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1. Broadband millimeter-wave frequency mixer based on thin-film lithium niobate photonics

Author

Xie, Xiangzhi, Feng, Hanke, Tao, Yuansheng, Zhang, Yiwen, Chen, Yikun, Zhang, Ke, Chen, Zhaoxi, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Frequency mixers are fundamental components in modern wireless communication and radar systems, responsible for up- and down-conversion of target radio-frequency (RF) signals. Recently, photonic-assisted RF mixers have shown unique advantages over traditional electronic counterparts, including broad operational bandwidth, flat frequency response, and immunity to electromagnetic interference. However, current integrated photonic mixers face significant challenges in achieving efficient conversion at high frequencies, especially in millimeter-wave bands, due to the limitations of existing electro-optic (EO) modulators. Additionally, high-frequency local oscillators in the millimeter-wave range are often difficult to obtain and expensive, leading to unsatisfactory cost and restricted operational bandwidth in practice. In this paper, we harness the exceptional EO property and scalability of thin-film lithium niobate (TFLN) photonic platform to implement a high-performance harmonic reconfigurable millimeter-wave mixer. The TFLN photonic circuit integrates a broadband EO modulator that allows for extensive frequency coverage, and an EO frequency comb source that significantly reduces the required carrier frequency of the local oscillator. We experimentally demonstrate fully reconfigurable frequency down-conversion across a broad operational bandwidth ranging from 20 GHz to 67 GHz, with a large intermediate frequency of 20 GHz, as well as up-conversion to frequencies of up to 110 GHz. Our integrated photonic mixing system shows dramatically improved bandwidth performance, along with competitive indicators of frequency conversion efficiency and spurious suppression ratio, positioning it as a promising solution for future millimeter-wave transceivers in next-generation communication and sensing systems., Comment: 8 pages, 7 figures

Published
2024

2. Integrated adaptive coherent LiDAR for 4D bionic vision

Author

Chen, Ruixuan, Wu, Yichen, Zhang, Ke, Liu, Chuxin, Chen, Yikun, Li, Wencan, Shen, Bitao, Chen, Zhaoxi, Feng, Hanke, Ge, Zhangfeng, Zhou, Yan, Tao, Zihan, Xu, Weihan, Wang, Yimeng, Cai, Pengfei, Pan, Dong, Shu, Haowen, Zhou, Linjie, Wang, Cheng, and Wang, Xingjun

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Light detection and ranging (LiDAR) is a ubiquitous tool to provide precise spatial awareness in various perception environments. A bionic LiDAR that can mimic human-like vision by adaptively gazing at selected regions of interest within a broad field of view is crucial to achieve high-resolution imaging in an energy-saving and cost-effective manner. However, current LiDARs based on stacking fixed-wavelength laser arrays and inertial scanning have not been able to achieve the desired dynamic focusing patterns and agile scalability simultaneously. Moreover, the ability to synchronously acquire multi-dimensional physical parameters, including distance, direction, Doppler, and color, through seamless fusion between multiple sensors, still remains elusive in LiDAR. Here, we overcome these limitations and demonstrate a bio-inspired frequency-modulated continuous wave (FMCW) LiDAR system with dynamic and scalable gazing capability. Our chip-scale LiDAR system is built using hybrid integrated photonic solutions, where a frequency-chirped external cavity laser provides broad spectral tunability, while on-chip electro-optic combs with elastic channel spacing allow customizable imaging granularity. Using the dynamic zoom-in capability and the coherent FMCW scheme, we achieve a state-of-the-art resolution of 0.012 degrees, providing up to 15 times the resolution of conventional 3D LiDAR sensors, with 115 equivalent scanning lines and 4D parallel imaging. We further demonstrate cooperative sensing between our adaptive coherent LiDAR and a camera to enable high-resolution color-enhanced machine vision.

Published
2024

3. Programmable multifunctional integrated microwave photonic circuit on thin-film lithium niobate

Author

Wei, Chuangchuang, Feng, Hanke, Ye, Kaixuan, Eijkel, Maarten, Klaver, Yvan, Chen, Zhaoxi, Keloth, Akshay, Wang, Cheng, and Marpaung, David

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Microwave photonics, with its advanced high-frequency signal processing capabilities, is expected to play a crucial role in next-generation wireless communications and radar systems. The realization of highly integrated, high-performance, and multifunctional microwave photonic links will pave the way for its widespread deployment in practical applications, which is a significant challenge. Here, leveraging thin-film lithium niobate intensity modulator and programmable cascaded microring resonators, we demonstrate for the first time a tunable microwave photonic notch filter that simultaneously achieves high level of integration along with high dynamic range, high link gain, low noise figure, and ultra-high rejection ratio. Additionally, this programmable on-chip system is multifunctional, allowing for the dual-band notch filter and the suppression of the high-power interference signal. This work demonstrates the potential applications of the thin-film lithium niobate platform in the field of high-performance integrated microwave photonic filtering and signal processing, facilitating the advancement of microwave photonic system towards practical applications., Comment: 18 pages, 8 figures, 1 table

Published
2024

4. Microwave resonator-enabled broadband on-chip electro-optic frequency comb generation

Author

Chen, Zhaoxi, Zhang, Yiwen, Feng, Hanke, Zeng, Yuansong, Zhang, Ke, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Optical frequency combs play a crucial role in optical communications, time-frequency metrology, precise ranging, and sensing. Among various generation schemes, resonant electro-optic combs are particularly attractive for its excellent stability, flexibility and broad bandwidths. In this approach, an optical pump undergoes multiple electro-optic modulation processes in a high-Q optical resonator, resulting in cascaded spectral sidebands. However, most resonant electro-optic combs to date make use of lumped-capacitor electrodes with relatively inefficient utilization of the input electrical power. This design also reflects most electrical power back to the driving circuits and necessitates costly RF isolators in between, presenting substantial challenges in practical applications. To address these issues, we present an RF circuit friendly electro-optic frequency comb generator incorporated with on-chip coplanar microwave resonator electrodes, based on a thin-film lithium niobate platform. Our design achieves more than three times electrical power reduction with minimal reflection at the designed comb repetition rate of ~ 25 GHz. We experimentally demonstrate broadband electro-optic frequency comb generation with a comb span of >85 nm at a moderate electrical driving power of 740 mW (28.7 dBm). Our power-efficient and isolator-free electro-optic comb source could offer compact, low-cost and simple-to-design solution for applications in spectroscopy, high-precise metrology, optical communications.

Published
2024

5. Monolithic lithium niobate photonic chip for efficient terahertz-optic modulation and terahertz generation

Author

Zhang, Yiwen, Yang, Jingwei, Chen, Zhaoxi, Feng, Hanke, Zhu, Sha, Shum, Kam-Man, Chan, Chi Hou, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

The terahertz (THz) frequency range, bridging the gap between microwave and infrared frequencies, presents unparalleled opportunities for advanced imaging, sensing, communications, and spectroscopy applications. Terahertz photonics, in analogy with microwave photonics, is a promising solution to address the critical challenges in THz technologies through optical methods. Despite its vast potential, key technical challenges remain in effectively interfacing THz signals with the optical domain, especially THz-optic modulation and optical generation of THz waves. Here, we address these challenges using a monolithic integrated photonic chip designed to support efficient bidirectional interaction between THz and optical waves. Leveraging the significant second-order optical nonlinearity and strong optical and THz confinement in a thin-film lithium niobate on quartz platform, the chip supports both efficient THz-optic modulation and continuous THz wave generation at up to 500 GHz. The THz-optic modulator features a radio frequency (RF) half-wave voltage of 8V at 500 GHz, representing more than an order of magnitude reduction in modulation power consumption from previous works. The measured continuous wave THz generation efficiency of 4.8*10-6 /W at 500 GHz also marks a tenfold improvement over existing tunable THz generation devices based on lithium niobate. We further leverage the coherent nature of the optical THz generation process and mature optical modulation techniques to realize high-speed electro-THz modulation at frequencies up to 35 GHz. The chip-scale THz-photonic platform paves the way for more compact, efficient, and cost-effective THz systems with potential applications in THz communications, remote sensing, and spectroscopy.

Published
2024

6. In-situ optical vector analysis based on integrated lithium niobate single-sideband modulators

Author

Feng, Hanke, Ge, Tong, Hu, Yaowen, Wang, Zhenzheng, Zhang, Yiwen, Chen, Zhaoxi, Zhang, Ke, Sun, Wenzhao, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Optical vector analysis (OVA) is an enabling technology for comprehensively characterizing both amplitude and phase responses of optical devices or systems. Conventional OVA technologies are mostly based on discrete optoelectronic components, leading to unsatisfactory system sizes, complexity, and stability. They also encounter challenges in revealing the on-chip characteristics of integrated photonic devices, which are often overwhelmed by the substantial coupling loss and extra spectral response at chip facets. In this work, we demonstrate a miniaturized OVA system for integrated photonics devices based on broadband single sideband (SSB) modulators on a thin-film lithium niobate (LN) platform. The OVA could provide a direct probe of both amplitude and phase responses of photonic devices with kHz-level resolution and tens of terahertz measurement bandwidth. We perform in-situ characterizations of single and coupled microring resonators fabricated on the same chip as the OVA, unfolding their intrinsic loss and coupling states unambiguously. Furthermore, we achieve the direct measurement of collective phase dynamics and density of states of the Bloch modes in a synthetic frequency crystal, by in-situ OVA of a dynamically modulated microring resonator. Our in-situ OVA system provides a compact, high-precision, and broadband solution for characterizing future integrated photonic devices and circuits, with potential applications ranging from optical communications, biosensing, neuromorphic computing, to quantum information processing.

Published
2024

7. Hypermultiplexed Integrated-Photonics-based Tensor Optical Processor

Author

Ou, Shaoyuan, Xue, Kaiwen, Zhou, Lian, Lee, Chun-ho, Sludds, Alexander, Hamerly, Ryan, Zhang, Ke, Feng, Hanke, Kopparapu, Reshma, Zhong, Eric, Wang, Cheng, Englund, Dirk, Yu, Mengjie, and Chen, Zaijun

Subjects
Computer Science - Emerging Technologies, Physics - Optics
Abstract

The escalating data volume and complexity resulting from the rapid expansion of artificial intelligence (AI), internet of things (IoT) and 5G/6G mobile networks is creating an urgent need for energy-efficient, scalable computing hardware. Here we demonstrate a hypermultiplexed integratedphotonics-based tensor optical processor (HITOP) that can perform trillions of operations per second (TOPS) at the energy efficiency of 40 TOPS/W. Space-time-wavelength three-dimensional (3D) optical parallelism enables O($N^{2}$) operations per clock-cycle using O($N$) modulator devices. The system is built with wafer-fabricated III/V micron-scale lasers and high-speed thin-film Lithium-Niobate electro-optics for encoding at 10s femtojoule/symbol. Lasing threshold incorporates analog inline rectifier (ReLu) nonlinearity for low-latency activation. The system scalability is verified with machine learning models of 405,000 parameters. A combination of high clockrates, energy-efficient processing and programmability unlocks the potential of light for large-scale AI accelerators in applications ranging from training of large AI models to real-time decision making in edge deployment.

Published
2024

8. Spectral engineering of optical microresonators in anisotropic lithium niobate crystal

Author

Zhang, Ke, Chen, Yikun, Sun, Wenzhao, Chen, Zhaoxi, Feng, Hanke, and Wang, Cheng

Subjects
Physics - Optics, 35Q61, B.7.1
Abstract

On-chip optical microresonators are essential building blocks in integrated optics. The ability to arbitrarily engineer their resonant frequencies is crucial for exploring novel physics in synthetic frequency dimensions and practical applications like nonlinear optical parametric processes and dispersion-engineered frequency comb generation. Photonic crystal ring (PhCR) resonators are a versatile tool for such arbitrary frequency engineering, by controllably creating mode splitting at selected resonances. To date, these PhCRs have mostly been demonstrated in isotropic photonic materials, while such engineering could be significantly more complicated in anisotropic platforms that often offer more fruitful optical properties. Here, we realize the spectral engineering of chip-scale optical microresonators in the anisotropic lithium niobate (LN) crystal by a gradient design that precisely compensates for variations in both refractive index and perturbation strength. We experimentally demonstrate controllable frequency splitting at single and multiple selected resonances in LN PhCR resonators with different sizes, while maintaining high Q-factors up to 1 million. Moreover, we experimentally construct a sharp boundary in the synthetic frequency dimension based on an actively modulated x-cut LN gradient-PhCR, opening up new paths toward the arbitrary control of electro-optic comb spectral shapes and exploration of novel physics in the frequency degree of freedom., Comment: 19 pages, 5 figures

Published
2024
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9. Integrated lithium niobate photonic millimeter-wave radar

Author

Zhu, Sha, Zhang, Yiwen, Feng, Jiaxue, Wang, Yongji, Zhai, Kunpeng, Feng, Hanke, Pun, Edwin Yue Bun, Zhu, Ning Hua, and Wang, Cheng

Subjects
Physics - Optics, Electrical Engineering and Systems Science - Signal Processing, Physics - Applied Physics
Abstract

Millimeter-wave (mmWave,>30 GHz) radars are the key enabler in the coming 6G era for high-resolution sensing and detection of targets. Photonic radar provides an effective approach to overcome the limitations of electronic radars thanks to the high frequency, broad bandwidth, and excellent reconfigurability of photonic systems. However, conventional photonic radars are mostly realized in tabletop systems composed of bulky discrete components, whereas the more compact integrated photonic radars are difficult to reach the mmWave bands due to the unsatisfactory bandwidths and signal integrity of the underlining electro-optic modulators. Here, we overcome these challenges and demonstrate a centimeter-resolution integrated photonic radar operating in the mmWave V band (40-50 GHz) based on a 4-inch wafer-scale thin-film lithium niobate (TFLN) technology. The fabricated TFLN mmWave photonic integrated circuit consists of a first electro-optic modulator capable of generating a broadband linear frequency modulated mmWave radar waveform through optical frequency multiplication of a low-frequency input signal, and a second electro-optic modulator responsible for frequency de-chirp of the received reflected echo wave, therefore greatly relieving the bandwidth requirements for the analog-to-digital converter in the receiver. Thanks to the absence of optical and electrical filters in the system, our integrated photonic mmWave radar features continuous on-demand tunability of the center frequency and bandwidth, currently only limited by the bandwidths of electrical amplifiers. We achieve multi-target ranging with a resolution of 1.50 cm and velocity measurement with a resolution of 0.067 m/s. Furthermore, we construct an inverse synthetic aperture radar (ISAR) and successfully demonstrate the imaging of targets with various shapes and postures with a two-dimensional resolution of 1.50 cm * 1.06 cm.

Published
2023

10. Surface acoustic wave stimulated Brillouin scattering in thin-film lithium niobate waveguides

Author

Ye, Kaixuan, Feng, Hanke, Klaver, Yvan, Keloth, Akshay, Mishra, Akhileshwar, Wang, Cheng, and Marpaung, David

Subjects
Physics - Optics
Abstract

We report the first-ever experimental observation of backward stimulated Brillouin scattering (SBS) in thin-film lithium niobate (TFLN) waveguides. The peak Brillouin gain coefficient of the z-cut LN waveguide with a crystal rotation angle of 20$^{\circ}$ is as high as 84.9m$^{-1}$W$^{-1}$, facilitated by surface acoustic waves (SAW) at 8.06GHz.

Published
2023

11. Integrated lithium niobate microwave photonic processing engine

Author

Feng, Hanke, Ge, Tong, Guo, Xiaoqing, Wang, Benshan, Zhang, Yiwen, Chen, Zhaoxi, Zhu, Sha, Zhang, Ke, Sun, Wenzhao, Huang, Chaoran, Yuan, Yixuan, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Integrated microwave photonics is an intriguing field that leverages integrated photonic technologies for the generation, transmission, and manipulation of microwave signals in chip-scale optical systems. In particular, ultrafast processing and computation of analog electronic signals in the optical domain with high fidelity and low latency could enable a variety of applications such as MWP filters, microwave signal processing, and image recognition. An ideal photonic platform for achieving these integrated MWP processing tasks shall simultaneously offer an efficient, linear and high-speed electro-optic modulation block to faithfully perform microwave-optic conversion at low power, and a low-loss functional photonic network that can be configured for a variety of signal processing tasks, as well as large-scale, low-cost manufacturability to monolithically integrate the two building blocks on the same chip. In this work, we demonstrate such an integrated MWP processing engine based on a thin-film lithium niobate platform capable of performing multi-purpose processing and computation tasks of analog signals up to 92 giga samples per second at CMOS-compatible voltages. We demonstrate high-speed analog computation, i.e., first- and second-order temporal integration and differentiation with computing accuracies up to 98.1 %, and deploy these functions to showcase three proof-of-concept applications, namely, ordinary differential equation solving, ultra-wideband signal generation and high-speed edge detection of images. We further leverage the image edge detector to enable a photonic-assisted image segmentation model that could effectively outline the boundaries of melanoma lesion in medical diagnostic images, achieving orders of magnitude faster processing speed and lower power consumption than conventional electronic processors.

Published
2023

13. Design and resonator-assisted characterization of high performance lithium niobate waveguide crossings

Author

Chen, Yikun, Zhang, Ke, Feng, Hanke, Sun, Wenzhao, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Waveguide crossings are elementary passive components for signal routing in photonic integrated circuits. Here, we design and characterize two multimode interferometer (MMI)-based waveguide crossings to serve the various routing directions in the anisotropic x-cut thin-film lithium niobate (TFLN) platform. To address the large measurement uncertainties in traditional cut-back characterization methods, we propose and demonstrate a resonator-assisted approach that dramatically reduces the uncertainty of insertion loss measurement(< 0.021 dB) and the lower bound of crosstalk measurement (-60 dB) using only two devices. Based on this approach, we demonstrate and verify TFLN waveguide crossings with insertion losses of < 0.070 dB and crosstalk of < -50 dB along all three routing directions at 1550 nm. The low-loss and low-crosstalk waveguide crossings in this work, together with the simple and efficient characterization strategy, could provide important layout design flexibility for future large-scale classical and quantum TFLN photonic circuits., Comment: 10 pages, 4 figures

Published
2023
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14. Waveguide-Integrated Two-Dimensional Material Photodetectors in Thin-Film Lithium Niobate

Author

Zhu, Sha, Zhang, Yiwen, Ren, Yi, Wang, Yongji, Zhai, Kunpeng, Feng, Hanke, Jin, Ya, Lin, Zezhou, Feng, Jiaxue, Li, Siyuan, Yang, Qi, Zhu, Ning Hua, Pun, Edwin Yue-Bun, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Thin-film lithium niobate on insulator (LNOI) is a promising platform for optical communications, microwave photonics, and quantum technologies. While many high-performance devices like electro-optic modulators and frequency comb sources have been achieved on LNOI platform, it remains challenging to realize photodetectors (PDs) on LNOI platform using simple and low-cost fabrication techniques. Two-dimensional (2D) materials are excellent candidates to achieve photodetection since they feature strong light-matter interaction, excellent mechanical flexibility, and potential large-scale complementary metal-oxide-semiconductor-compatible fabrication. In this work, we propose to address this demand using an LNOI-2D material platform and demonstrate two types of high-performance LNOI waveguide-integrated 2D material PDs, namely graphene and Tellurium (Te). Specifically, the LNOI-graphene PD features broadband operations at telecom and visible wavelengths, high normalized photocurrent-to-dark current ratios up to 3*106 W-1, and large 3-dB photoelectric bandwidths of over 40 GHz, simultaneously. The LNOI-Te PD on the other hand provides an ultrahigh responsivity of 7 A/W under 0.5 V bias for telecom optical signals while supporting GHz frequency responses. Our results show that the versatile properties of 2D materials and their excellent compatibility with LNOI waveguides could provide important low-cost solutions for system operating point monitoring and high-speed photoelectric conversion in future LN photonic integrated circuits.

Published
2022

15. A power-efficient integrated lithium niobate electro-optic comb generator

Author

Zhang, Ke, Sun, Wenzhao, Chen, Yikun, Feng, Hanke, Zhang, Yiwen, Chen, Zhaoxi, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Integrated electro-optic (EO) frequency combs are essential components for future applications in optical communications, light detection and ranging, optical computation, sensing and spectroscopy. To date, broadband on-chip EO combs are typically generated in high-quality-factor micro-resonators, while the more straightforward and flexible non-resonant method, usually using single or cascaded EO phase modulators, often requires high driving power to realize a reasonably strong modulation index. Here, we show that the phase modulation efficiency of an integrated lithium niobate modulator could be dramatically enhanced by passing optical signals through the modulation electrodes for a total of 4 round trips, via multiple low-loss TE0/TE1 mode multiplexers and waveguide crossings, reducing electrical power consumption by more than one order of magnitude. Using devices fabricated from a wafer-scale stepper lithography process, we demonstrate a broadband optical frequency comb featuring 47 comb lines at a 25-GHz repetition rate, using a moderate RF driving power of 28 dBm (0.63 W). Leveraging the excellent tunability in repetition rate and operation wavelength, our power-efficient EO comb generator could serve as a compact low-cost solution for future high-speed data transmission, sensing and spectroscopy, as well as classical and quantum optical computation systems., Comment: 9 pages, 4 fingures

Published
2022
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16. Ultra-high-linearity integrated lithium niobate electro-optic modulators

Author

Feng, Hanke, Zhang, Ke, Sun, Wenzhao, Ren, Yangming, Zhang, Yiwen, Zhang, Wenfu, and Wang, Cheng

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Integrated lithium niobate (LN) photonics is a promising platform for future chip-scale microwave photonics systems owing to its unique electro-optic properties, low optical loss and excellent scalability. A key enabler for such systems is a highly linear electro-optic modulator that could faithfully covert analog electrical signals into optical signals. In this work, we demonstrate a monolithic integrated LN modulator with an ultrahigh spurious-free dynamic range (SFDR) of 120.04 dB Hz4/5 at 1 GHz, using a ring-assisted Mach-Zehnder interferometer configuration. The excellent synergy between the intrinsically linear electro-optic response of LN and an optimized linearization strategy allows us to fully suppress the cubic terms of third-order intermodulation distortions (IMD3) without active feedback controls, leading to ~ 20 dB improvement over previous results in the thin-film LN platform. Our ultra-high-linearity LN modulators could become a core building block for future large-scale functional microwave photonic integrated circuits, by further integration with other high-performance components like low-loss delay lines, tunable filters and phase shifters available on the LN platform.

Published
2022
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20. Hypermultiplexed Integrated Tensor Optical Processor

Author

Ou, Shaoyuan, Sludds, Alexander, Hamerly, Ryan, Zhang, Ke, Feng, Hanke, Zhong, Eric, Wang, Cheng, Englund, Dirk, Yu, Mengjie, Chen, Zaijun, Ou, Shaoyuan, Sludds, Alexander, Hamerly, Ryan, Zhang, Ke, Feng, Hanke, Zhong, Eric, Wang, Cheng, Englund, Dirk, Yu, Mengjie, and Chen, Zaijun

Abstract

The escalating data volume and complexity resulting from the rapid expansion of artificial intelligence (AI), internet of things (IoT) and 5G/6G mobile networks is creating an urgent need for energy-efficient, scalable computing hardware. Here we demonstrate a hypermultiplexed integrated tensor optical processor (HITOP) that performs trillions of operations per second (TeraOPS) at the energy cost of 25 femtojoule per operation (25 fJ/OP). Based on space-time-wavelength three-dimensional (3D) data streaming, HITOP is built with arrays of wafer-fabricated III/V-based micron-scale lasers (spanning ~1 THz) incorporating thin-film Lithium-Niobate electro-optic (EO) photonics. Multidimensional parallelism allows matrix-matrix multiplications ($N^{3}$ operations) using $O(N)$ devices, facilitating scalable on-chip integration. With each device activating 10 billion parameters per second, the HITOP scalability is validated in machine learning models with 405,000 parameters, which is 25,000 times more than previous integrated optical systems. A combination of high clockrates (10 GS/s), parallel processing and real-time reprogrammability unlocks the full potential of light for next-generation AI accelerators in applications ranging from training with trillions of parameters, real-time decision making in autonomous vehicles and robotics, dynamic optimization in smart manufacturing, to complex simulation for climate modeling and drug discovery.

Published
2024

21. Stacking and Detecting Blood Glutathione as a Cation under Strong Acidic Conditions by Capillary Electrophoresis using Acetonitrile-salt Stacking Method

Author

Yu Kong, Feng, Hanke, Yang, Guifang, Kong, Linghong, Hou, Zhanwu, Li, Hua, and Gao, Meili

Subjects
Electrophoresis -- Analysis -- Methods, Phosphoric acid -- Methods -- Analysis, Thiols -- Analysis -- Methods, Phosphates -- Analysis -- Methods, Acetonitrile -- Analysis -- Methods, Chemistry
Abstract

Blood glutathione (exists in both reduced and oxidized states) was firstly stacked and separated as a cation using acetonitrile-salt stacking method by capillary electrophoresis. Blood samples were treated with 200 mM phosphoric acid and acetonitrile at a final volume ratio of 2 : 1 : 1 and supernates were directly assayed after centrifugation (15 000 g, 15 min). Several factors influencing the separation and stacking were systematically investigated and optimized. Under the selected conditions, blood glutathione can be detected within 35 min with satisfactory limit of detection (0.1-0.3 [mu]M), relative standard deviation (, Author(s): Yu Kong [sup.1], Hanke Feng [sup.1], Guifang Yang [sup.1], Linghong Kong [sup.1], Zhanwu Hou [sup.1], Hua Li [sup.1], Meili Gao [sup.1] Author Affiliations: (1) grid.43169.39, 0000 0001 0599 1243, [...]

Published
2020
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