Session Chairs: Bingyang Liu, Chen Tian, Chenren Xuĭesigning SmartNIC-accelerated TCP stacksĪccelerating Distributed Systems with In-Network Computing Yicheng Feng, Shihao Shen (Tianjin University) Cheng Zhang (Tianjin University of Finance and Economics) Xiaofei Wang (Tianjin University) Quicklayer: A Layer-stack-oriented Accelerating Middleware for Fast Deployment in Edge Clouds Youngmin Choi, Junghan Yoon (KAIST) YoungGyoun Moon (Samsung Research) KyoungSoo Park (KAIST) Is large MTU beneficial to cellular core networks? Yeonho Yoo (Korea University & Microsoft Research) Zhixiong Niu (Microsoft Research) Chuck Yoo (Korea University) Peng Cheng, Yongqiang Xiong (Microsoft Research)įlexCore: Leveraging XDP-SCTP for Scalable and Resilient Network Slice Service in Future 5G Corīhavishya Sharma, Shwetha Vittal, A Antony Franklin (IIT Hyderabad) SegaNet: An Advanced IoT Cloud Gateway for Performant and Priority-Oriented Message Delivery Heuristic Binary Search: Adaptive and Fast IPv6 Route Lookup with Incremental Updatesĭonghong Jiang, Yanbiao Li, Yuxuan Chen (CNIC CAS UCAS, China) Jing Hu, Yi Huang (Huawei Technologies Co., Ltd.) Gaogang Xie (CNIC CAS UCAS, China) Shuyuan Zhang, Shu Shan, Shizhen Zhao (Shanghai Jiao Tong University) Reducing Reconfiguration Time in Hybrid Optical-Electrical Datacenter Networks Rulan Yang, Xing Fang, Lizhao You, Qiao Xiang, Hanyang Shao, Gao Han, Ziyi Wang, Zhihao Zhang, Jiwu Shu (Xiamen University) Linghe Kong (Shanghai Jiao Tong University) Huisan Xu, Qiuyue Qin, Xing Fang, Qiao Xiang, Jiwu Shu (Xiamen University)ĭiagnosing Distributed Routing Configurations Using Sequential Program Analysis Toward Privacy-Preserving Interdomain Configuration Verification via Multi-Party Computation Xizheng Wang (Tsinghua University) Shuai Wang (Zhongguancun Laboratory) Dan Li (Tsinghua University) SRDMA: A General and Low-Overhead Scheduler for RDMA Zilong WANG, Xinchen WAN, Chaoliang ZENG, Kai CHEN (HKUST) Host Efficient Networking Stack Utilizing NIC DRAMīyeongKeon Lee, DongHyeon Lee, Jisu Ok, Wonsup Yoon, Sue Moon (KAIST)Īccurate and Scalable Rate Limiter for RDMA NICs Haibo Chen, Distinguished Professor of Shanghai Jiao Tong University IEEE FellowįastWake: Revisiting Host Network Stack for Interrupt-mode RDMAīojie Li, Zihao Xiang (Huawei) Xiaoliang Wang (Nanjing University) Han Ruan, Jingbin Zhou, Kun Tan (Huawei) Microsecond-scale Datacenter Computing with RDMA: Characterization, Optimization and Outlooking Program Chairs: Chuanxiong Guo, Arvind Krishnamurthy An improved energy density of 103.8 W h kg −1 is reached via the designed microstructure of the high entropy oxide electrode.Technical Program APNET 2023 Program Meeting (Tentative), in Beijing time Session Time Keynote Talk The specific capacitance is 332.2 F g −1 at a current density of 0.3 A g −1 in 1 M KOH electrolyte with a wide potential window of (−1, 0.6). The spinel-phase (FeCoCrMnNi) 3O 4 with a high specific surface area of 63.1 m 2 g −1 was prepared at a low calcination temperature of 450 ☌. The calcination temperature affects the structural morphology and crystallinity of the high entropy oxides and thus also affects the electrochemical performance. Transition metal elements Fe, Co, Cr, Mn and Ni were selected for their electrochemical activity, and high entropy oxides were prepared by a sol–gel method under different calcination temperatures. ![]() ![]() We tried to increase the energy density while increasing the specific capacitance of high entropy oxides from the potential window. However, there is still the problem of their low energy density. Previous studies have found that high entropy oxides can be used as electrode materials for supercapacitors.
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