT FROM AUTHOR]

Published
2020
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11. Reconfigurable Multistate Optical Systems Enabled by VO 2 Phase Transitions.

Author

Duan X, White ST, Cui Y, Neubrech F, Gao Y, Haglund RF, and Liu N

Abstract

Reconfigurable optical systems are the object of continuing, intensive research activities, as they hold great promise for realizing a new generation of compact, miniaturized, and flexible optical devices. However, current reconfigurable systems often tune only a single state variable triggered by an external stimulus, thus, leaving out many potential applications. Here we demonstrate a reconfigurable multistate optical system enabled by phase transitions in vanadium dioxide (VO 2 ). By controlling the phase-transition characteristics of VO 2 with simultaneous stimuli, the responses of the optical system can be reconfigured among multiple states. In particular, we show a quadruple-state dynamic plasmonic display that responds to both temperature tuning and hydrogen-doping. Furthermore, we introduce an electron-doping scheme to locally control the phase-transition behavior of VO 2 , enabling an optical encryption device encoded by multiple keys. Our work points the way toward advanced multistate reconfigurable optical systems, which substantially outperform current optical devices in both breadth of capabilities and functionalities., Competing Interests: The authors declare no competing financial interest., (© 2020 American Chemical Society.)

Published
2020
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12. Optical Limiting Based on Huygens' Metasurfaces.

Author

Howes A, Zhu Z, Curie D, Avila JR, Wheeler VD, Haglund RF, and Valentine JG

Abstract

Optical limiting is desirable or necessary in a variety of applications that employ high-power light sources or sensitive photodetectors. However, the most prevalent methods compromise between on-state transmission and turndown ratio or rely on narrow transmission windows. We demonstrate that a metasurface-based architecture incorporating phase-change materials enables both high and broadband on-state transmission (-4.8 dB) while also providing a large turndown ratio (25.2 dB). Additionally, this design can be extended for broadband multiwavelength limiting due to the high off-resonance transmittance and readily scalable resonant wavelength. Furthermore, our choice of active material allows for protection in ultrafast laser environments due to the speed of the phase transition. These benefits offer a strong alternative to state-of-the-art optical limiters in technologies ranging from sensor protection to protective eyewear.

Published
2020
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13. Imaging Nanometer Phase Coexistence at Defects During the Insulator-Metal Phase Transformation in VO 2 Thin Films by Resonant Soft X-ray Holography.

Author

Vidas L, Günther CM, Miller TA, Pfau B, Perez-Salinas D, Martínez E, Schneider M, Gührs E, Gargiani P, Valvidares M, Marvel RE, Hallman KA, Haglund RF Jr, Eisebitt S, and Wall S

Abstract

We use resonant soft X-ray holography to image the insulator-metal phase transition in vanadium dioxide with element and polarization specificity and nanometer spatial resolution. We observe that nanoscale inhomogeneity in the film results in spatial-dependent transition pathways between the insulating and metallic states. Additional nanoscale phases form in the vicinity of defects which are not apparent in the initial or final states of the system, which would be missed in area-integrated X-ray absorption measurements. These intermediate phases are vital to understand the phase transition in VO 2 , and our results demonstrate how resonant imaging can be used to understand the electronic properties of phase-separated correlated materials obtained by X-ray absorption.

Published
2018
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14. Dynamically Reconfigurable Metadevice Employing Nanostructured Phase-Change Materials.

Author

Zhu Z, Evans PG, Haglund RF Jr, and Valentine JG

Abstract

Mastering dynamic free-space spectral control and modulation in the near-infrared (NIR) and optical regimes remains a challenging task that is hindered by the available functional materials at high frequencies. In this work, we have realized an efficient metadevice capable of spectral control by minimizing the thermal mass of a vanadium dioxide phase-change material (PCM) and placing the PCM at the feed gap of a bow-tie field antenna. The device has an experimentally measured tuning range of up to 360 nm in the NIR and a modulation depth of 33% at the resonant wavelength. The metadevice is configured for integrated and local heating, leading to faster switching and more precise spatial control compared with devices based on phase-change thin films. We envisage that the combined advantages of this device will open new opportunities for signal processing, memory, security, and holography at optical frequencies.

Published
2017
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15. Ultrafast phase transition via catastrophic phonon collapse driven by plasmonic hot-electron injection.

Author

Appavoo K, Wang B, Brady NF, Seo M, Nag J, Prasankumar RP, Hilton DJ, Pantelides ST, and Haglund RF Jr

Abstract

Ultrafast photoinduced phase transitions could revolutionize data-storage and telecommunications technologies by modulating signals in integrated nanocircuits at terahertz speeds. In quantum phase-changing materials (PCMs), microscopic charge, lattice, and orbital degrees of freedom interact cooperatively to modify macroscopic electrical and optical properties. Although these interactions are well documented for bulk single crystals and thin films, little is known about the ultrafast dynamics of nanostructured PCMs when interfaced to another class of materials as in this case to active plasmonic elements. Here, we demonstrate how a mesh of gold nanoparticles, acting as a plasmonic photocathode, induces an ultrafast phase transition in nanostructured vanadium dioxide (VO2) when illuminated by a spectrally resonant femtosecond laser pulse. Hot electrons created by optical excitation of the surface-plasmon resonance in the gold nanomesh are injected ballistically across the Au/VO2 interface to induce a subpicosecond phase transformation in VO2. Density functional calculations show that a critical density of injected electrons leads to a catastrophic collapse of the 6 THz phonon mode, which has been linked in different experiments to VO2 phase transition. The demonstration of subpicosecond phase transformations that are triggered by optically induced electron injection opens the possibility of designing hybrid nanostructures with unique nonequilibrium properties as a critical step for all-optical nanophotonic devices with optimizable switching thresholds.

Published
2014
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16. Plasmonic probe of the semiconductor to metal phase transition in vanadium dioxide.

Author

Ferrara DW, Nag J, MacQuarrie ER, Kaye AB, and Haglund RF Jr

Subjects
Surface Plasmon Resonance, Gold chemistry, Nanoparticles chemistry, Oxides chemistry, Semiconductors, Vanadium Compounds chemistry
Abstract

An array of 180 nm diameter gold nanoparticles (NPs) embedded in a thin vanadium dioxide film was used as a nanoscale probe of the thermochromic semiconductor-to-metal transition (SMT) in the VO2. The observed 30% reduction in plasmon dephasing time resulted from the interaction between the localized surface plasmon resonance of the NPs with the 1.4 eV electronic transitions in VO2. The NPs act as nanoantennas probing the SMT; homogeneous broadening of the gold plasmon resonance is observed at the temperatures where electron correlations are strongest in VO2.

Published
2013
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17. Room-temperature reactions for self-cleaning molecular nanosensors.

Author

Warnick KH, Wang B, Cliffel DE, Wright DW, Haglund RF, and Pantelides ST

Abstract

New sensing techniques for detecting molecules, especially self-cleaning sensors, are in demand. Here we describe a room-temperature process in which a nanostructured substrate catalyzes the reaction of a target molecule with atmospheric oxygen and the reaction energy is absorbed by the substrate, where it can in principle be detected. Specifically, we report first-principles calculations describing a reaction between 2,4-dinitrotoluene (DNT) and atmospheric O(2) catalyzed by Fe-porphyrin at room temperature, incorporating an oxygen into the methyl group of DNT and releasing 1.9 eV per reaction. The atomic oxygen left on the Fe site can be removed by reacting with another DNT molecule, restoring the Fe catalyst.

Published
2013
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18. Revealing plasmonic gap modes in particle-on-film systems using dark-field spectroscopy.

Author

Lei DY, Fernández-Domínguez AI, Sonnefraud Y, Appavoo K, Haglund RF, Pendry JB, and Maier SA

Abstract

Polarization-controlled excitation of plasmonic modes in nanometric Au particle-on-film gaps is investigated experimentally using single-particle dark-field spectroscopy. Two distinct geometries are explored: nanospheres on top of and inserted in a thin gold film. Numerical simulations reveal that the three resonances arising in the scattering spectra measured for particles on top of a film originate from highly confined gap modes at the interface. These modes feature different azimuthal characteristics, which are consistent with recent theoretical transformation optics studies. On the other hand, the scattering maxima of embedded particles are linked to dipolar modes having different orientations and damping rates. Finally, the radiation properties of the particle-film gap modes are studied through the mapping of the scattered power within different solid angle ranges.

Published
2012
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19. Role of defects in the phase transition of VO2 nanoparticles probed by plasmon resonance spectroscopy.

Author

Appavoo K, Lei DY, Sonnefraud Y, Wang B, Pantelides ST, Maier SA, and Haglund RF Jr

Abstract

Defects are known to affect nanoscale phase transitions, but their specific role in the metal-to-insulator transition in VO(2) has remained elusive. By combining plasmon resonance nanospectroscopy with density functional calculations, we correlate decreased phase-transition energy with oxygen vacancies created by strain at grain boundaries. By measuring the degree of metallization in the lithographically defined VO(2) nanoparticles, we find that hysteresis width narrows with increasing size, thus illustrating the potential for domain boundary engineering in phase-changing nanostructures., (© 2012 American Chemical Society)

Published
2012
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20. Detecting nanoscale size dependence in VO2 phase transition using a split-ring resonator metamaterial.

Author

Appavoo K and Haglund RF

Abstract

We have measured the size dependence of a solid-solid phase transformation in discrete nanoscale volumes of vanadium dioxide (VO(2)) defined by split-ring resonators. By monitoring the in-coupling plasmonic mode while thermally cycling through the insulator-metal transition, we show that hysteresis width broadens with reduced interrogation volume (i.e., number of intrinsic nucleation sites). The results further imply a volume range over which both electronic and structural components of the switching exhibit similar size dependence.

Published
2011
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21. Plasmonic response of nanoscale spirals.

Author

Ziegler JI and Haglund RF Jr

Abstract

The Archimedean spiral geometry presents a platform for exploration of complex plasmonic mechanisms and applications. Here we show both through simulations and experiment that more complex plasmonic modes with unique near-field structure and larger mode volumes can be realized within a single, topologically robust structure. In the spiral, complex polarization response, resonant interactions and symmetry-breaking features are defined by the width and spacing of the spiral tracks and by the winding number of the spiral.

Published
2010
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22. Confocal Raman microscopy across the metal-insulator transition of single vanadium dioxide nanoparticles.

Author

Donev EU, Lopez R, Feldman LC, and Haglund RF

Abstract

We present the first Raman scattering measurements on nanoparticulate vanadium dioxide (VO(2)), as well as the first observations of the temperature-induced phase transition in individual VO(2) nanoparticles (NPs). We compare the Raman response of two VO(2) NPs and a companion VO(2) film undergoing their monoclinic-tetragonal-monoclinic transformations and offer qualitative explanations for the large observed differences in hysteresis width. While bulk crystals and contiguous films contain numerous nucleation sites, individual NPs likely harbor only a few, which may make it possible to correlate detectable defects (e.g., grain boundaries and dislocations) with the "ease" of switching phases, as quantified by the width of the thermal hysteresis.

Published
2009
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