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19 results on '"Raja, Arslan Sajid"'

1. Electrons herald non-classical light

Author

Arend, Germaine, Huang, Guanhao, Feist, Armin, Yang, Yujia, Henke, Jan-Wilke, Qiu, Zheru, Jeng, Hao, Raja, Arslan Sajid, Haindl, Rudolf, Wang, Rui Ning, Kippenberg, Tobias J., and Ropers, Claus

Subjects
Quantum Physics
Abstract

Free electrons are a widespread and universal source of electromagnetic fields. The past decades witnessed ever-growing control over many aspects of electron-generated radiation, from the incoherent emission produced by X-ray tubes to the exceptional brilliance of free-electron lasers. Reduced to the elementary process of quantized energy exchange between individual electrons and the electromagnetic field, electron beams may facilitate future sources of tunable quantum light. However, the quantum features of such radiation are tied to the correlation of the particles, calling for the joint electronic and photonic state to be explored for further applications. Here, we demonstrate the coherent parametric generation of non-classical states of light by free electrons. We show that the quantized electron energy loss heralds the number of photons generated in a dielectric waveguide. In Hanbury-Brown-Twiss measurements, an electron-heralded single-photon state is revealed via antibunching intensity correlations, while two-quantum energy losses of individual electrons yield pronounced two-photon coincidences. The approach facilitates the tailored preparation of higher-number Fock and other optical quantum states based on controlled interactions with free-electron beams.

Published
2024

2. Ultrafast optical circuit switching for data centers using integrated soliton microcombs

Author

Raja, Arslan Sajid, Lange, Sophie, Karpov, Maxim, Shi, Kai, Fu, Xin, Behrendt, Raphael, Cletheroe, Daniel, Lukashchuk, Anton, Haller, Istvan, Karinou, Fotini, Thomsen, Benn, Jozwik, Krzysztof, Liu, Junqiu, Costa, Paolo, Kippenberg, Tobias, and Ballani, Hitesh

Subjects
Physics - Applied Physics, Physics - Optics
Abstract

Networks inside current data centers comprise a hierarchy of power-hungry electronic packet switches interconnected via optical fibers and transceivers. As the scaling of such electrically-switched networks approaches a plateau, a power-efficient solution is to implement a flat network with optical circuit switching (OCS), without electronic switches and a reduced number of transceivers due to direct links among servers. One of the promising ways of implementing OCS is by using tunable lasers and arrayed waveguide grating routers. Such an OCS-network can offer high bandwidth and low network latency, and the possibility of photonic integration results in an energy-efficient, compact, and scalable photonic data center network. To support dynamic data center workloads efficiently, it is critical to switch between wavelengths in sub nanoseconds (ns). Here we demonstrate ultrafast photonic circuit switching based on a microcomb. Using a photonic integrated Si3N4 microcomb in conjunction with semiconductor optical amplifiers (SOAs), sub ns (< 500 ps) switching of more than 20 carriers is achieved. Moreover, the 25-Gbps non-return to zero (NRZ) and 50-Gbps four-level pulse amplitude modulation (PAM-4) burst mode transmission systems are shown. Further, on-chip Indium phosphide (InP) based SOAs and arrayed waveguide grating (AWG) are used to show sub-ns switching along with 25-Gbps NRZ burst mode transmission providing a path toward a more scalable and energy-efficient wavelength-switched network for future data centers., Comment: 11 pages, 6 figures

Published
2020
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3. Integrated photonics enables continuous-beam electron phase modulation

Author

Henke, Jan-Wilke, Raja, Arslan Sajid, Feist, Armin, Huang, Guanhao, Arend, Germaine, Yang, Yujia, and Kappert, F. Jasmin

Subjects
Photonics -- Influence, Electron beams -- Analysis, Phase modulation -- Methods, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Integrated photonics facilitates extensive control over fundamental light-matter interactions in manifold quantum systems including atoms.sup.1, trapped ions.sup.2,3, quantum dots.sup.4 and defect centres.sup.5. Ultrafast electron microscopy has recently made free-electron beams the subject of laser-based quantum manipulation and characterization.sup.6-11, enabling the observation of free-electron quantum walks.sup.12-14, attosecond electron pulses.sup.10,15-17 and holographic electromagnetic imaging.sup.18. Chip-based photonics.sup.19,20 promises unique applications in nanoscale quantum control and sensing but remains to be realized in electron microscopy. Here we merge integrated photonics with electron microscopy, demonstrating coherent phase modulation of a continuous electron beam using a silicon nitride microresonator. The high-finesse (Q.sub.0 [almost equal to] 10.sup.6) cavity enhancement and a waveguide designed for phase matching lead to efficient electron-light scattering at extremely low, continuous-wave optical powers. Specifically, we fully deplete the initial electron state at a cavity-coupled power of only 5.35 microwatts and generate >500 electron energy sidebands for several milliwatts. Moreover, we probe unidirectional intracavity fields with microelectronvolt resolution in electron-energy-gain spectroscopy.sup.21. The fibre-coupled photonic structures feature single-optical-mode electron-light interaction with full control over the input and output light. This approach establishes a versatile and highly efficient framework for enhanced electron beam control in the context of laser phase plates.sup.22, beam modulators and continuous-wave attosecond pulse trains.sup.23, resonantly enhanced spectroscopy.sup.24-26 and dielectric laser acceleration.sup.19,20,27. Our work introduces a universal platform for exploring free-electron quantum optics.sup.28-31, with potential future developments in strong coupling, local quantum probing and electron-photon entanglement. A silicon nitride microresonator is used for coherent phase modulation of a transmission electron microscope beam, with future applications in combining high-resolution microscopy with spectroscopy, holography and metrology., Author(s): Jan-Wilke Henke [sup.1] [sup.2] , Arslan Sajid Raja [sup.3] , Armin Feist [sup.1] [sup.2] , Guanhao Huang [sup.3] [sup.4] , Germaine Arend [sup.1] [sup.2] , Yujia Yang [sup.3] [sup.4] [...]

Published
2021
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5. Inducing Electron-Photon Correlations at an Integrated Photonics Microresonator

Author

Feist, Armin, primary, Huang, Guanhao, additional, Arend, Germaine, additional, Yang, Yujia, additional, Henke, Jan-Wilke, additional, Raja, Arslan Sajid, additional, Kappert, F. Jasmin, additional, Pan, Jiahe, additional, Lourenco-Martins, Hugo, additional, Qiu, Zheru, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2023
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6. Free-electron-heralded single-photon generation in high-Q microresonators

Author

Arend, Germaine, primary, Huang, Guanhao, additional, Feist, Armin, additional, Yang, Yujia, additional, Henke, Jan-Wilke, additional, Raja, Arslan Sajid, additional, Kappert, F. Jasmin, additional, Wang, Rui N., additional, Lourenço-Martins, Hugo, additional, Qiu, Zheru, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2023
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7. Photon Fock State Generation in Photonic Microresonators

Author

Arend, Germaine, primary, Feist, Armin, additional, Huang, Guanhao, additional, Yang, Yujia, additional, Henke, Jan-Wilke, additional, Raja, Arslan Sajid, additional, Kappert, F. Jasmin, additional, Pan, Jiahe, additional, Lourenco-Martins, Hugo, additional, Qiu, Zheru, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2023
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8. Cavity-mediated electron-photon pairs

Author

Feist, Armin, primary, Huang, Guanhao, additional, Arend, Germaine, additional, Yang, Yujia, additional, Henke, Jan-Wilke, additional, Raja, Arslan Sajid, additional, Kappert, F. Jasmin, additional, Wang, Rui Ning, additional, Lourenço-Martins, Hugo, additional, Qiu, Zheru, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2022
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10. Coupling free electrons and light at high-Q integrated photonics microresonators

Author

Henke, Jan-Wilke, primary, Raja, Arslan Sajid, additional, Feist, Armin, additional, Huang, Guanhao, additional, Arend, Germaine, additional, Yang, Yujia, additional, Kappert, Fee Jasmin, additional, Wang, Rui Ning, additional, Möller, Marcel, additional, Pan, Jiahe, additional, Lourenço-Martins, Hugo, additional, Qiu, Zheru, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2022
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11. Electron-photon correlations induced at a photonic integrated microresonator

Author

Feist, Armin, primary, Huang, Guanhao, additional, Arend, Germaine, additional, Yang, Yujia, additional, Henke, Jan-Wilke, additional, Raja, Arslan Sajid, additional, Kappert, F. Jasmin, additional, Wang, Rui Ning, additional, Lourenço-Martins, Hugo, additional, Liu, Junqiu, additional, Kfir, Ofer, additional, Kippenberg, Tobias J., additional, and Ropers, Claus, additional

Published
2022
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12. High-Q photonic chip-based temporal phase plates for electron microscopy

Author

Feist, Armin, primary, Raja, Arslan Sajid, additional, Henke, Jan-Wilke, additional, Liu, Junqiu, additional, Arend, Germaine, additional, Huang, Guanhao, additional, Kappert, Fee Jasmin, additional, Wang, Rui Ning, additional, Pan, Jiahe, additional, Kfir, Ofer, additional, Kippenberg, Tobias, additional, and Ropers, Claus, additional

Published
2021
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17. Generating optical pulses via a soliton state of an optical microresonator coupled with a chip based semiconductor laser

Author

Kippenberg, Tobias, Gorodetsky, Michael L, Raja, Arslan Sajid, and Guo, Hairun

Subjects
TTO:6.1902
Abstract

A light pulse source (100), being adapted for generating repetitive optical pulses (1), comprises a continuous wave cw laser device (10) being arranged for providing cw laser light (2), an optical waveguide (20) being optically coupled with the cw laser device (10),an optical microresonator (30) being made of a resonator material, which has a third order Kerr nonlinearity and an anomalous resonator dispersion, wherein the cw laser device (10) and the optical microresonator (30) are arranged on a common chip substrate device (40) for coupling the cw laser light (2) via the optical waveguide (20) into the optical microresonator (30), which, at a predetermined output frequency of the cw laser device (10), is capable of including a light field in a soliton state, so that soliton shaped pulses can be coupled out of the optical microresonator (30) for providing the repetitive optical pulses (1), and a tuning device (50) being arranged for adjusting the output frequency of the cw laser device (10), wherein the cw laser device (10) comprises a chip based semiconductor laser (11), at least one of the optical microresonator (30) and the optical waveguide (20) is adapted for reflecting an optical feedback portion (3) of light back to the semiconductor laser (11), which is capable of providing self injection locking relative to a resonance frequency of the optical microresonator (30) by the effect of the optical feedback portion (3), and the tuning device (50) is arranged for tuning at least one of a driving current and a temperature of the semiconductor laser (11) such that the optical microresonator (30) is capable of providing the soliton state. Furthermore, a light pulse generation method is described.

18. Linear and nonlinear applications of miniaturized silicon nitride microresonators

Author

Raja, Arslan Sajid and Kippenberg, Tobias

Subjects
transmission electron microscope, integrated photonics nonlinear photonics, self-injection locking, Photon-Induced Near-field Electron Microscopy, Photonics integration, datacenter, optical packaging, ultra-fast circuit switching, optical frequency comb, soliton microcomb
Abstract

Photonic integrated circuits (PICs) are the subject of massive interest due to the range of applications they can provide at a huge scale while building on well-established CMOS technologies. One of the critical parameters defining a technology's maturity level is its implementation in an operational environment. Optical frequency combs (microcombs) generated using on-chip microresonators have proved vital for multiple industrial and research applications. However, like many other technologies, microcombs based on PICs are restricted to a well-stabilized lab environment. The full photonic integration of soliton microcombs in a single, compact, and electrically-driven package would allow mass-manufacturable devices compatible with emerging high-volume applications such as laser-based ranging (LIDAR), or sources for dense wavelength division multiplexing for data center based optical interconnects. Another obstacle is establishing optical packaging protocol allowing the miniaturization and portability of this platform. The current thesis work aims at the miniaturization of the microcombs system based on ultra-low loss \ce{Si3N4} microresonator providing a path toward its applicability at a broader scale. Two approaches have been established for miniaturization based on application requirements. The first approach uses fast optical feedback originating from a \ce{Si3N4} microresonator known as "self-injection-locking." By directly coupling a multi-frequency laser diode to the \ce{Si3N4}, self-injection locking first leads to narrow linewidth single-mode lasing and subsequently enables the generation of the optical frequency comb. Moreover, the soliton state is initiated by changing the current simplifying conventional soliton generation mechanism and reducing the overall footprint to 1 cm$^3$. In the second approach, a more generic protocol of optical packaging is implemented, enabling the interfacing of \ce{Si3N4} based microcomb with standard fiber modules. The requirements of high input power and broadband coupling for frequency comb generation separate microresonator packaging from conventional packaging. Initially, packaging protocols are established, enabling device operation at high power ($>$ 2.5 W) and low temperature. The first application of a packaged soliton microcombs module demonstrates ultra-fast (nanoseconds timescale) circuit switching for the data center in collaboration with Microsoft Research (MSR), Cambridge. This study carried out at MSR Cambridge, shows the potential of a soliton microcomb as a multiwavelength source for future datacenter and the importance of optical packaging to enable the demonstration on a system level. Further validation of the generic optical packaging approach is done by interfacing a photonic integrated \ce{Si3N4} based microresonator inside a transmission electron microscope (TEM) to modulate the electron beam with the linear and nonlinear intracavity field. The introduction of integrated photonics, facilitated by optical packaging, has enabled highly efficient interactions in the continuous wave (CW) regime of the transmission electron microscope (TEM). Previously, achieving such efficiency was only possible using an advanced version of TEM known as ultrafast TEM (U-TEM), which has limited availability worldwide. Furthermore, the reliability of the packaging is confirmed through the successful generation of a soliton microcomb in the TEM.

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