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1. Ultrabroadband thin-film lithium tantalate modulator for high-speed communications

Author

Wang, Chengli, Fang, Dengyang, Kotz, Alexander, Lihachev, Grigory, Churaev, Mikhail, Li, Zihan, Schwarzenberger, Adrian, Ou, Xin, Koos, Christian, and Kippenberg, Tobias

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

The continuous growth of global data traffic over the past three decades, along with advances in disaggregated computing architectures, presents significant challenges for optical transceivers in communication networks and high-performance computing systems. Specifically, there is a growing need to significantly increase data rates while reducing energy consumption and cost. High-performance optical modulators based on materials such as InP, thin-film lithium niobate (LiNbO3), or plasmonics have been developed, with LiNbO3 excelling in high-speed and low-voltage modulation. Nonetheless, the widespread industrial adoption of thin film LiNbO3 remains compounded by the rather high cost of the underlying 'on insulator' substrates -- in sharp contrast to silicon photonics, which can benefit from strong synergies with high-volume applications in conventional microelectronics. Here, we demonstrate an integrated 110 GHz modulator using thin-film lithium tantalate (LiTaO3) -- a material platform that is already commercially used for millimeter-wave filters and that can hence build upon technological and economic synergies with existing high-volume applications to offer scalable low-cost manufacturing. We show that the LiTaO3 photonic integrated circuit based modulator can support 176 GBd PAM8 transmission at net data rates exceeding 400 Gbit/s, while exhibiting a lower bias drift compared to LiNbO3. Moreover, we show that using silver electrodes can reduce microwave losses compared to previously employed gold electrodes. Our demonstration positions LiTaO3 modulator as a novel and highly promising integration platform for next-generation high-speed, energy-efficient, and cost-effective transceivers.

Published
2024

2. Integrated Triply Resonant Electro-Optic Frequency Comb in Lithium Tantalate

Author

Zhang, Junyin, Wang, Chengli, Denney, Connor, Lihachev, Grigory, Hu, Jianqi, Kao, Wil, Blésin, Terence, Kuznetsov, Nikolai, Li, Zihan, Churaev, Mikhail, Ou, Xin, Riemensberger, Johann, Santamaria-Botello, Gabriel, and Kippenberg, Tobias J.

Subjects
Physics - Optics
Abstract

Integrated frequency comb generators based on Kerr parametric oscillation have led to chip-scale, gigahertz-spaced combs with new applications spanning hyperscale telecommunications, low-noise microwave synthesis, LiDAR, and astrophysical spectrometer calibration. Recent progress in lithium niobate (LN) photonic integrated circuits (PICs) has resulted in chip-scale electro-optic (EO) frequency combs, offering precise comb-line positioning and simple operation without relying on the formation of dissipative Kerr solitons. However, current integrated EO combs face limited spectral coverage due to the large microwave power required to drive the non-resonant capacitive electrodes and the strong intrinsic birefringence of Lithium Niobate. Here, we overcome both challenges with an integrated triply resonant architecture, combining monolithic microwave integrated circuits (MMICs) with PICs based on the recently emerged thin-film lithium tantalate. With resonantly enhanced EO interaction and reduced birefringence in Lithium Tantalate, we achieve a four-fold comb span extension and a 16-fold power reduction compared to the conventional non-resonant microwave design. Driven by a hybrid-integrated laser diode, the comb spans over 450nm (60THz) with >2000 lines, and the generator fits within a compact 1cm^2 footprint. We additionally observe that the strong EO coupling leads to an increased comb existence range approaching the full free spectral range of the optical microresonator. The ultra-broadband comb generator, combined with detuning-agnostic operation, could advance chip-scale spectrometry and ultra-low-noise millimeter wave synthesis and unlock octave-spanning EO combs. The methodology of co-designing microwave and optical resonators can be extended to a wide range of integrated electro-optics applications., Comment: Main text: 9 pages; SI: 20 pages; v2: Funding information correction; v3: Acknowledgement update

Published
2024

3. Dependence on parameters of solutions for a generalized poly-Laplacian system on weighted graphs

Author

Wang, Xiaoyu, Xie, Junping, Zhang, Xingyong, and Ou, Xin

Subjects
Mathematics - Analysis of PDEs
Abstract

We mainly investigate the continuous dependence on parameters of nontrivial solutions for a generalized poly-Laplacian system on the weighted finite graph $G=(V, E)$. We firstly present an existence result of mountain pass type nontrivial solutions when the nonlinear term $F$ satisfies the super-$(p, q)$ linear growth condition which is a simple generalization of those results in [28]. Then we mainly show that the mountain pass type nontrivial solutions of the poly-Laplacian system are uniformly bounded for parameters and the concrete upper and lower bounds are given, and are continuously dependent on parameters. Similarly, we also present the existence result, the concrete upper and lower bounds, uniqueness, and dependence on parameters for the locally minimum type nontrivial solutions. Subsequently, we present an example on optimal control as an application of our results. Finally, we give a nonexistence result and some results for the corresponding scalar equation.

Published
2024

4. Ground state sign-changing homoclinic solutions for a discrete nonlinear $p$-Laplacian equation with logarithmic nonlinearity

Author

Ou, Xin and Zhang, Xingyong

Subjects
Mathematics - Analysis of PDEs
Abstract

By using a direct non-Nehari manifold method from [X.H. Tang, B.T. Cheng. J. Differ. Equations. 261(2016), 2384-2402.], we obtain an existence result of ground state sign-changing homoclinic solution which only changes sign one times and ground state homoclinic solution for a class of discrete nonlinear $p$-Laplacian equation with logarithmic nonlinearity. Moreover, we prove that the sign-changing ground state energy is larger than twice of the ground state energy.

Published
2023

5. Room-Temperature entangled quantum processor on integrated semiconductor photonics platform

Author

Hu, Haibo, Zhou, Yu, Yi, Ailun, Bao, Tongyuan, Liu, Chengying, Luo, Qi, Zhang, Yao, Wang, Zi, Liu, Zhengtong, Xiao, Shuming, Ou, Xin, and Song, Qinghai

Subjects
Quantum Physics, Physics - Optics
Abstract

The rise of the 4H-silicon-carbide-on-insulator (SiCOI) platform marks a promising pathway towards the realization of monolithic quantum photonic networks. However, the challenge of establishing room-temperature entangled registers on these integrated photonics platforms remains unresolved. Herein, we demonstrate the first entangled processor on the SiCOI platform. We show that both deterministic generation of single divacancy electron spins and near-unity spin initialization of a single $^{13}$C nuclear spin can be achieved on SiCOI at room temperature. Besides coherently manipulating the single nuclear spin, a maximally entangled state with a fidelity of 0.89 has been prepared on this CMOS-compatible semiconductor-integrated photonics system. This work establishes the foundation for compact and on-chip solutions within existing defect-based computing and sensing protocols, positioning the SiCOI platform as the most promising candidate for integrated monolithic quantum photonic networks., Comment: 16 pages, 4 figures

Published
2023

6. Lithium tantalate electro-optical photonic integrated circuits for high volume manufacturing

Author

Wang, Chengli, Li, Zihan, Riemensberger, Johann, Lihachev, Grigory, Churaev, Mikhail, Kao, Wil, Ji, Xinru, Blesin, Terence, Davydova, Alisa, Chen, Yang, Wang, Xi, Huang, Kai, Ou, Xin, and Kippenberg, Tobias J.

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Photonic integrated circuits based on Lithium Niobate have demonstrated the vast capabilities afforded by material with a high Pockels coefficient, allowing linear and high-speed modulators operating at CMOS voltage levels for applications ranging from data-center communications and photonic accelerators for AI. However despite major progress, the industrial adoption of this technology is compounded by the high cost per wafer. Here we overcome this challenge and demonstrate a photonic platform that satisfies the dichotomy of allowing scalable manufacturing at low cost, while at the same time exhibiting equal, and superior properties to those of Lithium Niobate. We demonstrate that it is possible to manufacture low loss photonic integrated circuits using Lithium Tantalate, a material that is already commercially adopted for acoustic filters in 5G and 6G. We show that LiTaO3 posses equally attractive optical properties and can be etched with high precision and negligible residues using DUV lithography, diamond like carbon (DLC) as a hard mask and alkaline wet etching. Using this approach we demonstrate microresonators with an intrinsic cavity linewidth of 26.8 MHz, corresponding to a linear loss of 5.6 dB/m and demonstrate a Mach Zehnder modulator with Vpi L = 4.2 V cm half-wave voltage length product. In comparison to Lithium Niobate, the photonic integrated circuits based on LiTaO3 exhibit a much lower birefringence, allowing high-density circuits and broadband operation over all telecommunication bands (O to L band), exhibit higher photorefractive damage threshold, and lower microwave loss tangent. Moreover, we show that the platform supports generation of soliton microcombs in X-Cut LiTaO3 racetrack microresonator with electronically detectable repetition rate, i.e. 30.1 GHz., Comment: 8 pages, 4 figures

Published
2023
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7. Ground state sign-changing solutions for Kirchhoff-type equations with logarithmic nonlinearity on locally finite graphs

Author

Ou, Xin and Zhang, Xingyong

Subjects
Mathematics - Analysis of PDEs
Abstract

We obtain the existence results of ground state sign-changing solutions and ground state solutions for a class of Kirchhoff-type equations with logarithmic nonlinearity on a locally finite graph $G=(V,E)$, and obtain the sign-changing ground state energy is larger than twice of the ground state energy. The method we used is a direct non-Nehari manifold method in [X.H. Tang, B.T. Cheng. J. Differ. Equations. 261(2016), 2384-2402.]

Published
2023

14. Hybrid integration of deterministic quantum dots-based single-photon sources with CMOS-compatible silicon carbide photonics

Author

Zhu, Yifan, Wei, Wenqi, Yi, Ailun, Jin, Tingting, Shen, Chen, Wang, Xudong, Zhou, Liping, Wang, Chengli, Ou, Weiwen, Song, Sannian, Wang, Ting, Zhang, Jianjun, Ou, Xin, and Zhang, Jiaxiang

Subjects
Physics - Optics, Quantum Physics
Abstract

Thin film 4H-silicon carbide (4H-SiC) is emerging as a contender for realizing large-scale optical quantum circuits due to its high CMOS technology compatibility and large optical nonlinearities. Though, challenges remain in producing wafer-scale 4H-SiC thin film on insulator (4H-SiCOI) for dense integration of photonic circuits, and in efficient coupling of deterministic quantum emitters that are essential for scalable quantum photonics. Here we demonstrate hybrid integration of self-assembled InGaAs quantum dots (QDs) based single-photon sources (SPSs) with wafer-scale 4H-SiC photonic chips prepared by ion slicing technique. By designing a bilayer vertical coupler, we realize generation and highly efficient routing of single-photon emission in the hybrid quantum photonic chip. Furthermore, we realize a chip-integrated beamsplitter operation for triggered single photons through fabricating a 1x2 multi-mode interferometer (MMI) with a symmetric power splitting ratio of 50:50. The successful demonstration of heterogeneously integrating QDs-based SPSs on 4H-SiC photonic chip prepared by ion slicing technique constitutes an important step toward CMOS-compatible, fast reconfigurable quantum photonic circuits with deterministic SPSs., Comment: 16 pages, 4 figures

Published
2022

15. Silicon carbide for integrated photonics

Author

Yi, Ailun, Wang, Chengli, Zhou, Liping, Zhou, Min, Zhang, Shibin, You, Tiangui, Zhang, Jiaxiang, and Ou, Xin

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

The recent progress in chip-scale integrated photonics has stimulated the rapid development of material platforms with desired optical properties. Among the different material platforms that are currently investigated, the third-generation semiconductor, silicon carbide (SiC), offers the broadest range of functionalities, including wide bandgap, high optical nonlinearities, high refractive index, and CMOS-compatible device fabrication process. Here, we provide an overview of SiC-based integrated photonics, presenting the latest progress on investigating its basic optical and optoelectronic properties, as well as the recent developments in the fabrication of several typical approaches for light confinement structures that form the basic building blocks for low-loss, high functional and industry-compatible integrated photonic platform. Moreover, recent works employing SiC as optically-readable spin hosts for quantum information applications are also summarized and discussed. As a still-developing integrated photonic platform, the prospects and challenges of SiC material platform in the field of integrated photonics are also discussed, followed by potential solutions., Comment: 47pages, 15 figures

Published
2022
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18. Monolithic Integrated Multiband Acoustic Devices on Heterogeneous Substrate for Sub-6 GHz RF-FEMs

Author

Zhang, Shibin, Zhou, Hongyan, Zheng, Pengcheng, Wu, Jinbo, Zhang, Liping, Li, Zhongxu, Huang, Kai, Ou, Xin, and Wang, Xi

Subjects
Electrical Engineering and Systems Science - Signal Processing
Abstract

Monolithic integration of multiband (1.4~ 6.0 GHz) RF acoustic devices were successfully demonstrated within the same process flow by using the lithium niobate (LN) thin film on silicon carbide (LNOSiC) substrate. A novel surface mode with sinking energy distribution was proposed, exhibiting reduced propagation loss. Surface wave and Lamb wave resonators with suppressed transverse modes and leaky modes were demonstrated, showing scalable resonances from 1.4 to 5.7 GHz, electromechanical coupling coefficients (k2) between 7.9% and 29.3%, and maximum Bode-Q (Qmax) larger than 3200. Arrayed filters with a small footprint (4.0 x 2.5 mm2) but diverse center frequencies (fc) and 3-dB fractional bandwidths (FBW) were achieved, showing fc from 1.4 to 6.0 GHz, FBW between 3.3% and 13.3%, and insertion loss (IL) between 0.59 and 2.10 dB. These results may promote the progress of hundred-filter sub-6 GHz RF front-end modules (RF-FEMs)., Comment: 6 pages, 19 figures

Published
2021

21. An Ultrahigh-Q Microresonator on 4H-silicon-carbide-on-insulator Platform for Multiple Harmonics, Cascaded Raman Lasing and Kerr Comb Generations

Author

Wang, Chengli, Fang, Zhiwei, Yi, Ailun, Yang, Bingcheng, Wang, Zhe, Zhou, Liping, Shen, Chen, Zhu, Yifan, Zhou, Yuan, Bao, Rui, Li, Zhongxu, Chen, Yang, Huang, Kai, Zhang, Jiaxiang, Cheng, Ya, and Ou, Xin

Subjects
Physics - Optics
Abstract

The realization of ultrahigh quality (Q) resonators regardless of the underpinning material platforms has been a ceaseless pursuit, because the high Q resonators provide an extreme environment of storage of light to enable observations of many unconventional nonlinear optical phenomenon with high efficiencies. Here, we demonstrate an ultra-high Q factor (7.1*10^6) microresonator on the 4H-silicon-carbide-on-insulator (4H-SiCOI) platform in which both \c{hi}^(2) and \c{hi}^(3) nonlinear processes of high efficiencies have been generated. Broadband frequency conversions, including second-, third-, fourth-harmonic generation were observed. Cascaded Raman lasing was demonstrated in the SiC microresonator for the first time to the best of our knowledge. Broadband Kerr frequency combs covering from 1300 to 1700 nm were achieved using a dispersion-engineered SiC microresonator. Our demonstration is a significant milestone in the development of SiC photonic integrated devices.

Published
2021

22. Thermal Visualization of Buried Interfaces by Transient and Steady-State Responses of Time-Domain Thermoreflectance

Author

Cheng, Zhe, Mu, Fengwen, Ji, Xiaoyang, You, Tiangui, Xu, Wenhui, Suga, Tadatomo, Ou, Xin, Cahill, David G., and Graham, Samuel

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Thermal resistances from interfaces impede heat dissipation in micro/nanoscale electronics, especially for high-power electronics. Despite the growing importance of understanding interfacial thermal transport, advanced thermal characterization techniques which can visualize thermal conductance across buried interfaces, especially for nonmetal-nonmetal interfaces, are still under development. This work reports a dual-modulation-frequency TDTR mapping technique to visualize the thermal conduction across buried semiconductor interfaces for beta-Ga2O3-SiC samples. Both the beta-Ga2O3 thermal conductivity and the buried beta-Ga2O3-SiC thermal boundary conductance (TBC) are visualized for an area of 200 um x 200 um. Areas with low TBC values ( smaller than 20 MW/m2-K) are successfully identified on the TBC map, which correspond to weakly bonded interfaces caused by high-temperature annealing. The steady-state temperature rise (detector voltage), usually ignored in TDTR measurements, is found to be able to probe TBC variations of the buried interfaces without the limit of thermal penetration depth. This technique can be applied to detect defects/voids in deeply buried heterogeneous interfaces non-destructively, and also opens a door for the visualization of thermal conductance in nanoscale nonhomogeneous structures.

Published
2021

23. Visible and Near-infrared Microdisk Resonators on a 4H-Silicon-Carbide-on-Insulator Platform

Author

Wang, Chengli, Shen, Chen, Yi, Ailun, Yang, Shumin, Zhou, Liping, Zhu, Yifan, Huang, Kai, Song, Sannian, Zhou, Min, Zhang, Jiaxiang, and Ou, Xin

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Wavelength-sized microdisk resonators were fabricated on a single crystalline 4H-silicon-carbide-oninsulator platform (4H-SiCOI). By carrying out microphotoluminescence measurements at room temperature, we show that the microdisk resonators support whispering-gallery modes (WGMs) with quality factors up to $5.25 \times 10^3$ and mode volumes down to $2.69 \times(\lambda /n)^3$ at the visible and near-infrared wavelengths. Moreover, the demonstrated wavelength-sized microdisk resonators exhibit WGMs whose resonant wavelengths compatible with the zero-phonon lines of spin defects in 4H-SiCOI, making them a promising candidate for applications in cavity quantum electrodynamics and integrated quantum photonic circuits., Comment: 5 pages, 4 figures

Published
2021
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24. Superconducting microstrip single-photon detector with system detection efficiency over 90% at 1550 nm

Author

Xu, Guang-Zhao, Zhang, Wei-Jun, You, Li-Xing, Xiong, Jia-Min, Sun, Xing-Qu, Huang, Hao, Ou, Xin, Pan, Yi-Ming, Lv, Chao-Lin, Li, Hao, Wang, Zhen, and Xie, Xiao-Ming

Subjects
Physics - Instrumentation and Detectors, Physics - Optics
Abstract

Generally, a superconducting nanowire single-photon detector (SNSPD) is composed of wires with a typical width of ~100 nm. Recent studies have found that superconducting strips with a micrometer-scale width can also detect single photons. Compared with the SNSPD, the superconducting microstrip single-photon detector (SMSPD) has smaller kinetic inductance, higher working current, and lower requirement in fabrication accuracy, providing potential applications in the development of ultra-large active area detectors. However, the study on SMSPD is still in its infancy, and the realization of its high-performance and practical use remains an opening question. This study demonstrates a NbN SMSPD with a saturated system detection efficiency (SDE) of ~92.2% at a dark count rate of ~200 cps, a polarization sensitivity of ~1.03, and a minimum timing jitter of ~48 ps, at the telecom wavelength of 1550 nm when coupled with a single mode fiber and operated at 0.84 K. Furthermore, the detector's SDE is over 70% when operated at a 2.1-K closed-cycle cryocooler., Comment: 10 pages,7 figures, 2 tables

Published
2021
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25. A 16-channel fiber array-coupled superconducting single-photon detector array with average system detection efficiency over 60% at telecom wavelength

Author

Zhang, Wei-Jun, Xu, Guang-Zhao, You, Li-Xing, Zhang, Cheng-Jun, Huang, Hao, Ou, Xin, Sun, Xing-Qu, Xiong, Jia-Min, Li, Hao, Wang, Zhen, and Xie, Xiao-Ming

Subjects
Physics - Instrumentation and Detectors, Physics - Optics, Quantum Physics
Abstract

We report a compact, scalable, and high-performance superconducting nanowire single-photon detector (SNSPD) array by using a multichannel optical fiber array-coupled configuration. For single pixels with an active area of 18 um in diameter and illuminated at the telecom wavelength of 1550 nm, we achieved a pixel yield of 13/16 on one chip, an average system detection efficiency of 69% at a dark count rate of 160 cps, a minimum timing jitter of 74 ps, and a maximum count rate of ~40 Mcps. The optical crosstalk coefficient between adjacent channels is better than -60 dB. The performance of the fiber array-coupled detectors is comparable with a standalone detector coupled to a single fiber. Our method is promising for the development of scalable, high-performance, and high-yield SNSPDs., Comment: 8 pages, 12 figures (including Supplementary Material)

Published
2020
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26. Policy Document Analysis of China's Primary-level Public Health Governance System: a Case Study of the Public Health Committee

Author

OU Xin, YANG Jia

Subjects
public health administration, public health committee, grassroots public health, governance system, policy text analysis, Medicine
Abstract

Background In China, the governance of public health by the public health committee, a grassroots mass autonomous organization, is a new approach managing public health services in primary care. Many regions are exploring governance models of public health by the public health committee, aiming to make it a key hub to realize the vertical connection and horizontal linkage grid management of grassroots communities. Objective To analyze the policy documents related to the construction of local public health committees of various regions in China using policy document analysis, so as to provide a reference for improving the primary-level public health governance system and governance capacity. Methods In March 2022, we searched policy documents related to the construction of public health committees on the official websites of the local governments and health commissions of eight sample regions (Beijing, Guangdong, Chongqing, Shandong, Anhui, Guizhou, Gansu, and Ningxia Hui Autonomous Region) in which village (residential) public health committees have been constructed using "public health committee" as the key search term. Through literature review and policy document analysis, an analytical framework for the governance system of the public health committee was constructed. Nvivo 11 Plus was used for word frequency and coding analyses of the included policy literature. Results A total of 15 policy documents and 2 guidance manuals for the work of public health committees were ultimately included. Word frequency analysis showed that the five words, "hygiene" "public" "work" "committee" and "health", appeared most frequently, indicating that the selected policy literature conformed to the research theme. By using the analytical framework, the structural dimensions of the policy literature were determined, including four root nodes, namely, governance subjects, governance mechanisms, institutional guarantees, and capacity building, and 13 sub-nodes. There are 208 reference points for governance subjects, 48 reference points for governance mechanisms, 57 reference points for institutional guarantees, and 87 reference points for capacity building. Conclusion The local policy documents of the sample regions cover the contents of the four dimensions, but have different focuses. According to the framework in this study, further construction of the public health committee needs to set certain admission criteria with clear determination of rights and responsibilities for new committee members, establish an effective cooperation and communication mechanism, improve the system guarantee and provide financial and technical support.

Published
2023
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27. Wafer-scale Heterogeneous Integration of Monocrystalline \b{eta}-Ga2O3 Thin Films on SiC for Thermal Management by Ion-Cutting Technique

Author

Cheng, Zhe, Mu, Fengwen, You, Tiangui, Xu, Wenhui, Shi, Jingjing, Liao, Michael E., Wang, Yekan, Huynh, Kenny, Suga, Tadatomo, Goorsky, Mark S., Ou, Xin, and Graham, Samuel

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

The ultra-wide bandgap, high breakdown electric field, and large-area affordable substrates make \b{eta}-Ga2O3 promising for applications of next-generation power electronics while its thermal conductivity is at least one order of magnitude lower than other wide/ultrawide bandgap semiconductors. To avoid the degradation of device performance and reliability induced by the localized Joule-heating, aggressive thermal management strategies are essential, especially for high-power high-frequency applications. This work reports a scalable thermal management strategy to heterogeneously integrate wafer-scale monocrystalline \b{eta}-Ga2O3 thin films on high thermal conductivity SiC substrates by ion-cutting technique. The thermal boundary conductance (TBC) of the \b{eta}-Ga2O3-SiC interfaces and thermal conductivity of the \b{eta}-Ga2O3 thin films were measured by Time-domain Thermoreflectance (TDTR) to evaluate the effects of interlayer thickness and thermal annealing. Materials characterizations were performed to understand the mechanisms of thermal transport in these structures. The results show that the \b{eta}-Ga2O3-SiC TBC values increase with decreasing interlayer thickness and the \b{eta}-Ga2O3 thermal conductivity increases more than twice after annealing at 800 oC due to the removal of implantation-induced strain in the films. A Callaway model is built to understand the measured thermal conductivity. Small spot-to-spot variations of both TBC and Ga2O3 thermal conductivity confirm the uniformity and high-quality of the bonding and exfoliation. Our work paves the way for thermal management of power electronics and \b{eta}-Ga2O3 related semiconductor devices.

Published
2020

28. Room-temperature coherent control of implanted defect spins in silicon carbide

Author

Yan, Fei-Fei, Yi, Ai-Lun, Wang, Jun-Feng, Li, Qiang, Yu, Pei, Zhang, Jia-Xiang, Gali, Adam, Wang, Ya, Xu, Jin-Shi, Ou, Xin, Li, Chuan-Feng, and Guo, Guang-Can

Subjects
Physics - Applied Physics, Quantum Physics
Abstract

Recently, vacancy-related spin defects in silicon carbide (SiC) have been demonstrated to be potentially suitable for versatile quantum interface building and scalable quantum network construction. Significant efforts have been undertaken to identify spin systems in SiC and to extend their quantum capabilities using large-scale growth and advanced nanofabrication methods. Here we demonstrated a type of spin defect in the 4H polytype of SiC generated via hydrogen ion implantation with high-temperature post-annealing, which is different from any known defects. These spin defects can be optically addressed and coherently controlled even at room temperature, and their fluorescence spectrum and optically detected magnetic resonance spectra are different from those of any previously discovered defects. Moreover, the generation of these defects can be well controlled by optimizing the annealing temperature after implantation. These defects demonstrate high thermal stability with coherently controlled electron spins, facilitating their application in quantum sensing and masers under harsh conditions., Comment: 15 pages, 4 figures

Published
2020

29. Precise tuning of the superconducting properties of Mn-doped Al films for transition edge sensors by ion-implantation

Author

Lv, Yue, Huang, Hao, You, Tiangui, Ren, Feng, Ou, Xin, Gao, Bo, and Wang, Zhen

Subjects
Condensed Matter - Materials Science
Abstract

Magnetic impurities in metallic superconductors are important for both fundamental and applied sciences. In this study, we focused on dilute Mn-doped aluminum (AlMn) films, which are common superconducting materials used to make transition edge sensors (TES). We developed a multi-energy ion-implantation technique to make AlMn films. Compared with frequently used sputtering techniques, ion-implantation provides more precise and reliable control of the Mn doping concentration in the AlMn films.The ion implantation also enables us to quantitatively analyze the superconducting transition temperature curve as a function of the Mn doping concentration. We found that Mn dopants act as magnetic impurities and suppression of superconductivity is counteracted by the antiferromagnetic Ruderman Kittel Kasuya Yosida interaction among Mn dopants. The RKKY interaction can be tuned through defect engineering in the ion-implantation process and through post-implantation annealing., Comment: 15 pages, 5 figures

Published
2020

35. Enhancing intrinsic detection efficiency of superconducting nanowire single-photon detectors via helium ion irradiation

Author

Zhang, Weijun, Jia, Qi, You, Lixing, Ou, Xin, Li, Hao, Zhang, Lu, Wang, Zhen, and Xie, Xiaoming

Subjects
Physics - Applied Physics
Abstract

Realizing an NbN superconducting nanowire single-photon detector (SNSPD) with a 100% intrinsic detection efficiency (IDE) at the near-infrared wavelengths is still challenging. Herein, we developed a post-processing method to increase the IDE of NbN SNSPDs to near unity using a 20 keV helium ion irradiation. The IDE enhancement was achieved owing to the ion-induced reduction of the superconducting energy gap and the electron density of states at the Fermi level, determined with the electrical and magnetic transport measurements. The change in optical absorptance of the irradiated SNSPD was negligible as confirmed by the measured optical reflectance and system detection efficiency (SDE). Benefited with the IDE enhancement, the SDE of an irradiated device was significantly increased from 49% to 92% at 2.2 K for a 1550 nm wavelength., Comment: 5 pages, 2 figures, 2 tables

Published
2018
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