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102 results on '"Awan, Kashif"'

1. Optically Probing Unconventional Superconductivity in Atomically Thin Bi$_2$Sr$_2$Ca$_{0.92}$Y$_{0.08}$Cu$_2$O$_{8+{\delta}}$

Author

Xiao, Yunhuan, Wu, Jingda, Dadap, Jerry I, Awan, Kashif Masud, Yang, Dongyang, Liang, Jing, Watanabe, Kenji, Taniguchi, Takashi, Zonno, Marta, Bluschke, Martin, Eisaki, Hiroshi, Greven, Martin, Damascelli, Andrea, and Ye, Ziliang

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Superconductivity
Abstract

Atomically thin cuprates exhibiting a superconducting phase transition temperature similar to bulk have recently been realized, although the device fabrication remains a challenge and limits the potential for many novel studies and applications. Here we use an optical pump-probe approach to noninvasively study the unconventional superconductivity in atomically thin Bi$_2$Sr$_2$Ca$_{0.92}$Y$_{0.08}$Cu$_2$O$_{8+{\delta}}$ (Y-Bi2212). Apart from finding an optical response due to the superconducting phase transition that is similar to bulk Y-Bi2212, we observe that the sign and amplitude of the pump-probe signal in the atomically thin flake vary significantly in different dielectric environments depending on the nature of the optical excitation. By exploiting the spatial resolution of the optical probe, we uncover the exceptional sensitivity of monolayer Y-Bi2212 to the environment. Our results provide the first optical evidence for the intralayer nature of the superconducting condensate in Bi2212, and highlight the role of double-sided encapsulation in preserving superconductivity in atomically thin cuprates., Comment: To be published in Nano Letters

Published
2024

2. Phase-matched third-harmonic generation in silicon nitride waveguides

Author

Vijayakumar Surendar, Vyas Kaustubh, Espinosa Daniel H. G., Reshef Orad, Song Meiting, Awan Kashif Masud, Choudhary Saumya, Cardenas Jaime, Boyd Robert W., and Dolgaleva Ksenia

Subjects
harmonic generation, waveguide, frequency conversion, silicon nitride, nonlinear optics, Physics, QC1-999
Abstract

Third-harmonic generation (THG) in silicon nitride waveguides is an ideal source of coherent visible light, suited for ultrafast pulse characterization, telecom signal monitoring and self-referenced comb generation due to its relatively large nonlinear susceptibility and CMOS compatibility. We demonstrate third-harmonic generation in silicon nitride waveguides where a fundamental transverse mode at 1,596 nm is phase-matched to a TM02 mode at 532 nm, confirmed by the far-field image. We experimentally measure the waveguide width-dependent phase-matched wavelength with a peak-power-normalized conversion efficiency of 5.78 × 10−7 %/W2 over a 660-μm-long interaction length.

Published
2024
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3. Spontaneous Polarization Induced Photovoltaic Effect In Rhombohedrally Stacked MoS$_2$

Author

Yang, Dongyang, Wu, Jingda, Zhou, Benjamin T., Liang, Jing, Ideue, Toshiya, Siu, Teri, Awan, Kashif Masud, Watanabe, Kenji, Taniguchi, Takashi, Iwasa, Yoshihiro, Franz, Marcel, and Ye, Ziliang

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Stacking order in van der Waals materials determines the coupling between atomic layers and is therefore key to the materials' properties. By exploring different stacking orders, many novel physical phenomena have been realized in artificial vdW stacks. Recently, 2D ferroelectricity has been observed in zero-degree aligned hBN and graphene-hBN heterostructures, holding promise in a range of electronic applications. In those artificial stacks, however, the single domain size is limited by the stacking-angle misalignment to about 0.1 to 1 $\mu$m, which is incompatible with most optical or optoelectronic applications. Here we show MoS$_2$ in the rhombohedral phase can host a homogeneous spontaneous polarization throughout few-$\mu$m-sized exfoliated flakes, as it is a natural crystal requiring no stacking and is, therefore free of misalignment. Utilizing this homogeneous polarization and its induced depolarization field (DEP), we build a graphene-MoS$_2$ based photovoltaic device with high efficiency. The few-layer MoS$_2$ is thinner than most oxide-based ferroelectric films, which allows us to maximize the DEP and study its impact at the atomically thin limit, while the highly uniform polarization achievable in the commensurate crystal enables a tangible path for up-scaling. The external quantum efficiency of our device is up to 16% at room temperature, over one order larger than the highest efficiency observed in bulk photovoltaic devices, owing to the reduced screening in graphene, the exciton-enhanced light-matter interaction, and the ultrafast interlayer relaxation in MoS$_2$. In view of the wide range of bandgap energy in other TMDs, our findings make rhombohedral TMDs a promising and versatile candidate for applications such as energy-efficient photo-detection with high speed and programmable polarity., Comment: 20 pages, 6 figures

Published
2022
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4. Geometry-dependent two-photon absorption followed by free-carrier absorption in AlGaAs waveguides

Author

Espinosa, Daniel H. G., Harrigan, Stephen R., Awan, Kashif M., Rasekh, Payman, and Dolgaleva, Ksenia

Subjects
Physics - Optics
Abstract

Nonlinear absorption can limit the efficiency of nonlinear optical devices. However, it can also be exploited for optical limiting or switching applications. Thus, characterization of nonlinear absorption in photonic devices is imperative. This work used the nonlinear transmittance technique to measure the two-photon absorption coefficients ($\alpha_2$) of AlGaAs waveguides in the strip-loaded, nanowire, and half-core geometries in the wavelength range from $1480$ to $1560~\text{nm}$. The highest $\alpha_2$ values of $2.4$, $2.3$, and $1.1~\text{cm}/\text{GW}$ were measured at $1480~\text{nm}$ for a $0.8$-nm-wide half-core, $0.6$-nm-wide nanowire, and $0.9$-nm-wide strip-loaded waveguides, respectively, with $\alpha_2$ decreasing with increasing wavelength. The free-carrier absorption cross-section was also estimated from the nonlinear transmittance data to be around $2.2\times10^{-16}~\text{cm}^2$ for all three geometries. Our results contribute to a better understanding of the nonlinear absorption in heterostructure waveguides of different cross-sectional geometries. We discuss how the electric field distribution in the different layers of a heterostructure can lead to geometry-dependent effective two-photon absorption coefficients. More specifically, we pinpoint the third-order nonlinear confinement factor as a design parameter to estimate the strength of the effective nonlinear absorption, in addition to tailoring the bandgap energy by varying material composition.

Published
2021
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5. Hyperpolarizability of plasmonic meta-atoms in metasurfaces

Author

Bin-Alam, M. Saad, Baxter, Joshua, Awan, Kashif M., Kiviniemi, Antti, Mamchur, Yaryna, Lesina, Antonio Cala', Tsakmakidis, Kosmas L., Huttunen, Mikko J., Ramunno, Lora, and Dolgaleva, Ksenia

Subjects
Physics - Optics
Abstract

Plasmonic metasurfaces are promising as enablers of nanoscale nonlinear optics and flat nonlinear optical components. Nonlinear optical responses of such metasurfaces are determined by the nonlinear optical properties of individual nanostructured plasmonic meta-atoms, which are the building blocks of the metasurfaces. Unfortunately, no simple methods exist to determine the nonlinear coefficients (hyperpolarizabilities) of the meta-atoms hindering designing of nonlinear metasurfaces. Here, we develop the equivalent RLC circuit model of such meta-atoms to estimate their second-order nonlinear optical parameter i.e. the first-order hyperpolarizability in the optical spectral range. In parallel, we extract from second-harmonic generation experiments the spectrum of the 1st-order hyperpolarizabilities of individual meta-atoms consisting of asymmetrically shaped (elongated) plasmonic nanoprisms. Moreover, we verify our results using nonlinear hydrodynamic-FDTD and with calculations based on nonlinear scattering theory. All three approaches: analytical, experimental, and computational, yield results that agree very well. Our empirical RLC model can thus be used as a simple tool to enable efficient design of nonlinear plasmonic metasurfaces.

Published
2020

6. Tunable Four-Wave Mixing in AlGaAs Waveguides of Three Different Geometries

Author

Espinosa, Daniel H. G., Awan, Kashif M., Odungide, Mfon, Harrigan, Stephen R., J., David R. Sanchez, and Dolgaleva, Ksenia

Subjects
Physics - Optics
Abstract

The AlGaAs material platform has been intensively used to develop nonlinear photonic devices on-a-chip, thanks to its superior nonlinear optical properties. We propose a new AlGaAs waveguide geometry, called half-core etched, which represents a compromise between two previously studied geometries, namely the nanowire and strip-loaded waveguides, combining their best qualities. We performed tunable four-wave mixing (FWM) experiments in all three of these geometries in the telecommunications C-band (wavelengths around 1550 nm), with a pulsed pump beam and a continuous-wave (CW) signal beam. The maximum FWM peak efficiencies achieved in the nanowire, strip-loaded and half-core geometries were about -5 dB, -8 dB and -9 dB, respectively. These values are among the highest reported in AlGaAs waveguides. The signal-to-idler conversion ranges were also remarkable: 161 nm for the strip-loaded and half-core waveguides and 152 nm for the nanowire. Based on our findings, we conclude that the half-core geometry is an alternative approach to the nanowire geometry, which has been earlier deemed the most efficient geometry, to perform wavelength conversion in the spectral region above the half-bandgap. Moreover, we show that the half-core geometry exhibits fewer issues associated with multiphoton absorption than the nanowire geometry.

Published
2020
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7. Demonstration of Optical Nonlinearity in InGaAsP/InP Passive Waveguides

Author

Saeidi, Shayan, Rasekh, Payman, Awan, Kashif M., Tüğen, Alperen, Huttunen, Mikko J., and Dolgaleva, Ksenia

Subjects
Physics - Optics
Abstract

We report on the study of the third-order nonlinear optical interactions in In$_{x}$Ga$_{1-x}$As$_{y}$P$_{1-y}$/InP strip-loaded waveguides. The material composition and waveguide structures were optimized for enhanced nonlinear optical interactions. We performed self-phase modulation, four-wave mixing and nonlinear absorption measurements at the pump wavelength 1568 nm in our waveguides. The nonlinear phase shift of up to $2.5\pi$ has been observed in self-phase modulation experiments. The measured value of the two-photon absorption coefficient $\alpha_2$ was 15 cm/GW. The four-wave mixing conversion range, representing the wavelength difference between maximally separated signal and idler spectral components, was observed to be 45 nm. Our results indicate that InGaAsP has a high potential as a material platform for nonlinear photonic devices, provided that the operation wavelength range outside the two-photon absorption window is selected.

Published
2018
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8. Enhanced spectral sensitivity of a chip-scale photonic-crystal slow-light interferometer

Author

Magaña-Loaiza, Omar S., Gao, Boshen, Schulz, Sebastian A., Awan, Kashif, Upham, Jeremy, Dolgaleva, Ksenia, and Boyd, Robert W.

Subjects
Physics - Optics
Abstract

We experimentally demonstrate that the spectral sensitivity of a Mach-Zehnder (MZ) interferometer can be enhanced through structural slow light. We observe a 20 times enhancement by placing a dispersion-engineered-slow-light photonic-crystal waveguide in one arm of a fibre-based MZ interferometer. The spectral sensitivity of the interferometer increases roughly linearly with the group index, and we have quantified the resolution in terms of the spectral density of interference fringes. These results show promise for the use of slow-light methods for developing novel tools for optical metrology and, specifically, for compact high-resolution spectrometers.

Published
2016
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13. Spectroscopic Signatures of Plasmonic Near‐Fields on High‐Harmonic Emission.

Author

Jalil, Sohail A., Awan, Kashif M., Baxter, Joshua, Bart, Graeme, Purschke, David N., Fennel, Thomas, Villeneuve, David M., Staudte, André, Berini, Pierre, Brabec, Thomas, Ramunno, Lora, and Vampa, Giulio

Subjects
*ATTOSECOND pulses, *NANOSCIENCE, *ELECTRON emission, *PLASMONICS, *BULK solids, *GAS wells
Abstract

Intense laser fields can reveal the attosecond and femtosecond response of matter in the emitted photoelectrons and high‐harmonic photons. The complementary perspective offered by these two messengers is well explored in gas molecules and, more recently, in bulk solids, where both electron emission and high‐order harmonics have been utilized to probe the laser‐matter interaction. In nanoscale solids, electron emission provides a wealth of information about the localized and inhomogeneous near fields around the nanoparticles. Here, it is shown experimentally that inhomogeneous fields also affect high‐order harmonics. Specifically, the experiment reveals strong indications that the field gradient of a nanoscale plasmonic hotspot found inside a Si crystal induces the emission of even‐order high harmonics from the crystal itself. This demonstration extends the complementary electron‐photon perspective on attosecond science to nanoscale systems. [ABSTRACT FROM AUTHOR]

Published
2023
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16. Controlling the polarization and phase of high-order harmonics with a plasmonic metasurface

Author

Jalil, Sohail A., primary, Awan, Kashif M., additional, Ali, Idriss A., additional, Rashid, Sabaa, additional, Baxter, Joshua, additional, Korobenko, Aleksey, additional, Ernotte, Guilmot, additional, Naumov, Andrei, additional, Villeneuve, David M., additional, Staudte, André, additional, Berini, Pierre, additional, Ramunno, Lora, additional, and Vampa, Giulio, additional

Published
2022
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20. A perspective on silicon photonic quantum computing with spin qubits

Author

Pfenning, Andreas, primary, Yan, Xiruo, additional, Gitt, Sebastian, additional, Fabian, Joshua, additional, Lin, Becky, additional, Witt, Donald, additional, Afifi, Abdelrahman, additional, Azem, Adan, additional, Darcie, Adam, additional, Wu, Jingda, additional, Mitchell, Matthew, additional, Awan, Kashif, additional, Chrostowski, Lukas, additional, and Young, Jeff F., additional

Published
2022
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25. Silicon photonic quantum computing with spin qubits

Author

Yan, Xiruo, primary, Gitt, Sebastian, additional, Lin, Becky, additional, Witt, Donald, additional, Abdolahi, Mahssa, additional, Afifi, Abdelrahman, additional, Azem, Adan, additional, Darcie, Adam, additional, Wu, Jingda, additional, Awan, Kashif, additional, Mitchell, Matthew, additional, Pfenning, Andreas, additional, Chrostowski, Lukas, additional, and Young, Jeff F., additional

Published
2021
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26. Spontaneous-polarization-induced photovoltaic effect in rhombohedrally stacked MoS2.

Author

Yang, Dongyang, Wu, Jingda, Zhou, Benjamin T., Liang, Jing, Ideue, Toshiya, Siu, Teri, Awan, Kashif Masud, Watanabe, Kenji, Taniguchi, Takashi, Iwasa, Yoshihiro, Franz, Marcel, and Ye, Ziliang

Abstract

Stacking order in van der Waals materials determines the coupling between atomic layers and is therefore the key to materials' properties. Recently, ferroelectricity, a phenomenon exhibiting reversible spontaneous electrical polarization, has been observed in zero-degree aligned van der Waals structures. In these artificial stacks, the single-domain size is limited by angle misalignment. Here we show that naturally rhombohedrally stacked MoS2 can host a homogeneous spontaneous polarization throughout the exfoliated flakes, free of misalignment. Utilizing this homogeneous polarization and its induced depolarization field, we build a graphene–MoS2-based photovoltaic device with high efficiency. Few-layer MoS2 is thinner than most oxide-based ferroelectric films, which allows us to maximize the depolarization field and study its impact at the atomically thin limit, whereas the highly uniform polarization in the commensurate crystal enables a tangible path for upscaling. The external quantum efficiency of our device is up to 16% at room temperature, over one order larger than the highest efficiency observed in bulk photovoltaic devices, owing to the reduced screening in graphene, exciton-enhanced light–matter interaction and ultrafast interlayer relaxation. Our findings make rhombohedral transition metal dichalcogenides a promising candidate for applications such as energy-efficient photodetection with high speed and programmable polarity. It is shown that rhombohedral stacked MoS2 can enable scalable photovoltaic effects induced by spontaneous polarization throughout few-micrometre-sized exfoliated flakes. This is exploited in a graphene–MoS2-based photovoltaic device. [ABSTRACT FROM AUTHOR]

Published
2022
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27. SiEPICfab: the Canadian silicon photonics rapid-prototyping foundry for integrated optics and quantum computing

Author

Darcie, Adam, primary, Mitchell, Matthew, additional, Awan, Kashif M., additional, Abdolahi, Mahssa, additional, Hammood, Mustafa, additional, Pfenning, Andreas, additional, Yan, Xiruo, additional, Afifi, Abdelrahman, additional, Witt, Donald, additional, Lin, Becky, additional, Gou, Steven, additional, Jhoja, Jaspreet, additional, Wu, Jingda, additional, Taghavi, Iman, additional, Weekes, David, additional, Jaeger, Nicolas A., additional, Young, Jeff, additional, and Chrostowski, Lukas, additional

Published
2021
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28. A silicon photonic evanescent-field sensor architecture using a fixed-wavelength laser

Author

Chrostowski, Lukas, primary, Leanne, Dias, additional, Matthew, Mitchell, additional, Connor, Mosquera, additional, Luan, Enxiao, additional, Al-Qadasi, Mohammed, additional, Avineet, Randhawa, additional, Mojaver, Hassan R., additional, Lyall, Eric, additional, Gervais, Antoine, additional, Dubé-Demers, Raphaël, additional, Awan, Kashif M., additional, Gou, Steven, additional, Liboiron-Ladouceur, Odile, additional, Shi, Wei, additional, Shekhar, Sudip, additional, and Cheung, Karen, additional

Published
2021
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29. Microscopic nonlinear optical characteristics of plasmonic meta-atoms

Author

Bin-Alam, M. Saad, primary, Baxter, Joshua, additional, Awan, Kashif M., additional, Kiviniemi, Antti, additional, Mamchur, Yaryna, additional, Calà Lesina, Antonino, additional, Tsakmakidis, Kosmas L., additional, Huttunen, Mikko J., additional, Ramunno, Lora, additional, and Dolgaleva, Ksenia, additional

Published
2021
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30. Hyperpolarizability of Plasmonic Meta-Atoms in Metasurfaces

Author

Bin-Alam, M. Saad, primary, Baxter, Joshua, additional, Awan, Kashif M., additional, Kiviniemi, Antti, additional, Mamchur, Yaryna, additional, Lesina, Antonio Calà, additional, Tsakmakidis, Kosmas L., additional, Huttunen, Mikko J., additional, Ramunno, Lora, additional, and Dolgaleva, Ksenia, additional

Published
2020
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38. Broadband and High‐Sensitivity Time‐Resolved THz System Using Grating‐Assisted Tilted‐Pulse‐Front Phase Matching.

Author

Cui, Wei, Awan, Kashif Masud, Huber, Rupert, Dolgaleva, Ksenia, and Ménard, Jean‐Michel

Subjects
*DYNAMICAL systems, *CRYSTALS
Abstract

A broadband and sensitive time‐resolved terahertz (THz) configuration relying on noncollinear optical interactions is presented. This noncollinear scheme enables a higher THz generation and detection efficiency in nonlinear crystals. The concept relies on a pair of thick (2 mm) GaP crystals with a phase grating etched on their surface to achieve phase matching between a diffracted near‐infrared pulse and a THz wave propagating at normal incidence. This system is compared to a standard collinear scheme based on thin (0.2 mm) crystals and, while both systems provide access to a spectral bandwidth extending up to 6.5 THz, it is found that the noncollinear configuration improves the THz signal by more than a factor of 400 and the dynamic range of the system by 30 dB at a frequency of 3 THz. [ABSTRACT FROM AUTHOR]

Published
2022
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39. Fabrication of III-V Integrated Photonic Devices

Author

Awan, Kashif

Subjects
Condensed Matter::Materials Science, Nonlinear optics, Semiconductor devices, Integrated photonics, Nanophotonics, III-V materials, Physics::Optics, Nanofabrication
Abstract

This doctoral dissertation focuses on fabrication processes for integrated photonic devices based on III-V semiconductors. This work covers a range of III-V materials and a variety of devices. Initially, design, fabrication and optical characterization of aluminum gallium arsenide (AlGaAs) waveguides for enhanced optical nonlinear interactions was carried out. Based on our results, we proposed a new type of waveguide for AlGaAs integrated nonlinear optics. Photonic crystal nanocavities and waveguides are attractive components for integrated photonic devices, due to their control over spatial, spectral and dispersion properties of light. Fabrication process for high-Q GaAs photonic crystal nanocavities was developed. Design, fabrication and optical characterization of strip-loaded indium gallium arsenide phosphide (InGaAsP) waveguides were then carried out to demonstrate the potential of Quaternary III-V semiconductors for integrated nonlinear optics. Self-phase modulation and four-wave mixing were demonstrated in InGaAsP waveguides and nonlinear absorption was determined experimentally. Gallium nitride (GaN), due to its wide band-gap, has plethora of photonics and optoelectronics applications. First demonstration of GaN waveguides grown on (-201) b-Ga2O3 (gallium oxide) was carried out leading to an experimentally determined propagation loss of 7.5 dB/cm. In summary, this doctoral work presents repeatable and reliable micro and nanofabrication processes for III-V integrated photonic devices.

Published
2018
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40. Weak superradiance in arrays of plasmonic nanoantennas

Author

Choudhary, Saumya, primary, De Leon, Israel, additional, Swiecicki, Sylvia, additional, Awan, Kashif Masud, additional, Schulz, Sebastian A., additional, Upham, Jeremy, additional, Alam, M. Zahirul, additional, Sipe, J. E., additional, and Boyd, Robert W., additional

Published
2019
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