Your search keyword '"Ding, Yunhong"' showing total 744 results

1. BISAP: A student academic performance prediction model based on the fusion of classroom behavior images and educational information

Author

Feng, Caihong, Liu, Jingyu, Wang, Jianhua, Ding, Yunhong, and Ji, Weidong

Published

2024

2. Temporal Multiplexing of Heralded Photons Based on Thin Film Lithium Niobate Photonics

Author

Ekici, Cagin, Yu, Yonghe, Adcock, Jeremy C., Muthali, Alif Laila, Zahidy, Mujtaba, Tan, Heyun, Lin, Zhongjin, Li, Hao, Oxenløwe, Leif K., Cai, Xinlun, and Ding, Yunhong

Subjects

Quantum Physics

Abstract

Heralded photons from a silicon source are temporally multiplexed utilizing thin film lithium niobate photonics. The time-multiplexed source, operating at a rate of R = 62.2 MHz, enhances single photon probability by 3.25 $\pm$ 0.05.

Published

2023

3. Efficient and robust second-harmonic generation in thin-film lithium niobate using modal phase matching

Author

Hansen, Mikkel T., Ulsig, Emil Z., Labbe, Fabien, Madsen, Magnus L., Ding, Yunhong, Rottwitt, Karsten, and Volet, Nicolas

Subjects

Physics - Optics

Abstract

A double-ridge waveguide is designed for efficient and robust second-harmonic generation (SHG) using the thin-film lithium-niobate-on-insulator (LNOI) platform. Perfect phase matching (PhM) is achieved between the fundamental waveguide mode at 1550 nm and a higher-order mode at the second harmonic. The fabrication tolerances of the PhM condition are simulated using a finite-difference method mode solver, and conversion efficiencies as high as 3.92/W are obtained for a 1-cm long waveguide. This design allows access to the largest element of the second-order nonlinear susceptibility tensor, and represents a scalable alternative to waveguides based on periodically-poled lithium niobate (PPLN). The design has the potential for generating pairs of entangled photons in the infrared C-band by spontaneous parametric down-conversion (SPDC).

Published

2023

4. Addressing Data Scarcity in Optical Matrix Multiplier Modeling Using Transfer Learning

Author

Cem, Ali, Jovanovic, Ognjen, Yan, Siqi, Ding, Yunhong, Zibar, Darko, and Da Ros, Francesco

Subjects

Computer Science - Machine Learning, Physics - Optics

Abstract

We present and experimentally evaluate using transfer learning to address experimental data scarcity when training neural network (NN) models for Mach-Zehnder interferometer mesh-based optical matrix multipliers. Our approach involves pre-training the model using synthetic data generated from a less accurate analytical model and fine-tuning with experimental data. Our investigation demonstrates that this method yields significant reductions in modeling errors compared to using an analytical model, or a standalone NN model when training data is limited. Utilizing regularization techniques and ensemble averaging, we achieve < 1 dB root-mean-square error on the matrix weights implemented by a 3x3 photonic chip while using only 25% of the available data.

Published

2023

5. High Resolution On-Chip Thin-Film Lithium Niobate Single-Photon Buffer

Author

Ekici, Cagin, Yu, Yonghe, Adcock, Jeremy C., Muthali, Alif Laila, Tan, Heyun, Li, Hao, Oxenløwe, Leif Katsuo, Cai, Xinlun, and Ding, Yunhong

Subjects

Quantum Physics, Physics - Applied Physics

Abstract

We experimentally demonstrate a room-temperature, voltage controlled, short-term quantum photonics memory on a lithium niobate chip. Our chip is capable of resolving 100 ps time steps with 0.74 dB loss per round-trip.

Published

2023

6. Loss-induced high-density multi-mode integrated waveguides array

Author

Wei, Yanxian, Zhou, Hailong, Ding, Yunhong, Cheng, Zihao, Huang, Dongmei, Wai, P. K. A., Dong, Jianji, and Zhang, Xinliang

Subjects

Physics - Optics

Abstract

The integration density of photonic integrated circuits has been limited by light coupling between waveguides. Traditional approaches to layout the waveguide with high density are based on refractive index engineering to suppress the light coupling between waveguides. However, these methods mostly require sophisticated and sensitive structure design, thus lack universality. Herein, we propose high-density multi-mode-multi-core integrated photonic waveguides by inserting high-loss metal strips between waveguides. We have achieved a 10-spatial-channel multi-mode-multi-core waveguide with total occupying spacing of 6.6 um. The multi-mode waveguides have a close spacing of 400 nm. The proposed scheme has high fabrication tolerance, ultra-large bandwidth and good compatibility to the complementary metal-oxide-semiconductor technology. It can be applied to any integration platform, any working waveband and any operating mode, providing a universal solution for high-density photonic circuits.

Published

2022

7. Data-efficient Modeling of Optical Matrix Multipliers Using Transfer Learning

Author

Cem, Ali, Jovanovic, Ognjen, Yan, Siqi, Ding, Yunhong, Zibar, Darko, and Da Ros, Francesco

Subjects

Computer Science - Machine Learning, Computer Science - Emerging Technologies, Computer Science - Neural and Evolutionary Computing

Abstract

We demonstrate transfer learning-assisted neural network models for optical matrix multipliers with scarce measurement data. Our approach uses <10\% of experimental data needed for best performance and outperforms analytical models for a Mach-Zehnder interferometer mesh., Comment: 2 pages, 2 figues, submitted to CLEO

Published

2022

8. Data-driven Modeling of Mach-Zehnder Interferometer-based Optical Matrix Multipliers

Author

Cem, Ali, Yan, Siqi, Ding, Yunhong, Zibar, Darko, and Da Ros, Francesco

Subjects

Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing, Physics - Optics

Abstract

Photonic integrated circuits are facilitating the development of optical neural networks, which have the potential to be both faster and more energy efficient than their electronic counterparts since optical signals are especially well-suited for implementing matrix multiplications. However, accurate programming of photonic chips for optical matrix multiplication remains a difficult challenge. Here, we describe both simple analytical models and data-driven models for offline training of optical matrix multipliers. We train and evaluate the models using experimental data obtained from a fabricated chip featuring a Mach-Zehnder interferometer mesh implementing 3-by-3 matrix multiplication. The neural network-based models outperform the simple physics-based models in terms of prediction error. Furthermore, the neural network models are also able to predict the spectral variations in the matrix weights for up to 100 frequency channels covering the C-band. The use of neural network models for programming the chip for optical matrix multiplication yields increased performance on multiple machine learning tasks., Comment: 12 pages, 17 figures, submitted to Jorunal of Lightwave Technology

Published

2022

9. Enhancement of a silicon waveguide single photon source by temporal multiplexing

Author

Adcock, Jeremy C., Bacco, Davide, and Ding, Yunhong

Subjects

Quantum Physics, Physics - Optics

Abstract

Efficient generation of single photons is one of the key challenges of building photonic quantum technology, such as quantum computers and long-distance quantum networks. Photon source multiplexing -- where successful pair generation is heralded by the detection of one of the photons, and its partner is routed to a single mode output -- has long been known to offer a concrete solution, with output probability tending toward unity as loss is reduced. Here, we present a temporally multiplexed integrated single photon source based on a silicon waveguide and a low-loss fibre switch and loop architecture, which achieves enhancement of the single photon output probability of $4.5 \pm 0.5$, while retaining $g^{(2)}(0) = 0.01$.

Published

2022

10. Advances in silicon quantum photonics

Author

Adcock, Jeremy C., Bao, Jueming, Chi, Yulin, Chen, Xiaojiong, Bacco, Davide, Gong, Qihuang, Oxenløwe, Leif K., Wang, Jianwei, and Ding, Yunhong

Subjects

Quantum Physics, Physics - Optics

Abstract

Quantum technology is poised to enable a step change in human capability for computing, communications and sensing. Photons are indispensable as carriers of quantum information - they travel at the fastest possible speed and readily protected from decoherence. However, the system requires thousands of near-transparent components with ultra-low-latency control. For quantum technology to be implemented, a new paradigm photonic system is required: one with in-built coherence, stability, the ability to define arbitrary circuits, and a path to manufacturability. Silicon photonics has unparalleled density and component performance, which, with CMOS compatible fabrication, place it in a strong position for a scalable quantum photonics platform. This paper is a progress report on silicon quantum photonics, focused on developments in the past five years. We provide an introduction on silicon quantum photonic component and the challenges in the field, summarise the current state-of-the-art and identify outstanding technical challenges, as well as promising avenues of future research. We also resolve a conflict in the definition of Hong-Ou-Mandel interference visibility in integrated quantum photonic experiments, needed for fair comparison of photon quality across different platforms. Our aim is the development of scalability on the platform, to which end we point the way to ever-closer integration, toward silicon quantum photonic systems-on-a-chip.

Published

2022

11. Comparison of Models for Training Optical Matrix Multipliers in Neuromorphic PICs

Author

Cem, Ali, Yan, Siqi, de Moura, Uiara Celine, Ding, Yunhong, Zibar, Darko, and Da Ros, Francesco

Subjects

Computer Science - Machine Learning, Computer Science - Neural and Evolutionary Computing

Abstract

We experimentally compare simple physics-based vs. data-driven neural-network-based models for offline training of programmable photonic chips using Mach-Zehnder interferometer meshes. The neural-network model outperforms physics-based models for a chip with thermal crosstalk, yielding increased testing accuracy., Comment: 3 pages, 3 figures

Published

2021

12. Quantum randomness generation via orbital angular momentum modes crosstalk in a ring-core fiber

Author

Zahidy, Mujtaba, Tebyanian, Hamid, Cozzolino, Daniele, Liu, Yaoxin, Ding, Yunhong, Morioka, Toshio, Oxenløwe, Leif K., and Bacco, Davide

Subjects

Quantum Physics

Abstract

Genuine random numbers can be produced beyond a shadow of doubt through the intrinsic randomness provided by quantum mechanics theory. While many degrees of freedom have been investigated for randomness generation, not adequate attention has been paid to the orbital angular momentum of light. In this work, we present a quantum random number generator based on the intrinsic randomness inherited from the superposition of orbital angular momentum modes caused by the crosstalk inside a ring-core fiber. We studied two possible cases: a first one, device-dependent, where the system is trusted, and a second one, semi-device-independent, where the adversary can control the measurements. We experimentally realized the former, extracted randomness, and, after privacy amplification, we achieved a generation rate higher than 10 Mbit/s. In addition, we presented a possible realization of the semi-device-independent protocol, using a newly introduced integrated silicon photonic chip. Our work can be considered as a starting point for novel investigations of quantum random number generators based on the orbital angular momentum of light., Comment: 5 pages, 6 figures

Published

2021

13. Chiral polarizer based on encircling EP

Author

Wei, Yanxian, Zhou, Hailong, Chen, Yuntian, Ding, Yunhong, Dong, Jianji, and Zhang, Xinliang

Subjects

Physics - Optics

Abstract

Encircling an exceptional point (EP) in a parity-time (PT) symmetric system has shown great potential for chiral optical devices, such as chiral mode switching for symmetric and anti-symmetric modes. However, the chiral switching for polarization states has never been reported although chiral polarization manipulation has significant applications in imaging, sensing, and communication etc. Here inspired by the anti-PT symmetry, we demonstrate an on-chip chiral polarizer by constructing polarization-coupled anti-PT symmetric system for the first time. The transmission axes of the chiral polarizer are different for forward and backward propagation. A polarization extinction ratio of over 10 dB is achieved for both propagating directions. Moreover, a telecommunication experiment is performed to demonstrate the potential applications in polarization encoding signals. It provides a novel functionality for encircling-an-EP parametric evolution and offer a new approach for on-chip chiral polarization manipulation.

Published

2021

14. Photonic integrated chip enabling orbital angular momentum multiplexing for quantum communication

Author

Zahidy, Mujtaba, Liu, Yaoxin, Cozzolino, Daniele, Ding, Yunhong, Morioka, Toshio, Oxenløwe, Leif K., and Bacco, Davide

Subjects

Quantum Physics

Abstract

Light carrying orbital angular momentum constitutes an important resource for both classical and quantum information technologies. Its inherently unbounded nature can be exploited to generate high-dimensional quantum states or for channel multiplexing in classical and quantum communication in order to significantly boost the data capacity and the secret key rate, respectively. While the big potentials of light owning orbital angular momentum have been widely ascertained, its technological deployment is still limited by the difficulties deriving from the fabrication of integrated and scalable photonic devices able to generate and manipulate it. Here, we present a photonic integrated chip able to excite orbital angular momentum modes in an 800 m long ring-core fiber, allowing us to perform parallel quantum key distribution using 2 and 3 different modes simultaneously. The experiment sets the first steps towards quantum orbital angular momentum division multiplexing enabled by a compact and light-weight silicon chip, and further pushes the development of integrated scalable devices supporting orbital angular momentum modes., Comment: 5 pages main text, 5 figures

Published

2021

15. Path-encoded high-dimensional quantum communication over a 2 km multicore fiber

Author

Da Lio, Beatrice, Cozzolino, Daniele, Biagi, Nicola, Ding, Yunhong, Rottwitt, Karsten, Zavatta, Alessandro, Bacco, Davide, and Oxenløwe, Leif K.

Subjects

Quantum Physics

Abstract

Quantum key distribution (QKD) protocols based on high-dimensional quantum states have shown the route to increase the key rate generation while benefiting of enhanced error tolerance, thus overcoming the limitations of two-dimensional QKD protocols. Nonetheless, the reliable transmission through fiber links of high-dimensional quantum states remains an open challenge that must be addressed to boost their application. Here, we demonstrate the reliable transmission over a 2 km long multicore fiber of path-encoded high-dimensional quantum states. Leveraging on a phase-locked loop system, a stable interferometric detection is guaranteed, allowing for low error rates and the generation of 6.3 Mbit/s of secret key rate., Comment: to appear in npj Quantum Information

Published

2021

16. Very-large-scale integrated quantum graph photonics

Author

Bao, Jueming, Fu, Zhaorong, Pramanik, Tanumoy, Mao, Jun, Chi, Yulin, Cao, Yingkang, Zhai, Chonghao, Mao, Yifei, Dai, Tianxiang, Chen, Xiaojiong, Jia, Xinyu, Zhao, Leshi, Zheng, Yun, Tang, Bo, Li, Zhihua, Luo, Jun, Wang, Wenwu, Yang, Yan, Peng, Yingying, Liu, Dajian, Dai, Daoxin, He, Qiongyi, Muthali, Alif Laila, Oxenløwe, Leif K., Vigliar, Caterina, Paesani, Stefano, Hou, Huili, Santagati, Raffaele, Silverstone, Joshua W., Laing, Anthony, Thompson, Mark G., O’Brien, Jeremy L., Ding, Yunhong, Gong, Qihuang, and Wang, Jianwei

Published

2023

17. Error protected qubits in a silicon photonic chip

Author

Vigliar, Caterina, Paesani, Stefano, Ding, Yunhong, Adcock, Jeremy C., Wang, Jianwei, Morley-Short, Sam, Bacco, Davide, Oxenløwe, Leif K., Thompson, Mark G., Rarity, John G., and Laing, Anthony

Subjects

Quantum Physics, Physics - Optics

Abstract

General purpose quantum computers can, in principle, entangle a number of noisy physical qubits to realise composite qubits protected against errors. Architectures for measurement-based quantum computing intrinsically support error-protected qubits and are the most viable approach for constructing an all-photonic quantum computer. Here we propose and demonstrate an integrated silicon photonic architecture that both entangles multiple photons, and encodes multiple physical qubits on individual photons, to produce error-protected qubits. We realise reconfigurable graph states to compare several schemes with and without error-correction encodings and implement a range of quantum information processing tasks. We observe a success rate increase from 62.5% to 95.8% when running a phase estimation algorithm without and with error protection, respectively. Finally, we realise hypergraph states, which are a generalised class of resource states that offer protection against correlated errors. Our results show how quantum error-correction encodings can be implemented with resource-efficient photonic architectures to improve the performance of quantum algorithms.

Published

2020

18. Multimode silicon photonics using on-chip geometrical-optics

Author

Sun, Chunlei, Ding, Yunhong, Li, Zhen, Qi, Wei, Yu, Yu, and Zhang, Xinliang

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

On-chip optical interconnect has been widely accepted as a promising technology to realize future large-scale multiprocessors. Mode-division multiplexing (MDM) provides a new degree of freedom for optical interconnects to dramatically increase the link capacity. Present on-chip multimode devices are based on traditional wave-optics. Although large amount of computation and optimization are adopted to support more modes, mode-independent manipulation is still hard to be achieved due to severe mode dispersion. Here, we propose a universal solution to standardize the design of fundamental multimode building blocks, by introducing a geometrical-optics-like concept adopting waveguide width larger than the working wavelength. The proposed solution can tackle a group of modes at the same time with very simple processes, avoiding demultiplexing procedure and ensuring compact footprint. Compare to conventional schemes, it is scalable to larger mode channels without increasing the complexity and whole footprint. As a proof of concept, we demonstrate a set of multimode building blocks including crossing, bend, coupler and switches. Low losses of multimode waveguide crossing and bend are achieved, as well as ultra-low power consumption of the multimode switch is realized since it enables reconfigurable routing for a group of modes simultaneously. Our work promotes the multimode photonics research and makes the MDM technique more practical.

Published

2020

19. Stable transmission of high-dimensional quantum states over a 2 km multicore fiber

Author

Da Lio, Beatrice, Bacco, Davide, Cozzolino, Daniele, Biagi, Nicola, Arge, Tummas Napoleon, Larsen, Emil, Rottwitt, Karsten, Ding, Yunhong, Zavatta, Alessandro, and Oxenløwe, Leif Katsuo

Subjects

Quantum Physics

Abstract

High-dimensional quantum states have already settled their advantages in different quantum technology applications. However, their reliable transmission in fiber links remains an open challenge that must be addressed to boost their application, e.g. in the future quantum internet. Here, we prove how path encoded high-dimensional quantum states can be reliably transmitted over a 2 km long multicore fiber, taking advantage of a phase-locked loop system guaranteeing a stable interferometric detection.

Published

2020

20. Chip-to-chip quantum teleportation and multi-photon entanglement in silicon

Author

Llewellyn, Daniel, Ding, Yunhong, Faruque, Imad I., Paesani, Stefano, Bacco, Davide, Santagati, Raffaele, Qian, Yan-Jun, Li, Yan, Xiao, Yun-Feng, Huber, Marcus, Malik, Mehul, Sinclair, Gary F., Zhou, Xiaoqi, Rottwitt, Karsten, Brien, Jeremy L. O, Rarity, John G., Gong, Qihuang, Oxenlowe, Leif K., Wang, Jianwei, and Thompson, Mark G.

Subjects

Quantum Physics

Abstract

Exploiting semiconductor fabrication techniques, natural carriers of quantum information such as atoms, electrons, and photons can be embedded in scalable integrated devices. Integrated optics provides a versatile platform for large-scale quantum information processing and transceiving with photons. Scaling up the integrated devices for quantum applications requires highperformance single-photon generation and photonic qubit-qubit entangling operations. However, previous demonstrations report major challenges in producing multiple bright, pure and identical single-photons, and entangling multiple photonic qubits with high fidelity. Another notable challenge is to noiselessly interface multiphoton sources and multiqubit operators in a single device. Here we demonstrate on-chip genuine multipartite entanglement and quantum teleportation in silicon, by coherently controlling an integrated network of microresonator nonlinear single-photon sources and linear-optic multiqubit entangling circuits. The microresonators are engineered to locally enhance the nonlinearity, producing multiple frequencyuncorrelated and indistinguishable single-photons, without requiring any spectral filtering. The multiqubit states are processed in a programmable linear circuit facilitating Bell-projection and fusion operation in a measurement-based manner. We benchmark key functionalities, such as intra-/inter-chip teleportation of quantum states, and generation of four-photon Greenberger-HorneZeilinger entangled states. The production, control, and transceiving of states are all achieved in micrometer-scale silicon chips, fabricated by complementary metal-oxide-semiconductor processes. Our work lays the groundwork for scalable on-chip multiphoton technologies for quantum computing and communication.

Published

2019

21. Boosting the secret key rate in a shared quantum and classical fibre communication system

Author

Bacco, Davide, Da Lio, Beatrice, Cozzolino, Daniele, Da Ros, Francesco, Guo, Xueshi, Ding, Yunhong, Sasaki, Yusuke, Aikawa, Kazuhiko, Miki, Shigehito, Terai, Hirotaka, Yamashita, Taro, Neergaard-Nielsen, Jonas S., Galili, Michael, Rottwitt, Karsten, Andersen, Ulrik L., Morioka, Toshio, and Oxenløwe, Leif K.

Subjects

Quantum Physics

Abstract

During the last 20 years, the advance of communication technologies has generated multiple exciting applications. However, classical cryptography, commonly adopted to secure current communication systems, can be jeopardized by the advent of quantum computers. Quantum key distribution (QKD) is a promising technology aiming to solve such a security problem. Unfortunately, current implementations of QKD systems show relatively low key rates, demand low channel noise and use ad hoc devices. In this work, we picture how to overcome the rate limitation by using a 37-core fibre to generate 2.86 Mbit/s per core that can be space multiplexed into the highest secret key rate of 105.7 Mbit/s to date. We also demonstrate, with off-the-shelf equipment, the robustness of the system by co-propagating a classical signal at 370 Gbit/s, paving the way for a shared quantum and classical communication network.

Published

2019

22. Energy-efficient integrated silicon optical phased array

Author

Qiu, Huaqing, Liu, Yong, Meng, Xiansong, Guan, Xiaowei, Ding, Yunhong, and Hu, Hao

Published

2023

23. Experimental demonstration of the DPTS QKD protocol over a 170 km fiber link

Author

Da Lio, Beatrice, Bacco, Davide, Cozzolino, Daniele, Ding, Yunhong, Dalgaard, Kjeld, Rottwitt, Karsten, and Oxenløwe, Leif

Subjects

Quantum Physics

Abstract

Quantum key distribution (QKD) is a promising technology aiming at solving the security problem arising from the advent of quantum computers. While the main theoretical aspects are well developed today, limited performances, in terms of achievable link distance and secret key rate, are preventing the deployment of this technology on a large scale. More recent QKD protocols, which use multiple degrees of freedom for the encoding of the quantum states, allow an enhancement of the system performances. Here, we present the experimental demonstration of the differential phase-time shifting protocol (DPTS) up to 170 km of fiber link. We compare its performance with the well-known coherent one-way (COW) and the differential phase shifting (DPS) protocols, demonstrating a higher secret key rate up to 100 km. Moreover, we propagate a classical signal in the same fiber, proving the compatibility of quantum and classical light., Comment: 5 pages, 3 figures, journal paper

Published

2019

24. Genome sequence assembly algorithms and misassembly identification methods

Author

Meng, Yue, Lei, Yu, Gao, Jianlong, Liu, Yuxuan, Ma, Enze, Ding, Yunhong, Bian, Yixin, Zu, Hongquan, Dong, Yucui, and Zhu, Xiao

Published

2022

25. Generation and sampling of quantum states of light in a silicon chip

Author

Paesani, Stefano, Ding, Yunhong, Santagati, Raffaele, Chakhmakhchyan, Levon, Vigliar, Caterina, Rottwitt, Karsten, Oxenløwe, Leif K., Wang, Jianwei, Thompson, Mark G., and Laing, Anthony

Subjects

Quantum Physics, Physics - Optics

Abstract

Implementing large instances of quantum algorithms requires the processing of many quantum information carriers in a hardware platform that supports the integration of different components. While established semiconductor fabrication processes can integrate many photonic components, the generation and algorithmic processing of many photons has been a bottleneck in integrated photonics. Here we report the on-chip generation and processing of quantum states of light with up to eight photons in quantum sampling algorithms. Switching between different optical pumping regimes, we implement the Scattershot, Gaussian and standard boson sampling protocols in the same silicon chip, which integrates linear and nonlinear photonic circuitry. We use these results to benchmark a quantum algorithm for calculating molecular vibronic spectra. Our techniques can be readily scaled for the on-chip implementation of specialised quantum algorithms with tens of photons, pointing the way to efficiency advantages over conventional computers.

Published

2018

26. Unidirectional frequency conversion in microring resonators for on-chip frequency-multiplexed single-photon sources

Author

Heuck, Mikkel, Koefoed, Jacob Gade, Christensen, Jesper Bjerge, Ding, Yunhong, Frandsen, Lars Hagedorn, Rottwitt, Karsten, and Oxenlowe, Leif Katsuo

Subjects

Quantum Physics

Abstract

Microring resonators are attractive for low-power frequency conversion via Bragg-scattering four-wave-mixing due to their comb-like resonance spectrum. However, conversion efficiency is limited to 50% due to the equal probability of up- and down-conversion. Here, we demonstrate how two coupled microrings enable highly directional conversion between the spectral modes of one of the rings. An extinction between up- and down-conversion of more than 40 dB is experimentally observed. Based on this method, we propose a design for on-chip multiplexed single-photon sources that allow localized frequency modes to be converted into propagating continuous-mode photon wave packets using a single operation. The key is that frequency conversion works as a switch on both spatial and spectral degrees of freedom of photons if the microring is interferometrically coupled to a bus waveguide. Our numerical results show 99% conversion efficiency into a propagating mode with a wave packet having a 90% overlap with a Gaussian for a ratio between intrinsic and coupling quality factors of 400.

Published

2018

27. Spatially controlled electrostatic doping in graphene p-i-n junction for hybrid silicon photodiode

Author

Li, Tiantian, Mao, Dun, Petrone, Nick, Grassi, Robert, Hu, Hao, Ding, Yunhong, Huang, Zhihong, Lo, Guo Qiang, Hone, James, Low, Tony, Wong, Chee Wei, and Gu, Tingyi

Subjects

Physics - Applied Physics, Physics - Optics

Abstract

Sufficiently large depletion region for photocarrier generation and separation is a key factor for two-dimensional material optoelectronic devices, but few device configurations has been explored for a deterministic control of a space charge region area in graphene with convincing scalability. Here we investigate a graphene-silicon p-i-n photodiode defined in a foundry processed planar photonic crystal waveguide structure, achieving visible - near-infrared, zero-bias and ultrafast photodetection. Graphene is electrically contacting to the wide intrinsic region of silicon and extended to the p an n doped region, functioning as the primary photocarrier conducting channel for electronic gain. Graphene significantly improves the device speed through ultrafast out-of-plane interfacial carrier transfer and the following in-plane built-in electric field assisted carrier collection. More than 50 dB converted signal-to-noise ratio at 40 GHz has been demonstrated under zero bias voltage, with quantum efficiency could be further amplified by hot carrier gain on graphene-i Si interface and avalanche process on graphene-doped Si interface. With the device architecture fully defined by nanomanufactured substrate, this study is the first demonstration of post-fabrication-free two-dimensional material active silicon photonic devices., Comment: NPJ 2D materials and applications (2018)

Published

2018

28. Ultra-compact graphene plasmonic photodetector with the bandwidth over 110GHz

Author

Ding, Yunhong, Cheng, Zhao, Zhu, Xiaolong, Yvind, Kresten, Dong, Jianji, Galili, Michael, Hu, Hao, Mortensen, N. Asger, Xiao, Sanshui, and Oxenløwe, Leif Katsuo

Subjects

Physics - Applied Physics, Physics - Optics

Abstract

Graphene-based photodetectors, taking advantage of high carrier mobility and broadband absorption in graphene, have recently experienced rapid development. However, their performances with respect to the responsivity and bandwidth are still limited by either weak light-graphene interaction or large resistance-capacitance product. Here, we demonstrate a waveguide coupled integrated graphene plasmonic photodetector on the silicon-on-insulator platform. Benefiting from plasmonic enhanced graphene-light interactions and subwavelength confinement of the optical energy, we present a small-footprint graphene-plasmonic photodetector with bandwidth beyond 110GHz and intrinsic responsivity of 360mA/W. Attributed to the unique electronic bandstructure of graphene and its ultra-broadband absorption, the operational wavelength range extending beyond mid-infrared, and possibly further, can be anticipated. Our results show that the combination of graphene with plasmonic devices has great potential to realize ultra-compact and high-speed optoelectronic devices for graphene-based optical interconnects., Comment: 6 pages, 4 figures, supplementary materials are available under request

Published

2018

29. Orbital angular momentum states enabling fiber-based high-dimensional quantum communication

Author

Cozzolino, Daniele, Bacco, Davide, Da Lio, Beatrice, Ingerslev, Kasper, Ding, Yunhong, Dalgaard, Kjeld, Kristensen, Poul, Galili, Michael, Rottwitt, Karsten, Ramachandran, Siddharth, and Oxenløwe, Leif Katsuo

Subjects

Quantum Physics

Abstract

Quantum networks are the ultimate target in quantum communication, where many connected users can share information carried by quantum systems. The keystones of such structures are the reliable generation, transmission and manipulation of quantum states. Two-dimensional quantum states, qubits, are steadily adopted as information units. However, high-dimensional quantum states, qudits, constitute a richer resource for future quantum networks, exceeding the limitations imposed by the ubiquitous qubits. The generation and manipulation of such $D$-level systems have been improved over the last ten years, but their reliable transmission between remote locations remains the main challenge. Here, we show how a recent air-core fiber supporting orbital angular momentum (OAM) modes can be exploited to faithfully transmit $D$-dimensional states. Four OAM quantum states and their superpositions are created, propagated in a 1.2 km long fiber and detected with high fidelities. In addition, three quantum key distribution (QKD) protocols are implemented as concrete applications to assert the practicality of our results. This experiment enhances the distribution of high-dimensional quantum states, attesting the orbital angular momentum as vessel for the future quantum network.

Published

2018

30. Multidimensional quantum entanglement with large-scale integrated optics

Author

Wang, Jianwei, Paesani, Stefano, Ding, Yunhong, Santagati, Raffaele, Skrzypczyk, Paul, Salavrakos, Alexia, Tura, Jordi, Augusiak, Remigiusz, Mančinska, Laura, Bacco, Davide, Bonneau, Damien, Silverstone, Joshua W., Gong, Qihuang, Acín, Antonio, Rottwitt, Karsten, Oxenløwe, Leif K., O'Brien, Jeremy L., Laing, Anthony, and Thompson, Mark G.

Subjects

Quantum Physics, Physics - Optics

Abstract

The ability to control multidimensional quantum systems is key for the investigation of fundamental science and for the development of advanced quantum technologies. Here we demonstrate a multidimensional integrated quantum photonic platform able to robustly generate, control and analyze high-dimensional entanglement. We realize a programmable bipartite entangled system with dimension up to $15 \times 15$ on a large-scale silicon-photonics quantum circuit. The device integrates more than 550 photonic components on a single chip, including 16 identical photon-pair sources. We verify the high precision, generality and controllability of our multidimensional technology, and further exploit these abilities to demonstrate key quantum applications experimentally unexplored before, such as quantum randomness expansion and self-testing on multidimensional states. Our work provides a prominent experimental platform for the development of multidimensional quantum technologies., Comment: Science, (2018)

Published

2018

31. Scalable temporal multiplexing of telecom photons via thin-film lithium niobate photonics.

Author

Ekici, Çağın, Yu, Yonghe, Adcock, Jeremy C., Muthali, Alif Laila, Zahidy, Mujtaba, Tan, Heyun, Lin, Zhongjin, Li, Hao, Oxenløwe, Leif K., Cai, Xinlun, and Ding, Yunhong

Subjects

QUANTUM theory, LITHIUM niobate, PHYSICAL sciences, DEGREES of freedom, PHOTONICS

Abstract

Efficient single-photon generation remains a big challenge in quantum photonics. A promising approach to overcome this challenge is to employ active multiplexing—repeating a nondeterministic photon pair generation process across orthogonal degrees of freedom and exploiting heralding to actively route the heralded photon to the desired single output mode via feedforward. The main barriers of multiplexing schemes, however, are minimizing resource requirements to allow scalability and the lack of availability of high-speed, low-loss switches. Here, we present an on-chip temporal multiplexing scheme utilizing thin-film lithium niobate (TFLN) photonics to effectively address these challenges. Our time-multiplexed source, operating at a rate of 62.2 MHz, enhances single-photon probability by a factor of 3.37 ± 0.05 without introducing additional multi-photon noise. This demonstration highlights the feasibility and potential of TFLN photonics for large-scale complex quantum information technologies. [ABSTRACT FROM AUTHOR]

Published

2025

32. Space division multiplexing chip-to-chip quantum key distribution

Author

Bacco, Davide, Ding, Yunhong, Dalgaard, Kjeld, Rottwit, Karsten, and Oxenløwe, Leif Katsuo

Subjects

Quantum Physics

Abstract

Quantum cryptography is set to become a key technology for future secure communications. However, to get maximum benefit in communication networks, transmission links will need to be shared among several quantum keys for several independent users. Such links will enable switching in quantum network nodes of the quantum keys to their respective destinations. In this paper we present an experimental demonstration of a photonic integrated silicon chip quantum key distribution protocols based on space division multiplexing (SDM), through multicore fiber technology. Parallel and independent quantum keys are obtained, which are useful in crypto-systems and future quantum network.

Published

2017

33. A 3D tortuous fracture network construction approach to analyze proppant distribution in post-fractured shale

Author

Xu, Jiaxiang, Gao, Rui, Yang, Lifeng, Liu, Zhe, Ding, Yunhong, Wang, Zhen, and Mo, Shaoyuan

Published

2022

34. Effective electro-optic modulation in low-loss graphene-plasmonic slot waveguides

Author

Ding, Yunhong, Guan, Xiaowei, Zhu, Xiaolong, Hu, Hao, Bozhevolnyi, Sergey I., Oxenløwe, Leif Katsuo, Jin, Kuijuan, Mortensen, N. Asger, and Xiao, Sanshui

Subjects

Physics - Optics

Abstract

Surface plasmon polaritons enable light concentration within subwavelength regions, opening thereby new avenues for miniaturizing the device and strengthening light-matter interactions. Here we realize effective electro-optic modulation in low-loss plasmonic waveguides with the aid of graphene, and the devices are fully integrated in the silicon-on-insulator platform. By advantageously exploiting low-loss plasmonic slot-waveguide modes, which weakly leak into a substrate while feature strong fields within the two-layer-graphene covered slots in metal, we successfully achieve a tunability of 0.13 dB/um for our fabricated graphene-plasmonic waveguide devices with extremely low insertion loss, which outperforms previously reported graphene-plasmonic devices. Our results highlight the potential of graphene plasmonic leaky-mode hybrid waveguides to realized active ultra-compact devices for optoelectronic applications., Comment: revised version with 12 pages and 4 figures

Published

2016

35. High-Dimensional Quantum Key Distribution based on Multicore Fiber using Silicon Photonic Integrated Circuits

Author

Ding, Yunhong, Bacco, Davide, Dalgaard, Kjeld, Cai, Xinlun, Zhou, Xiaoqi, Rottwitt, Karsten, and Oxenløwe, Leif Katsuo

Subjects

Quantum Physics

Abstract

Quantum Key Distribution (QKD) provides an efficient means to exchange information in an unconditionally secure way. Historically, QKD protocols have been based on binary signal formats, such as two polarisation states, and the transmitted information efficiency of the quantum key is intrinsically limited to 1 bit/photon. Here we propose and experimentally demonstrate, for the first time, a high-dimensional QKD protocol based on space division multiplexing in multicore fiber using silicon photonic integrated lightwave circuits. We successfully realized three mutually unbiased bases in a four-dimensional Hilbert space, and achieved low and stable quantum bit error rate well below both coherent attack and individual attack limits. Compared to previous demonstrations, the use of a multicore fiber in our protocol provides a much more efficient way to create high-dimensional quantum states, and enables breaking the information efficiency limit of traditional QKD protocols. In addition, the silicon photonic circuits used in our work integrate variable optical attenuators, highly efficient multicore fiber couplers, and Mach-Zehnder interferometers, enabling manipulating high-dimensional quantum states in a compact and stable means. Our demonstration pave the way to utilize state-of-the-art multicore fibers for long distance high-dimensional QKD, and boost silicon photonics for high information efficiency quantum communications., Comment: Please see the complementary work arXiv:1610.01682 (2016)

Published

2016

36. Reconfigurable SDM Switching Using Novel Silicon Photonic Integrated Circuit

Author

Ding, Yunhong, Kamchevska, Valerija, Dalgaard, Kjeld, Ye, Feihong, Asif, Rameez, Gross, Simon, Withford, Michael J., Galili, Michael, Morioka, Toshio, and Oxenlowe, Leif Katsuo

Subjects

Physics - Optics

Abstract

Space division multiplexing using multicore fibers is becoming a more and more promising technology. In space-division multiplexing fiber network, the reconfigurable switch is one of the most critical components in network nodes. In this paper we for the first time demonstrate reconfigurable space-division multiplexing switching using silicon photonic integrated circuit, which is fabricated on a novel silicon-on-insulator platform with buried Al mirror. The silicon photonic integrated circuit is composed of a 7x7 switch and low loss grating coupler array based multicore fiber couplers. Thanks to the Al mirror, grating couplers with ultra-low coupling loss with optical multicore fibers is achieved. The lowest total insertion loss of the silicon integrated circuit is as low as 4.5 dB, with low crosstalk lower than -30 dB. Excellent performances in terms of low insertion loss and low crosstalk are obtained for the whole C-band. 1 Tb/s/core transmission over a 2-km 7-core fiber and space-division multiplexing switching is demonstrated successfully. Bit error rate performance below 10-9 is obtained for all spatial channels with low power penalty. The proposed design can be easily upgraded to reconfigurable optical add/drop multiplexer capable of switching several multicore fibers., Comment: 9 pages, 7 figures

Published

2016

37. Slow-light-enhanced energy efficiency for the graphene microheater on silicon photonic crystal waveguides

Author

Yan, Siqi, Zhu, Xiaolong, Frandsen, Lars Hagedorn, Xiao, Sanshui, Mortensen, N. Asger, Dong, Jianji, and Ding, Yunhong

Subjects

Physics - Optics

Abstract

Slow light has been widely utilized to obtain enhanced nonlinearities, enhanced spontaneous emissions, and increased phase shifts owing to its ability to promote light-matter interactions. By incorporating a graphene microheater on a slow-light silicon photonic crystal waveguide, we experimentally demonstrated an energy-efficient graphene microheater with a tuning efficiency of 1.07 nm/mW and power consumption per free spectral range of 3.99 mW. The rise and decay times (10% to 90%) were only 750 ns and 525 ns, which, to the best of our knowledge, are the fastest reported response times for microheaters in silicon photonics. The corresponding record-low figure of merit of the device was 2.543 nW.s, which is one order of magnitude lower than results reported in previous studies. The influences of the graphene-photonic crystal waveguide interaction length and the shape of the graphene heater were also investigated, providing valuable guidelines for enhancing the graphene microheater tuning efficiency., Comment: 18 pages, 4 figures

Published

2016

38. Two-dimensional distributed-phase-reference protocol for quantum key distribution

Author

Bacco, Davide, Christensen, Jesper Bjerge, Castaneda, Mario A. Usuga, Ding, Yunhong, Forchhammer, Søren, Rottwitt, Karsten, and Oxenløwe, Leif Katsuo

Subjects

Quantum Physics

Abstract

Quantum key distribution (QKD) and quantum communication enable the secure exchange of information between remote parties. Currently, the distributed-phase-reference (DPR) protocols, which are based on weak coherent pulses, are among the most practical solutions for long-range QKD. During the last 10 years, long-distance fiber-based DPR systems have been successfully demonstrated, although fundamental obstacles such as intrinsic channel losses limit their performance. Here, we introduce the first two-dimensional DPR-QKD protocol in which information is encoded in the time and phase of weak coherent pulses. The ability of extracting two bits of information per detection event, enables a higher secret key rate in specific realistic network scenarios. Moreover, despite the use of more dimensions, the proposed protocol remains simple, practical, and fully integrable., Comment: 7 pages, 5 figures

Published

2016

39. Photonic integrated chip enabling orbital angular momentum multiplexing for quantum communication

Author

Zahidy Mujtaba, Liu Yaoxin, Cozzolino Daniele, Ding Yunhong, Morioka Toshio, Oxenløwe Leif K., and Bacco Davide

Subjects

orbital angular momentum, quantum communication, quantum key distribution, silicon photonics, Physics, QC1-999

Abstract

Light carrying orbital angular momentum constitutes an important resource for both classical and quantum information technologies. Its inherently unbounded nature can be exploited to generate high-dimensional quantum states or for channel multiplexing in classical and quantum communication in order to significantly boost the data capacity and the secret key rate, respectively. While the big potentials of light owning orbital angular momentum have been widely ascertained, its technological deployment is still limited by the difficulties deriving from the fabrication of integrated and scalable photonic devices able to generate and manipulate it. Here, we present a photonic integrated chip able to excite orbital angular momentum modes in an 800 m long ring-core fiber, allowing us to perform parallel quantum key distribution using two and three different modes simultaneously. The experiment sets the first steps towards quantum orbital angular momentum division multiplexing enabled by a compact and light-weight silicon chip, and further pushes the development of integrated scalable devices supporting orbital angular momentum modes.

Published

2021

40. A programmable qudit-based quantum processor

Author

Chi, Yulin, Huang, Jieshan, Zhang, Zhanchuan, Mao, Jun, Zhou, Zinan, Chen, Xiaojiong, Zhai, Chonghao, Bao, Jueming, Dai, Tianxiang, Yuan, Huihong, Zhang, Ming, Dai, Daoxin, Tang, Bo, Yang, Yan, Li, Zhihua, Ding, Yunhong, Oxenløwe, Leif K., Thompson, Mark G., O’Brien, Jeremy L., Li, Yan, Gong, Qihuang, and Wang, Jianwei

Published

2022

41. Quantum prospects for hybrid thin-film lithium niobate on silicon photonics

Author

Adcock, Jeremy C. and Ding, Yunhong

Published

2022

42. Conductivity analysis of tortuous fractures filled with non-spherical proppants

Author

Xu, Jiaxiang, Ding, Yunhong, Yang, Lifeng, Liu, Zhe, Gao, Rui, Yang, Hanxuan, and Wang, Zhen

Published

2021

43. Ultrafast Silicon/Graphene Optical Nonlinear Activator for Neuromorphic Computing.

Author

Zhou, Ziwen, Liu, Chen, Zhao, Weiwei, Liu, Jingze, Jiang, Ting, Peng, Wenyi, Xiong, Jiawang, Wu, Hao, Zhang, Chi, Ding, Yunhong, Da Ros, Francesco, Xu, Xingyuan, Xu, Kun, Yan, Siqi, and Tang, Ming

Subjects

ARTIFICIAL neural networks, SIGNAL processing, ENERGY consumption, GRAPHENE, PLASMONICS

Abstract

Optical neural networks (ONNs) have shown great promise in overcoming the speed and efficiency bottlenecks of artificial neural networks. However, the absence of high‐speed, energy‐efficient nonlinear activators significantly impedes the advancement of ONNs and their extension to ultrafast application scenarios like real‐time intelligent signal processing. In this work, a novel silicon/graphene ultrafast all‐optical nonlinear activator, leveraging the hybrid integration of silicon slot waveguides, plasmonic slot waveguides, and monolayer graphene is demonstrated. Exploiting the exceptional picosecond‐scale photogenerated carrier relaxation time of graphene, the response time of the activator is markedly reduced to ≈93.6 ps, establishing all‐optical activator as the fastest known in silicon photonics to knowledge. Moreover, the all‐optical nonlinear activator holds a low threshold power of 5.49 mW and a corresponding power consumption per activation of 0.51 pJ. Its feasibility and capability for use in ONNs, manifesting performance comparable with commonly used activation functions are experimentally confirmed. This breakthrough in speed and energy efficiency of all‐optical nonlinear activators opens the door to significant improvements in the performance and applicability of ONNs. [ABSTRACT FROM AUTHOR]

Published

2024

44. A Method for Prediction and Analysis of Student Performance That Combines Multi-Dimensional Features of Time and Space.

Author

Luo, Zheng, Mai, Jiahao, Feng, Caihong, Kong, Deyao, Liu, Jingyu, Ding, Yunhong, Qi, Bo, and Zhu, Zhanbo

Subjects

MACHINE learning, EDUCATIONAL indicators, FEATURE selection, MULTISENSOR data fusion, TEACHING methods

Abstract

The prediction and analysis of students' academic performance are essential tools for educators and learners to improve teaching and learning methods. Effective predictive methods assist learners in targeted studying based on forecast results, while effective analytical methods help educators design appropriate educational content. However, in actual educational environments, factors influencing student performance are multidimensional across both temporal and spatial dimensions. Therefore, a student performance prediction and analysis method incorporating multidimensional spatiotemporal features has been proposed in this study. Due to the complexity and nonlinearity of learning behaviors in the educational process, predicting students' academic performance effectively is challenging. Nevertheless, machine learning algorithms possess significant advantages in handling data complexity and nonlinearity. Initially, a multidimensional spatiotemporal feature dataset was constructed by combining three categories of features: students' basic information, performance at various stages of the semester, and educational indicators from their places of origin (considering both temporal aspects, i.e., performance at various stages of the semester, and spatial aspects, i.e., educational indicators from their places of origin). Subsequently, six machine learning models were trained using this dataset to predict student performance, and experimental results confirmed their accuracy. Furthermore, SHAP analysis was utilized to extract factors significantly impacting the experimental outcomes. Subsequently, this study conducted data ablation experiments, the results of which proved the rationality of the feature selection in this study. Finally, this study proposed a feasible solution for guiding teaching strategies by integrating spatiotemporal multi-dimensional features in the analysis of student performance prediction in actual teaching processes. [ABSTRACT FROM AUTHOR]

Published

2024

45. Measurement of the Dispersion of χ(3)$\chi ^{(3)}$ of SiO2${\rm SiO}_2$ and SiN Across the THz and Far‐Infrared Frequency Bands.

Author

Zhou, Binbin, Rasmussen, Mattias, Zibod, Soheil, Yan, Siqi, Noori, Narwan Kabir, Nagy, Oliver, Ding, Yunhong, Lange, Simon Jappe, Dolgaleva, Ksenia, Boyd, Robert W., and Jepsen, Peter Uhd

Subjects

NONLINEAR optics, SILICON nitride, LORENTZIAN function, FUSED silica, GALLIUM arsenide

Abstract

Terahertz (THz) radiation sources based on two‐color femtosecond plasmas in air are becoming a mature technology for coherent spectroscopy and strong‐field physics across the extended THz range to several tens of THz. The field‐resolved detection of such THz transients relies on the third‐order nonlinearity of the detection medium. Here, a comparative measurement is demonstrated with air‐biased coherent detection (ABCD) and solid‐state biased detection (SSBCD) as a novel method to measure the dispersion of the magnitude and phase of the relevant third‐order nonlinearity χ(3)(2ω±Ω;ω,ω,±Ω)$\chi ^{(3)}(2\omega \pm \Omega;\omega,\omega,\pm \Omega)$ for fused silica (SiO2${\rm SiO}_2$) and silicon nitride (SiN). Based on the development of the ultrabroadband SSBCD device with a detection bandwidth exceeding 30 THz, χ(3)$\chi ^{(3)}$ measurements are obtained across the 1–28 THz frequency range, hence covering the THz and far‐infrared. It is shown that the vibrational modes in SiO2${\rm SiO}_2$ and SiN in the THz range lead to strong resonant enhancement and dispersion of the nonlinearity. The SSBCD devices operate down to nanojoule (nJ) probe energy, and their is demonstrated by measuring the dielectric function of the Lorentzian line profile of transverse‐optical (TO) phonon mode at 9 THz in single‐crystal gallium arsenide (GaAs) and observing the weak phonon combination bands near the TO phonon. [ABSTRACT FROM AUTHOR]

Published

2024

46. Ultra‐Sparse Aperiodic Silicon Optical Phased Array Using High‐Performance Thermo‐Optic Phase Shifter.

Author

Qiu, Huaqing, Liu, Yong, Meng, Xiansong, Guan, Xiaowei, Ding, Yunhong, and Hu, Hao

Subjects

PHASED array antennas, BEAM steering, INSERTION loss (Telecommunication), INTEGRATED circuits, ELECTRIC power

Abstract

Integrated optical phased array (OPA) is evolving into a transformational technology for LiDAR and free‐space optical communication systems due to its distinctive qualities of compact size, rapid scanning, and low cost. When the integrated OPA is utilized for long‐range vehicle LiDAR (300 m range), a large emission aperture (mm‐cm length) is required. However, a large aperture typically necessitates thousands of phase‐controlled emitters and consumes tens of watts when utilizing traditional thermo‐optic phase shifters. Here, an easy‐to‐understand theory is proposed and an ultra‐sparse aperiodic OPA is experimentally demonstrated with a large aperture (6 mm ×$\times$ 5 mm) using just 120 phase‐controlled emitters. In the azimuthal (φ$\varphi$) direction, high resolvable points of ≈$\approx$ 1300 have attained within a field of view (FOV) beam steering range of 162∘$162^{\circ }$. The consumed electric power is only 0.47 W thanks to the ultra‐sparse aperiodic spacing (≈$\approx$50 μm$\umu {\rm m}$ average pitch) and the high‐performance optical phase shifters. The fabrication‐robust thermo‐optic phase shifter achieved high performance in all relevant aspects including power consumption (3.1 mW/π$\pi$), driving voltage (1.1 V for 2π$\pi$), insertion loss (0.6 dB), modulation bandwidth (34 kHz), and footprint (42 μm×$\umu {\rm m} \times$ 42 μm$\umu {\rm m}$), acting as an ideal phase tuning component in large‐scale photonic integrated circuits. [ABSTRACT FROM AUTHOR]

Published

2024

47. A method for comparison of lifting effects of plunger lift and continuous gas lift

Author

Qi, Dan, Zou, Honglan, Chen, Ting, and Ding, Yunhong

Published

2020

48. Numerical analysis of proppants transport in tortuous fractures of shale gas reservoirs after shear deformation

Author

Xu, Jiaxiang, Ding, Yunhong, Yang, Lifeng, Liu, Zhe, Gao, Rui, Wang, Zhen, and Mo, Shaoyuan

Published

2020

49. Effective electro-optical modulation with high extinction ratio by a graphene-silicon microring resonator

Author

Ding, Yunhong, Zhu, Xiaolong, Xiao, Sanshui, Hu, Hao, Frandsen, Lars Hagedorn, Mortensen, N. Asger, and Yvind, Kresten

Subjects

Physics - Optics

Abstract

Graphene opens up for novel optoelectronic applications thanks to its high carrier mobility, ultra-large absorption bandwidth, and extremely fast material response. In particular, the opportunity to control optoelectronic properties through tuning of Fermi level enables electro-optical modulation, optical-optical switching, and other optoelectronics applications. However, achieving a high modulation depth remains a challenge because of the modest graphene-light interaction in the graphene-silicon devices, typically, utilizing only a monolayer or few layers of graphene. Here, we comprehensively study the interaction between graphene and a microring resonator, and its influence on the optical modulation depth. We demonstrate graphene-silicon microring devices showing a high modulation depth of 12.5 dB with a relatively low bias voltage of 8.8 V. On-off electro-optical switching with an extinction ratio of 3.8 dB is successfully demonstrated by applying a square-waveform with a 4 V peak-to-peak voltage., Comment: 12 pages, including 7 figures

Published

2015

50. Towards on-chip demonstration of a high-dimensional quantum random number generator

Author

Genzini, Maddalena, primary, Vigliar, Caterina, additional, Zahidy, Mujtaba, additional, Ding, Yunhong, additional, Zhou, Siyan, additional, Bacco, Davide, additional, and Da Ros, Francesco, additional

Published

2024