反饋

李勁鋒

李勁鋒，東方鋼琴少年，首屆國際非職業鋼琴比賽青年組國際亞軍，擅長即興演奏跨時代感的新世紀音樂^[1] 。代表作有：鋼琴原創專輯《慕尼黑車站》^[141] 《國王十字》原創英倫古典鋼琴新民謠專輯^[142] 、鋼琴即興編曲《聖母瑪利亞之淚》^[2] 《華語情歌串燒》^[3] 《風雲雄霸天下鋼琴組曲》^[4] 《神探狄仁傑》^[5] 《東方鋼琴連奏》《最終幻想鋼琴合集》《Flower Dance》《大魚·海棠》^[6] 《還珠格格鋼琴組曲》^[7] 《周星馳鋼琴組曲》^[8] 《薛之謙鋼琴串燒》《中華小當家鋼琴組曲》^[9-10] ^[11] 《鋼琴遇見紅樓夢》^[110] 等，被譽為“無心插柳”的鋼琴王子^[12-13] 。本科畢業於華中科技大學電氣工程及其自動化專業，碩士畢業於劍橋大學核能研究中心，博士畢業於劍橋大學先進光子學與電子技術中心^[14-15] ，Cambridge Overseas Trust 獎學金獲得者^[16] 。

本名: 李勁鋒
外文名: Jinfeng LI
民族: 漢族
國籍: 中國
出生地: 廣東省茂名市
出生日期: 1991年4月
畢業院校: 華中科技大學伯明翰大學劍橋大學
星座: 金牛座

代表作品

跨時代鋼琴走心即興串燒

職業

鋼琴家學者

主要成就

首屆澳門國際青少年鋼琴賽金獎第一名
首屆國際非職業鋼琴比賽亞軍
英國工程技術協會IET Prize獲得者
Cambridge Trust Scholar
AP Jarvis Prize 展開

主要成就: 首屆澳門國際青少年鋼琴賽金獎第一名
首屆國際非職業鋼琴比賽亞軍
英國工程技術協會IET Prize獲得者
Cambridge Trust Scholar
AP Jarvis Prize
IEEE會議最佳論文獎
英國物理學會 Institute of Physics - Journal of Physics 會議最佳論文獎
計算新興技術年鑑高被引文章獎 AETiC Highly Cited Article Award 2023^[165]
2023年入選國家級青年人才^[170] 收起

別名

Cambridge李勁鋒

李勁鋒研究領域

李勁鋒劍橋大學研究生畢業典禮

液晶微波毫米波相控陣天線、超級計算機核反應堆蒙特卡洛模擬^[17] 、信息論、鋼琴^[12] ^[18] 、混合動力汽車逆變器^[19] 、核反應堆熱工水力測控^[157] 。

主講課程: 本科生必修課《ECE學科前沿與進展》、選修課《賦能6G：液晶毫米波技術前沿》^[173] 。

李勁鋒學習經歷

廣東省茂名市第一中學.

華中科技大學電氣工程及其自動化工學學士.

英國伯明翰大學電子與電氣工程一級榮譽學士學位^[20] .

英國劍橋大學核能工程碩士^[21] .

英國劍橋大學液晶微波毫米波電子工程博士^[22-23] .

李勁鋒劍橋大學(3張)

李勁鋒學術獲獎

Arthur Jarvis Prize (AP Jarvis Undergraduate Prize) at the University of Birmingham in 2013^[22] .

英國工程技術協會 IET prize awarded by TRW Automotive^[24] , 混合動力汽車研究獲美國TRW公司頒獎^[25] .
2023年榮獲計算新興技術年鑑高被引文章獎 (AETiC Highly Cited Article Award 2023)^[165] .
IEEE會議最佳論文獎 Best Paper Award for the 3rd IEEE International Conference on Computing, Electronics & Communications Engineering 2020^[26] .

英國物理學會 Institute of Physics - Journal of Physics 會議最佳論文獎 2021^[89] .

擔任IEEE第27屆天線與傳播國際研討會“新傳輸線/結構”分會主席: Session Chair of IEEE ISAP (27th International Symposium on Antennas and Propagation)^[109] .
擔任2023年中國微波周IEEE第15屆國際微波毫米波技術會議“無源器件/電路” 分會主席: Session Chair of IEEE 15th International Conference on Microwave and Millimeter Wave Technology (ICMMT 2023)^[156] .
擔任第五屆全國太赫茲科學技術青年年會暨中國國際太赫茲青年論壇太赫茲探測及檢測技術分論壇主席^[182]
主編專著《Advances in Sentiment Analysis - Techniques, Applications, and Challenges》(ISBN: 978-0-85014-061-3)^[175]
Session chair for IEEE IOTSMS - SNAMS 2019^[27] .
Technical Program Committee for SOTICS 2020^[28] , Computing Conference 2020 & 2021^[29] , IntelliSys 2020^[30] , and FICC 2021^[31] .
Topic Editor & Guest Editor^[88] for Crystals (Impact Factor: 2.67. Science Citation Index Expanded)^[32] .
Editorial Board for Medicine® (Impact Factor: 2.133. Science Citation Index)^[33] .

Editorial Board of Nuclear Energy for Frontiers in Energy Research (Impact Factor: 3.858. Science Citation Index Expanded).

Reviewer for more than 20 journals indexed in SCI/EI/Scopus^[34] . Top 1% reviewer on Publons^[84] .
中國通信學會高級會員: Senior Member of China Institute of Communications (CIC)

擔任權威期刊審稿人：Nature - npj Digital Medicine (影響因子: 15.357)，IEEE Transactions on Power Electronics 等^[90] .
擔任英國牛頓獎基金項目評審：Newton Prize (£1m fund) reviewer for the UK National Commission for UNESCO^[35] .
擔任英國國家衞生研究院（NIHR）健康與社會護理交付研究（HSDR）基金項目評審：Grants reviewer for Health and Social Care Delivery Research (HSDR) fund from National Institute for Health Research (NIHR).

引力波講壇李勁鋒與霍金

李勁鋒劍橋大學核能工程研究生學位授予

李勁鋒藝術履歷

2004年首屆澳門國際青少年鋼琴大賽少年組國際第一名^[18] .

2004年13歲舉辦鋼琴獨奏會，演奏舒伯特《流浪者幻想曲》，肖邦《平穩的行板與華麗的大波蘭舞曲》，格什温《藍色狂想曲》，格林卡《夜鶯》^[18] ，李斯特-帕格尼尼練習曲《鍾》《唐璜的回憶》等.

2009年加入華中科技大學藝術團鋼琴鍵盤隊，

2009年首屆國際非職業鋼琴比賽青年組國際亞軍^[36-37] ，獎金1500美元.

2009-2012年在華中科技大學【鍵上人生】及【青春琴緣】系列音樂會演奏《練聲曲》《社員都是向陽花》《託卡塔與賦格》《諾基亞鈴聲變奏曲》《鳥之詩》《加勒比海盜》《忐忑》等.

2011年3月《東方音樂精選輯》《初音未來鋼琴二次創作輯》.

2011年5月受邀武漢琴台音樂廳演奏自己改編的《鳥之詩》，與鋼琴家沈文裕同台演出.

2013年10月劍橋大學 Selwyn College Hall演出：《社員都是向陽花》《平湖秋月》^[38] ，為女高音歌唱家伴奏《黃河怨》^[39] 《康定情歌》^[40] 《秋之歌》^[41] 《江河水》^[42] .

2013年12月劍橋大學Hughes Hall演出：《拉赫瑪尼諾夫練聲曲》^[38] 《皮亞佐拉探戈Oblivion》^[1] .

2014年6月劍橋大學Hughes Hall演出：《肖邦英雄波羅乃茲舞曲》^[43]

2014年8月劍橋大學Hughes Hall舉辦中國古典音樂會^[44] ：《黃河鋼琴協奏曲》^[45] 《梁祝小提琴協奏曲》《彩雲追月》^[46] 《風居住的街道》^[47] 《那就是我》^[48] 《牧歌》^[49] 《偶然》^[50] 《踏雪尋梅》^[51] 《我住長江頭》^[52] 《一杯美酒》^[53] 《望春風》^[54] .

2014年10月首次與劍橋大學交響樂團 Cambridge Graduate Orchestra ^[55] 合作排練蕭邦第一鋼琴協奏曲.

2014年11月劍橋大學Lee Hall演出：蕭邦《平穩的行板與華麗的大波蘭舞曲》^[56] .

2015年1月起擔任劍橋大學Wolfson Chamber Singers （沃夫森學院室內樂合唱團）鋼琴伴奏^[57]

2015年2月劍橋大學春晚The Cambridge Chinese New Year Gala^[58] 鋼琴伴奏

2015年3月劍橋大學Lent Term Concert^[59] 演奏 Arabesque No.1 (第一號阿拉貝斯克)

2016年1月劍橋大學皮亞佐拉與肖邦作品音樂會^[60]

2016年3月 West Road Concert Hall: 在劍橋大學華樂團年度音樂會首演《人生若只如初見》^[93]

2017年1月倫敦威斯敏斯特中央大廳 (Central Hall Westminster) 全英春晚鋼琴薩克斯合奏《秋意濃》^[61]

2018年11月 Robinson College Chapel：劍橋大學華樂團年度音樂會演奏《還珠格格鋼琴組曲》

2019年1月 Cambridge Corn Exchange：劍橋大學豬年春晚演奏《紅豬》當鋼琴遇上薩克斯

2019年3月劍橋大學李勁鋒鋼琴獨奏會^[62]

2019年11月 Robinson College Chapel：劍橋大學華樂團年度音樂會演奏《風雲雄霸天下鋼琴組曲》^[63] .

2019年12月華中科技大學鍵盤隊建隊20週年校友音樂會《英雄波蘭舞曲》

2022年2月受邀在 CCTV全球愛華詩歌春晚、英國浙江會春晚、劍橋華人社區中心春晚、英國華人女性聯盟元宵晚會等鋼琴演奏

2022年2月受邀倫敦市政廳演奏《紅樓夢》《我的中國心》《鐵血丹心》等，央視CGTN全程直播^[92]

2022年3月 West Road Concert Hall: 在劍橋大學華樂團年度音樂會首演《外來媳婦本地郎鋼琴組曲》

2022年6月倫敦中國城: 受邀在英國女王登基70週年盆菜宴上鬥琴《當神探夏洛克遇上外來媳婦本地郎》^[99]

2022年10月倫敦St Gabriel's Pimlico: 李勁鋒個人十年作品鋼琴音樂會^[102]

2017年-2023年，發行原創鋼琴曲專輯：《The last minute flight》^[145] 《扎心老鐵》^[146] 《慕尼黑車站》^[143] 《鋼鐵銀河廣場》^[154] 《貝克街雪茄》^[155] 《光》^[153] 《輓歌》^[144] 《時間情話》^[150] 《你是否記得》^[151] 《孤勇》^[152] 《夢迴東山坡村》^[147] 《訣別之扉》^[148] 《宇稱不守恆》^[149] 《波粒二象性》^[162] 《硅基生命》^[160] 《室温超導》^[161] 《幽靈粒子》^[163] 《誓的三重境界》^[171] 等.

李勁鋒新聞報道

《歐洲時報》2022年10月21日僑界新聞：李勁鋒“東方鋼琴幻想”倫敦音樂會舉行^[120]
《揚子晚報》2022年11月01日 A03版：他在倫敦街頭即興彈奏中國經典^[121]
《揚子晚報》紫牛新聞 2022年10月31日：在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學博士^[123]
《南方都市報》2022年11月11日 A16 版：把家鄉和祖國的聲音傳播到天涯海角是他的使命^[133]
《南方都市報》2022年11月06日：對話倫敦街頭彈琴走紅的廣東博士：傳播家鄉的聲音是他的使命^[125]
《南方都市報》南都即時2022年11月7日：廣東籍劍橋博士倫敦街頭奏響中國樂曲。稱傳播家鄉聲音很自豪^[124]
《中央廣播電視總枱粵港澳大灣區之聲》2022-11-10：獲百萬點贊。廣東90後博士在國外街頭做了這件事^[135]
《中國經濟網》^[134] 《楚天都市報》^[126] ：劍橋博士倫敦街頭彈琴獲贊無數：生活還有詩和遠方
"在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學博士" 相關報道刊登在新華報業網 ^[122] 揚子晚報網^[127] 騰訊新聞^[136] 湖北網絡廣播電視台^[128] 中國新聞網^[129] 中國僑網^[130] 澎湃新聞^[131] 中國青年網^[132]
南方網, 【60週年校慶專欄】校友風采 | 李勁鋒 2019-06-25^[112]
《鋼琴藝術》2010年第4期, 55-57頁, "讓音樂擁抱世界——首屆“海泰杯”國際非職業鋼琴比賽賽後感".^[111]
“國際鋼琴賽學子獲佳績,” 華中科技大學校報《華中科技大學週報》第341期第2版^[113] ，華中科技大學新聞網^[179]
華中科技大學校報《華中科技大學週報》第348期第3版李勁鋒———"無心插柳”的鋼琴王子," ^[114] .
華中科技大學校報 "人生的拉普拉斯變換," 中國高校報網，8 Nov. 2010^[115]
"Lunchtime Concert: Jinfeng Li piano recital," Wolfson College University of Cambridge News, Mar. 2019^[116]
"The Newsletter of Wolfson College Cambridge," page 8, Issue 18, Spring 2015^[117]
"St Edmund's Alumni Festival Event 2016," St Edmund's College University of Cambridge News, 24 Sept. 2016^[118]
"Chinese Music on a Summer's Evening," Hughes Hall University of Cambridge News, 13 Aug. 2014^[119]
"EESE students win IET awards," University of Birmingham News, 29 Apr. 2013^[19]

李勁鋒出版物

電子工程/核工程論文/專著節選

[1] J. Li and D. Chu, “Liquid crystal-based enclosed coplanar waveguide phase shifter for 54–66 GHz applications,” Crystals, vol. 9, 12, 650, December 2019. doi: 10.3390/cryst9120650^[64]

[2] A. Yontem, J. Li, and D. Chu, “Imaging through a projection screen using bi-stable switchable diffusive photon sieves,” Optics Express, vol. 26, pp. 10162–10170, April 2018. doi: 10.1364/OE.26.010162^[65]

[3] J. Li, “All-optically Controlled Microwave Analog Phase Shifter with Insertion Losses Balancing,” Engineering Letters, vol. 28, no. 3, pp. 663–667, 2020.^[67]

[4] J. Li and H. Li, “Modeling 0.3 THz Coaxial Single-Mode Phase Shifter Designs in Liquid Crystals with Constitutive Loss Quantifications,” Crystals, vol. 14, 4, 364, April 2024.^[183]

[5] J. Li, “Tunability Dependence of All-Optical Liquid Crystal Delay Line on Laser Polarization and Incidence Angle,” Photonics Letters of Poland, vol. 15, no. 4, pp. 51–53, Dec. 2023. doi:10.4302/plp.v15i4.1234^[177]

[6] J. Li, “Challenges and Opportunities for Nematic Liquid Crystals in Radio Frequency and Beyond,” Crystals, vol. 12, 5, 632, April 2022. doi: 10.3390/cryst12050632^[94]

[7] J. Li, Y. Seki, K. V. Rajan, M. A. Ayu, A. H. Muhendra, S. A. Thabit, K. Kyritsis, N. Spatiotis, I. Perikos, and M. Paraskevas, "Advances in Sentiment Analysis - Techniques, Applications, and Challenges,” Book Editor: Jinfeng Li. IntechOpen, ISBN: 978-0-85014-061-3, ISSN: 2633-1403. January 2024. doi:10.5772/intechopen.111293^[175] (主編學術專著叢書)

[8] J. Li, “Rethinking Liquid Crystal Tunable Phase Shifter Design with Inverted Microstrip Lines at 1–67 GHz by Dissipative Loss Analysis,” Electronics, vol. 12, 2, 421, January 2023. doi: 10.3390/electronics12020421^[139]

[9] J. Li, “Taking Flow Characterization to New Heights by Fiber Bragg Gratings Array,” Energies, vol. 16, 10, 4218, May 2023. doi: 10.3390/en16104218^[157]

[10] J. Li, “Vulnerabilities Mapping based on OWASP-SANS: A Survey for Static Application Security Testing (SAST),” Annals of Emerging Technologies in Computing (AETiC), Print ISSN: 2516-0281, Online ISSN: 2516-029X, pp. 1-8, vol. 4, no. 3, 1st July 2020. doi: 10.33166/AETiC.2020.03.001^[68]

[11] J. Li and H. Li, “Liquid Crystal-Filled 60 GHz Coaxially Structured Phase Shifter Design and Simulation with Enhanced Figure of Merit by Novel Permittivity-Dependent Impedance Matching,” Electronics, vol. 13, no. 3, 626, February 2024. doi: 10.3390/electronics13030626^[178]

[12] H. Plows, J. Li, M. Dahlfors, and M. Margulis, “Flow Characterisation Using Fibre Bragg Gratings and Their Potential Use in Nuclear Thermal Hydraulics Experiments,” Journal of Nuclear Engineering, vol. 4, no. 4, pp. 668–690, October 2023. doi: 10.3390/jne4040042^[167]

[13] J. Li, “From Liquid Crystal on Silicon and Liquid Crystal Reflectarray to Reconfigurable Intelligent Surfaces for Post-5G Networks,” Applied Sciences, vol. 13, 13, 7407, June 2023. doi: 10.3390/app13137407^[159]

[14] L. Cai, H. Xu, J. Li, and D. Chu, “High figure-of-merit compact phase shifters based on liquid crystal material for 1–10 GHz applications,” Japanese Journal of Applied Physics, vol. 56, 011701, November 2017. doi: 10.7567/JJAP.56.011701^[66]

[15] J. Li, “Millimetre-wave beam steering with analog-resolution and minimised distortion based on liquid crystals tunable delay lines with enhanced signal-to-noise ratios,” Proc. SPIE, Millimetre Wave and Terahertz Sensors and Technology XIII, 115410H, September 2020. doi: 10.1117/12.2570001^[69]

[16] J. Li, “Monte Carlo Investigation of the UK’s First EPR Nuclear Reactor Startup Core using Serpent,” Energies, vol. 13, 19, 5168, October 2020. doi: 10.3390/en13195168^[103]

[17] J. Li, “Will ‘Liquid-Crystal-Based Floating-Electrode-Free Coplanar Waveguide Phase Shifter With an Additional Liquid-Crystal Layer for 28-GHz Applications’ Work?” Engineering Letters, vol. 31, no. 2, pp. 820–824, 2023.^[158]

[18] J. Li, “Rethinking Figure-of-Merits of Liquid Crystals Shielded Coplanar Waveguide Phase Shifters at 60 GHz,” J, vol. 4, pp. 444–451, August 2021. doi: 10.3390/j4030034^[96]

[19] J. Li, “An Efficient Mixed-signal Dielectric-partitioning Model of Liquid Crystals based Shielded Coplanar Waveguide for Electronically Reconfigurable Delay Lines Design,” Proc. SPIE, Integrated Optics: Design, Devices, Systems and Applications VI, vol.11775, 1177519, April 2021. doi: 10.1117/12.2593624^[85]

[20] J. Li, “Towards 76-81 GHz Scalable Phase Shifting by Folded Dual-strip Shielded Coplanar Waveguide with Liquid Crystals,” Annals of Emerging Technologies in Computing (AETiC), vol. 5, no. 4, pp. 14–22, October 2021. doi: 10.33166/AETiC.2021.04.002^[95]

[21] J. Li, “Low-loss tunable dielectrics for millimeter-wave phase shifter: from material modelling to device prototyping,” IOP Conference Series: Materials Science and Engineering, vol. 892, 012057, 2020. doi: 10.1088/1757-899x/892/1/012057 ^[78]

[22] J. Li, “Modelling nuclear fuel assembly with thermal-hydraulic feedback and burnup using WIMS-PANTHER-Serpent,” Journal of Physics: Conference Series, vol. 1603, 012012, 2020. doi: 10.1088/1742-6596/1603/1/012012^[104]

[23] J. Li, “Performance Limits of 433 MHz Quarter-wave Monopole Antennas due to Grounding Dimension and Conductivity,” Annals of Emerging Technologies in Computing (AETiC), vol. 6, no. 3, pp. 1–10, July 2022. doi: 10.33166/AETiC.2022.03.001^[100]

[24] J. Li, “60 GHz 0-360˚ Passive Analog Delay Line in Liquid Crystal Technology based on a Novel Conductor-backed Fully-enclosed Coplanar Waveguide,” IEEE 72nd Electronic Components and Technology Conference (ECTC), San Diego, USA, 2022, pp. 1841–1846. doi: 10.1109/ECTC51906.2022.00289^[101]

[25] J. Li, H. Xu, and D. Chu, “Design of liquid crystal based coplanar waveguide tunable phase shifter with no floating electrodes for 60–90 GHz applications,” 46th European Microwave Conference (EuMC), London, 2016, pp. 1047–1050. doi: 10.1109/EuMC.2016.7824526^[71]

[26] J. Li, “Wideband PCB-to-Connectors Impedance Adapters for Liquid Crystal-Based Low-Loss Phase Shifters,” 50th European Microwave Conference (EuMC), Utrecht, Netherlands, 2021, pp. 546–549. doi: 10.23919/EuMC48046.2021.9337967^[79]

[27] J. Li, “Managing 60 GHz Field Peaking of an Liquid Crystal Enclosed Coplanar Waveguide by Core Edge Shaping,” 2020 IEEE 32nd Asia-Pacific Microwave Conference (APMC), Hong Kong, 2020, pp. 403–405. doi: 10.1109/APMC47863.2020.9331555^[74]

[28] J. Li, “Optically Steerable Phased Array Enabling Technology Based on Mesogenic Azobenzene Liquid Crystals for Starlink Towards 6G,” 2020 IEEE 32nd Asia-Pacific Microwave Conference (APMC), Hong Kong, 2020, pp. 345–347. doi: 10.1109/APMC47863.2020.9331345^[75]

[29] J. Li, “Figure-of-Merits Mismatch in Liquid Crystals mmWave Phase Shifters,” IEEE 46th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz), 2021. pp. 1–2. doi: 10.1109/IRMMW-THz50926.2021.9567615^[87]

[30] J. Li, “Bias Tees Integrated Liquid Crystals Inverted Microstrip Phase Shifter for Phased Array Feeds,” IEEE EPS 21st International Conference on Electronic Packaging Technology (ICEPT), Guangzhou, 2020, pp. 1–5. doi: 10.1109/ICEPT50128.2020.9202604^[73]

[31] J. Li, “60 GHz Optimised Nickel-free Gold-plated Enclosed Coplanar Waveguide Liquid Crystal Phase Shifter,” 2020 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP), Suzhou, China, 2020, pp. 1–3. doi: 10.1109/IMWS-AMP49156.2020.9199680^[72]

[32] J. Li, “79 GHz Meandering Enclosed-Coplanar Variable Delay Lines in Liquid Crystals Encapsulated Within Independent and Shared Cavities,” IEEE 27th International Symposium on Antennas and Propagation (ISAP), Sydney, Australia, 2022, pp. 457–458, doi: 10.1109/ISAP53582.2022.9998660^[137] （擔任分會主席）

[33] L. Cai, H. Xu, J. Li, and D. Chu, “High FoM liquid crystal based microstrip phase shifter for phased array antennas,” IEEE 21st International Symposium on Antennas and Propagation (ISAP), Okinawa, 2016, pp. 402–403.^[80]

[34] J. Li, “Design and Control Optimisation of a Novel Bypass-embedded Multilevel Multicell Inverter for Hybrid Electric Vehicle Drives,” IEEE 11th International Symposium on Power Electronics for DistributedGeneration Systems (PEDG), Dubrovnik, 2020. pp. 382–385. doi: 10.1109/PEDG48541.2020.9244313^[77]

[35] J. Li, “Hybrid Propulsion Motor Drives Model based on Multi-level Inverters with Optimised Fuel Economy,” IEEE Vehicular Power and Propulsion Conference (IEEE VPPC), Gijón, Spain, 2020, pp. 1–5. doi: 10.1109/VPPC49601.2020.9330818^[83]

[36] J. Li, “Novel Partially-Shielded Coplanar Waveguide with Metasurfaces for Liquid Crystals Tunable Delay Lines Beyond 67 GHz,” 2022 IEEE Conference on Antenna Measurements & Applications (IEEE CAMA), Guangzhou, China, 2022, pp. 1–4, doi: 10.1109/CAMA56352.2022.10002683^[138]

[37] J. Li, “Computational Perturbation Methods for Moderator and Doppler Temperature Coefficients in the European Pressurised Reactor Core Analysis,” 3rd IEEE International Conference on Computer, Electrical & Communication Engineering (IEEE ICCECE), Southend, 2020, pp. 201–204. doi: 10.1109/iCCECE49321.2020.9231053^[105]

[38] J. Li, “Multi-ring Subgroup Method in Characterising Highly Self-shielded Gadolinia Burnable Poison Pins for the UK EPR Nuclear Fuel Assembly,” 3rd IEEE International Conference on Computer, Electrical & Communication Engineering (IEEE ICCECE), Southend, 2020, pp. 196–200. doi: 10.1109/iCCECE49321.2020.9231157^[106]

[39] J. Li, “Performance Limits of Liquid Crystals Coplanar Phase Shifters beyond 60 GHz due to Fabrication,” IEEE International Conference on Computing, Networking, Telecommunications &Engineering Sciences Applications 2020 (IEEE CoNTESA), Tirana, Albania, 2020, pp. 21–26. doi: 10.1109/CoNTESA50436.2020.9302865^[108]

[40] J. Li, “Power Peaking, Critical Boron, and Shutdown Margin Benchmark of the UK Hinkley Point C EPR using WIMS-PANTHER Deterministic Codes,” IEEE International Conference on Computing, Networking, Telecommunications & Engineering Sciences Applications 2020 (IEEE CoNTESA), Tirana, Albania, 2020, pp. 1–4. doi: 10.1109/CoNTESA50436.2020.9302867^[107]

[41] J. Li, “Machine Learning and Digital Twinning Enabled Liquid Crystals mm-Wave Reconfigurable Devices Design and Systems Operation,” 2022 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP), Guangzhou, China, 2022, pp. 1–3. doi: 10.1109/IMWS-AMP54652.2022.10107046^[140]

[42] J. Li, “Experimental Characterization of Patterned Electrodes and Shaped Substrates for A Liquid Crystals Phase Shifter at V Band,” IEEE 15th International Conference on Microwave and Millimeter Wave Technology (ICMMT), Qingdao, China, 2023, pp. 1–3. doi: 10.1109/ICMMT58241.2023.10277064^[166]

[43] J. Li, “Design Margin of Millimeter-wave Ultra-wideband 0-180° Analog Delay Line with Insertion Loss Less Than 2 dB,” 2023 16th UK-Europe-China Workshop on Millimetre Waves and Terahertz Technologies (UCMMT), Guangzhou, China, 2023, pp. 1–3. doi: 10.1109/UCMMT58116.2023.10310430^[169]

[44] J. Li, “Dissipative Analysis of Liquid Crystal-loaded Passive Reconfigurable Transmission Line Components with Filled Vias at 60 GHz,” IEEE MTT-S International Conference on Numerical Electromagnetic and Multiphysics Modeling and Optimization (NEMO), Winnipeg, Canada, 2023, pp. 48–50. doi: 10.1109/NEMO56117.2023.10202478^[164]

[45] J. Li, H. Li, “Impedance Characterization for Liquid CrystalTunable Coaxial Transmission Lines at 60 GHz,” 2023 Cross Strait Radio Science and Wireless Technology Conference (CSRSWTC 2023), Guilin, China, February 2024, pp. 01–03. doi: 10.1109/CSRSWTC60855.2023.10426867^[180]

[46] J. Li, “Towards Fabrication of High-tuning-range Liquid Crystals High-aspect-ratio Coplanar Waveguide Phase Shifter by LIGA, DRIE and Laser Ablation,” 2023 Cross Strait Radio Science and Wireless Technology Conference (CSRSWTC 2023), Guilin, China, February 2024, pp. 1–3. doi: 10.1109/CSRSWTC60855.2023.10427011^[181]

[47] J. Khatry, J. Li, M. Margulis, M. Dahlfors, J. Corre, H. Prasser, “Light Water Reactor Thermal Hydraulics Facility Development in North Wales,” 19th International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-19), March 2022.^[98] (第十九屆國際核反應堆熱工水力大會)

[48] M. Dahlfors, J. Khatry, M. Margulis, H. Plows, J. Li, S. Middleburgh, I. Marshall, M. Rushton and W. Lee, “Open-access water thermal hydraulics facility development in North Wales,” Proceedings of the 17th UK Heat Transfer Conference (UKHTC 2021), April 2022.^[97]

[49] J. Li, “Optically Inspired Cryptography and Cryptanalysis: A Survey and Research Directions,” Emerging Technologies in Computing, Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering (LNICST), Springer, 2020, vol. 332, pp. 98–110. ISBN: 9783030600358. doi: 10.1007/978-3-030-60036-5_7^[70]

[50] J. Li and X. Guo, “COVID-19 Contact-tracing Apps: A Survey on the Global Deployment and Challenges,” arXiv preprint arXiv:2005.03599, 2020. ^[81] （被PNAS 美國國家科學院院刊引用^[86] , 收到 MIT Technology Review《麻省理工科技評論》採訪邀請）

[51] J. Li, “Impact of laser polarization and angle of incidence on phase shifting efficacy of an all-optically addressed liquid crystal delay line at X band,” Proc. SPIE, SPIE/COS Photonics Asia, Optoelectronic Devices and Integration XII, vol.12764, 127640X, November 2023. doi: 10.1117/12.2685859^[172]

[52] J. Li and X. Guo, “Global Deployment Mappings and Challenges of Contact-tracing Apps for COVID-19,” SSRN Electronic Journal, May 2020. doi: 10.2139/ssrn.3609516 ^[82] （被The Lancet Public Health《柳葉刀-公共衞生》引用^[91] ）

[53] X. Guo and J. Li*, “A Novel Twitter Sentiment Analysis Model with Baseline Correlation for Financial Market Prediction with Improved Efficiency,” IEEE 6th International Conference on Social Networks Analysis, Management and Security (SNAMS), Granada, Spain, 2019, pp. 472-477. doi: 10.1109/SNAMS.2019.8931720^[76] （擔任分會主席）

[54] J. Li, “Physics-Informed Machine Learning Assisted Liquid Crystals µWave Phase Shifters Design and Synthesis,” Emerging Technologies in Computing, Lecture Notes of the Institute for Computer Sciences, Social Informatics and Telecommunications Engineering (LNICST), Springer Nature, 2023, vol. 538, pp. 3–13. ISBN: 9783031502149. doi: 10.1007/978-3-031-50215-6_1^[174]

[55] J. Li, "Introductory Chapter: The 2023 Sentiment Analysis Roadmap,” in: Advances in Sentiment Analysis - Techniques, Applications, and Challenges, Book Editor: Jinfeng Li. IntechOpen, ISBN: 978-0-85014-061-3, ISSN: 2633-1403. January 2024. doi:10.5772/intechopen.112276^[176]

[56] H. Plows, M. Margulis, and J. Li, “3D Imaging of Phase Structures Using Fibre Bragg Grating Grid Sensors,” 20th International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-20), American Nuclear Society (ANS), Washington, D.C., August 2023, pp. 2944–2944. doi: 10.13182/NURETH20-40208^[168] (第二十屆國際核反應堆熱工水力大會)

參考資料

1. Rehearsal of Astor Piazzolla's Tango in Cambridge ．youku[引用日期2013-12-14]
2. Ave Maria 《聖母瑪利亞之淚》纖指滑過靈魂的憂傷．youku[引用日期2015-09-01]
3. 劍橋華樂團 2016年春音樂會李勁鋒．youku[引用日期2016-03-27]
4. 鋼琴版真愛你的雲《風雲雄霸天下》步驚雲組曲．youku[引用日期2016-03-27]
5. 神探狄仁傑劍橋走心鋼琴版 - 閣老，您怎麼看．youku[引用日期2016-03-27]
6. 動畫電影《大魚·海棠》純鋼琴印象曲《大魚》劍橋大學唯美鋼琴獨奏．秒拍[引用日期2016-06-16]
7. 還珠格格鋼琴組曲,好燃！．秒拍[引用日期2016-08-20]
8. 周星馳鋼琴組曲 : 賭神+少林足球+賭俠II之上海灘賭聖+國產凌凌漆劍橋鋼琴串燒．秒拍[引用日期2016-09-24]
9. 中華小當家-中華一番！鋼琴全集 piano by Cambridge李勁鋒．bilibili[引用日期2018-11-14]
10. 鋼琴串燒薛之謙【醜八怪+認真的雪+演員】🎹前奏融化了．秒拍[引用日期2016-08-20]
11. 薛之謙走心鋼琴串燒【你還要我怎樣 + 演員 + 剛剛好】聽前奏就美哭了… ．秒拍[引用日期2016-08-21]
12. 人物: 李勁鋒：“無心插柳”的鋼琴王子．中國校媒網[引用日期2013-05-29]
13. 李勁鋒：“無心插柳”的鋼琴王子．華中科技大學新聞網．2010-01-01[引用日期2018-05-18]
14. A concert in Hughes Hall, Cambridge ．youku[引用日期2014-04-11]
15. 劍橋大學金秋音樂會節選社員都是向陽花平湖秋月．youku[引用日期2013-11-07]
16. Cambridge Commonwealth, European and International Trust awards at the University of Cambridge: October 2014 ．CCEIT_Awards_2014_as_per_24_April_2014.pdf[引用日期2018-05-21]
17. Monte Carlo Simulation and Risk Modelling ．Linkedin[引用日期2014-07-20]
18. 一曲驚四座才藝少年屬茂名．新華網廣東頻道[引用日期2013-09-14]
19. EECE students win IET awards ．University of Birmingham[引用日期2013-05-29]
20. Electronic and Electrical Engineering BEng ．The University of Birmingham[引用日期2013-06-14]
21. A Presentation by Jinfeng LI at University of Cambridge ．Youku[引用日期2013-09-14]
22. Research Students ．University of Cambridge: Centre for Photonic Devices and Sensors[引用日期2018-05-22]
23. Recital to mark the PhD graduation of Dr Jinfeng Li ．Wolfson College, Cambridge[引用日期2019-01-15]
24. Jinfeng Li won a prize awarded by TRW in University Projec Evening 2013 in UK ．University of Birmingham．2013-03-21[引用日期2013-03-23]
25. UK Project Evening 2013 ．Newsletter from the University of Birmingham[引用日期2013-06-13]
26. (PDF) Best Paper Award for 3rd IEEE International Conference on Computing, Electronics & Communications Engineering 2020 ．ResearchGate[引用日期2020-09-08]
27. Detailed Programme IOTSMS-SNAMS 2019 ．The Sixth International Conference on Social Networks Analysis, Management and Security(SNAMS-2019)[引用日期2019-12-24]
28. SOTICS 2020: Committees ．The Tenth International Conference on Social Media Technologies, Communication, and Informatics SOTICS 2020[引用日期2020-02-15]
29. Technical Program Committee for Computing Conference 2021 ．Computing Conference 2021[引用日期2020-05-19]
30. Member of Technical Program Committee for IntelliSys 2020 ．IntelliSys 2020[引用日期2020-07-20]
31. Member of Technical Program Committee for FICC 2021 ．FICC 2021[引用日期2020-07-20]
32. Crystals Editor Certificate - Dr Jinfeng Li ．ResearchGate[引用日期2020-09-29]
33. Editorial Board - Medicine ．Medicine®[引用日期2020-10-06]
34. DR JINFENG LI, Faculty of Engineering, Department of Electrical and Electronic Engineering ．Imperial College London[引用日期2020-04-28]
35. Dr Jinfeng Li PhD ．Zepler Institute for Photonics and Nanoelectronics, University of Southampton[引用日期2020-04-28]
36. 藝術團學子國際非職業鋼琴賽獲佳績．華中科技大學國際交流處．2009-12-09[引用日期2013-11-29]
37. “海泰杯”國際非職業鋼琴比賽決賽選手獲獎名單．中國網[引用日期2018-06-06]
38. Rachmaninoff's 【Vocalise】．優酷網[引用日期2013-10-16]
39. 劍橋大學金秋音樂會節選《黃河怨》．youku[引用日期2013-12-26]
40. 劍橋大學金秋音樂會節選《康定情歌》 Kangding Love Song. ．youku[引用日期2013-12-26]
41. 劍橋大學金秋音樂會節選《秋之歌》 Song of Autumn ．youku[引用日期2013-12-26]
42. 劍橋大學金秋音樂會節選《江河水》 "The water in the river" ．youku[引用日期2013-12-26]
43. Polonaise in A flat major Op.53（Heroic）- 劍橋音樂會．youku[引用日期2014-07-23]
44. Chinese Music on a Summer’s Evening ．Hughes Hall, University of Cambridge．2014年8月14日[引用日期2014-08-14]
45. 《黃河鋼琴協奏曲》李勁鋒劍橋中國古典音樂會．youku[引用日期2014-08-15]
46. 《彩雲追月》李勁鋒劍橋中國古典音樂會．youku[引用日期2014-08-15]
47. 風居住的街道鋼琴與小提琴的憂傷對話．youku[引用日期2014-08-14]
48. 香港歌劇院女高音《那就是我》劍橋中國古典音樂會伴奏：李勁鋒．youku[引用日期2014-08-15]
49. 《牧歌》劍橋中國古典音樂會小提琴鋼琴：陳倉雄李勁鋒．youku[引用日期2014-08-15]
50. 《偶然》劍橋中國古典音樂會．youku[引用日期2014-08-16]
51. 《踏雪尋梅》劍橋中國古典音樂會．youku[引用日期2014-08-16]
52. 《我住長江頭》劍橋中國古典音樂會．youku[引用日期2014-08-15]
53. 《一杯美酒》劍橋中國古典音樂會．youku[引用日期2014-08-16]
54. 《望春風》小提琴鋼琴版劍橋中國古典音樂會．youku[引用日期2014-08-16]
55. Cambridge Graduate Orchestra ．Cambridge Graduate Orchestra[引用日期2014-10-13]
56. 蕭邦《平穩的行板與華麗的大波蘭舞曲》 - 劍橋大學音樂會 - 李勁鋒．youku[引用日期2014-11-07]
57. Chamber Singers ．Wolfson College Cambridge[引用日期2015-01-31]
58. The Cambridge Chinese New Year Gala ．The Cambridge Chinese New Year Gala 19th Feb 2015[引用日期2015-03-13]
59. Soirée Française: Sing True, Lent Term Concert, Lee Hall ．Wolfson College Cambridge[引用日期2015-06-25]
60. 2016年劍橋音樂會皮亞佐拉與肖邦作品李勁鋒．youku[引用日期2016-01-31]
61. 駐英國大使劉曉明出席2017年全英學聯春節晚會．中華人民共和國駐英國大使館教育處．2017-01-26[引用日期2017-12-05]
62. Lunchtime Concert: Jinfeng Li piano recital ．Wolfson College Cambridge[引用日期2019-03-02]
63. 【風雲 · 雄霸天下】鋼琴組曲劍橋大學華樂團2019音樂會．bilibili[引用日期2019-12-02]
64. Liquid Crystal-Based Enclosed Coplanar Waveguide Phase Shifter for 54–66 GHz Applications ．crystals[引用日期2019-12-06]
65. Imaging through a projection screen using bi-stable switchable diffusive photon sieves ．Optics Express．2018-04-09[引用日期2018-04-10]
66. High figure-of-merit compact phase shifters based on liquid crystal material for 1–10 GHz applications ．Japanese Journal of Applied Physics[引用日期2016-12-22]
67. All-optically Controlled Microwave Analog Phase Shifter with Insertion Losses Balancing ．Engineering Letters, vol. 28, no. 3．2020-08-15[引用日期2020-08-16]
68. Vulnerabilities Mapping based on OWASP-SANS: A Survey for Static Application Security Testing (SAST) ．Annals of Emerging Technologies in Computing[引用日期2020-12-21]
69. Millimetre-wave beam steering with analog-resolution and minimised distortion based on liquid crystals tunable delay lines with enhanced signal-to-noise ratios ．SPIE Security + Defence 2020[引用日期2020-09-20]
70. Optically Inspired Cryptography and Cryptanalysis: A Survey and Research Directions ．Springer[引用日期2020-09-29]
71. J. F. Li, H. Xu and D. P. Chu, "Design of liquid crystal based coplanar waveguide tunable phase shifter with no floating electrodes for 60–90 GHz applications," ．ieee xplore[引用日期2017-02-10]
72. 60 GHz Optimised Nickel-free Gold-plated Enclosed Coplanar Waveguide Liquid Crystal Phase Shifter - IEEE Conference Publication ．IEEE[引用日期2020-09-23]
73. Bias Tees Integrated Liquid Crystals Inverted Microstrip Phase Shifter for Phased Array Feeds ．IEEE．2020-09-22[引用日期2020-09-26]
74. Managing 60 GHz Field Peaking of an Liquid Crystal Enclosed Coplanar Waveguide by Core Edge Shaping - IEEE Conference Publication ．IEEE[引用日期2021-02-02]
75. Optically Steerable Phased Array Enabling Technology Based on Mesogenic Azobenzene Liquid Crystals for Starlink Towards 6G ．IEEE[引用日期2021-02-02]
76. A Novel Twitter Sentiment Analysis Model with Baseline Correlation for Financial Market Prediction with Improved Efficiency ．IEEE[引用日期2019-12-24]
77. Design and Control Optimisation of a Novel Bypass-embedded Multilevel Multicell Inverter for Hybrid Electric Vehicle Drives - IEEE Conference Publication ．IEEE[引用日期2020-11-12]
78. Low-loss tunable dielectrics for millimeter-wave phase shifter: from material modelling to device prototyping - IOPscience ．IOP Conference Series: Materials Science and Engineering．2020-08-04[引用日期2020-08-05]
79. Wideband PCB-to-Connectors Impedance Adapters for Liquid Crystal-based Low-loss Phase Shifters - IEEE Conference Publication ．IEEE[引用日期2021-02-07]
80. High FoM liquid crystal based microstrip phase shifter for phased array antennas ．IEEE[引用日期2017-08-02]
81. COVID-19 Contact-tracing Apps: a Survey on the Global Deployment and Challenges ．arxiv．2020-05-07[引用日期2020-09-26]
82. Global Deployment Mappings and Challenges of Contact-tracing Apps for COVID-19 ．SSRN Electronic Journal[引用日期2020-12-29]
83. Hybrid Propulsion Motor Drives Model based on Multi-level Inverters with Optimised Fuel Economy - IEEE Conference Publication ．IEEE[引用日期2021-02-18]
84. Jinfeng Li | Publons ．Publons[引用日期2021-02-19]
85. An efficient mixed-signal dielectric-partitioning model of liquid crystals based shielded coplanar waveguide for electronically reconfigurable delay lines design ．SPIE[引用日期2021-04-20]
86. Measuring the scientific effectiveness of contact tracing: Evidence from a natural experiment | PNAS ．Proceedings of the National Academy of Sciences of the United States of America[引用日期2021-09-05]
87. Figure-of-Merits Mismatch in Liquid Crystals mmWave Phase Shifters | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2021-10-28]
88. Crystals | Special Issue : Nematic Liquid Crystals 2022 ．Special Issue "Nematic Liquid Crystals 2022"[引用日期2021-11-09]
89. Best Paper Award_IOP_Jinfeng Li ．ResearchGate[引用日期2022-02-22]
90. ORCID - Jinfeng Li ．ORCID[引用日期2022-02-22]
91. Effectiveness evaluation of digital contact tracing for COVID-19 in New South Wales, Australia ．The Lancet Public Health[引用日期2022-02-22]
92. 中國小夥一曲紅樓夢點亮倫敦市政廳街拍 Cambridge李勁鋒受邀倫敦市政廳鋼琴完整版紅樓夢．bilibili[引用日期2022-02-22]
93. 鋼琴【人生若只如初見】Cambridge李勁鋒劍橋大學華樂團年度音樂會．bilibili[引用日期2022-03-15]
94. Crystals | Free Full-Text | Challenges and Opportunities for Nematic Liquid Crystals in Radio Frequency and Beyond ．Challenges and Opportunities for Nematic Liquid Crystals in Radio Frequency and Beyond[引用日期2022-04-28]
95. Towards 76-81 GHz Scalable Phase Shifting by Folded Dual-strip Shielded Coplanar Waveguide with Liquid Crystals ．Annals of Emerging Technologies in Computing (AETiC)[引用日期2022-04-28]
96. Rethinking Figure-of-Merits of Liquid Crystals Shielded Coplanar Waveguide Phase Shifters at 60 GHz ．J[引用日期2022-04-28]
97. Open-access water thermal hydraulics facility development in North Wales ．Proceedings of the 17th UK Heat Transfer Conference[引用日期2022-04-28]
98. Light Water Reactor Thermal Hydraulics Facility Development in North Wales ．19th International Topical Meeting on Nuclear Reactor Thermal Hydraulics[引用日期2022-04-28]
99. 受邀在英國女王登基70週年盆菜宴上鬥琴《當神探夏洛克遇上外來媳婦本地郎》．bilibili[引用日期2022-07-13]
100. Performance Limits of 433 MHz Quarter-wave Monopole Antennas due to Grounding Dimension and Conductivity ．Annals of Emerging Technologies in Computing[引用日期2022-07-14]
101. 60 GHz 0-360˚ Passive Analog Delay Line in Liquid Crystal Technology based on a Novel Conductor-backed Fully-enclosed Coplanar Waveguide | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2022-07-14]
102. Piano Fantasy - Concert by Dr. Jinfeng Li Tickets, Sat 8 Oct 2022 at 19:00 | Eventbrite ．Piano Fantasy - Concert by Dr. Jinfeng Li[引用日期2022-08-31]
103. Monte Carlo Investigation of the UK’s First EPR Nuclear Reactor Startup Core Using Serpent ．energies[引用日期2022-08-31]
104. Modelling nuclear fuel assembly with thermal-hydraulic feedback and burnup using WIMS-PANTHER-Serpent - IOPscience ．Journal of Physics: Conference Series[引用日期2022-08-31]
105. Computational Perturbation Methods for Moderator and Doppler Temperature Coefficients in the European Pressurised Reactor Core Analysis | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2022-08-31]
106. Multi-ring Subgroup Method in Characterising Highly Self-shielded Gadolinia Burnable Poison Pins for the UK EPR Nuclear Fuel Assembly | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2022-08-31]
107. Power Peaking, Critical Boron, and Shutdown Margin Benchmark of the UK Hinkley Point C EPR using WIMS-PANTHER Deterministic Codes | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2022-08-31]
108. Performance Limits of Liquid Crystals Coplanar Phase Shifters beyond 60 GHz due to Fabrication | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2022-08-31]
109. Program – ISAP2022 ．ISAP2022 The 2022 International Symposium on Antennas and Propagation[引用日期2022-10-18]
110. 中國小夥Cambridge李勁鋒受邀倫敦市政廳奏響紅樓夢枉凝眉葬花吟央視CGTN全程直播．bilibili[引用日期2022-11-07]
111. 讓音樂擁抱世界——首屆“海泰杯”國際非職業鋼琴比賽賽後感．知網空間[引用日期2014-07-10]
112. 【60週年校慶專欄】校友風采 | 李勁鋒．南方網[引用日期2020-03-16]
113. 國際鋼琴賽學子獲佳績．華中科技大學校報 - 《華中科技大學週報》[引用日期2020-03-18]
114. 李勁鋒——— “無心插柳”的鋼琴王子．華中科技大學校報．2010-03-08[引用日期2020-03-14]
115. 人生的拉普拉斯變換．華中科技大學校報 - 《華中科技大學週報》[引用日期2020-02-07]
116. Lunchtime Concert: Jinfeng Li piano recital ．Wolfson College Cambridge[引用日期2020-03-18]
117. THE NEWSLETTER OF WOLFSON COLLEGE CAMBRIDGE ．Wolfson College, Cambridge[引用日期2016-03-18]
118. St Edmund's Alumni Festival Event 2016 ．St Edmund's College University of Cambridge[引用日期2020-03-18]
119. CHINESE MUSIC ON A SUMMER'S EVENING ．Hughes Hall University of Cambridge[引用日期2020-03-18]
120. 歐洲時報–歐時網-歐時大參-李勁鋒“東方鋼琴幻想”倫敦音樂會舉行．歐洲時報[引用日期2022-10-25]
121. 愛彈琴的中國小夥是劍橋大學博士，希望以此在海外傳播中國文化．揚子晚報[引用日期2022-11-07]
122. 在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學博士．新華報業網[引用日期2022-11-07]
123. 【紫牛頭條】在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學博士．揚子晚報紫牛新聞[引用日期2022-11-07]
124. 廣東籍劍橋博士倫敦街頭奏響中國樂曲！稱傳播家鄉聲音很自豪．南方都市報APP · 南都即時[引用日期2022-11-07]
125. 對話倫敦街頭彈琴走紅的廣東博士：傳播家鄉的聲音是我的使命．南方都市報[引用日期2022-11-07]
126. 劍橋博士倫敦街頭彈琴獲贊無數：生活還有詩和遠方 | 極目新聞．極目新聞[引用日期2022-11-07]
127. 【紫牛頭條】在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學博士．揚子晚報網[引用日期2022-11-07]
128. 他在倫敦街頭即興彈奏中國經典．湖北省網絡廣播電視台[引用日期2022-11-07]
129. 他在倫敦街頭即興彈奏中國經典-中新網．中國新聞網[引用日期2022-11-07]
130. 他在倫敦街頭即興彈奏中國經典-中國僑網．中國僑網[引用日期2022-11-07]
131. 在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學電子工程博士．澎湃新聞[引用日期2022-11-07]
132. 在倫敦街頭彈鋼琴獲贊無數的中國小夥，還是劍橋大學電子工程博士．中國青年網[引用日期2022-11-07]
133. 把家鄉和祖國的聲音傳播到天涯海角是我的使命．南方都市報[引用日期2022-11-13]
134. 劍橋博士倫敦街頭彈琴獲贊無數：生活還有詩和遠方．中國經濟網[引用日期2022-11-13]
135. 獲百萬點贊！廣東90後博士在國外街頭做了這件事→ ．中央廣播電視總枱粵港澳大灣區之聲[引用日期2022-11-13]
136. 對話倫敦街頭彈琴走紅的廣東博士：傳播家鄉的聲音是我的使命．騰訊新聞[引用日期2022-11-13]
137. 79 GHz Meandering Enclosed-coplanar Variable Delay Lines in Liquid Crystals Encapsulated within Independent and Shared Cavities | IEEE Conference Publication | IEEE Xplore ．IEEE Xplore[引用日期2023-01-05]
138. Novel Partially-Shielded Coplanar Waveguide with Metasurfaces for Liquid Crystals Tunable Delay Lines beyond 67 GHz | IEEE Conference Publication | IEEE Xplore ．IEEE Xplore[引用日期2023-01-08]
139. Rethinking Liquid Crystal Tunable Phase Shifter Design with Inverted Microstrip Lines at 1–67 GHz by Dissipative Loss Analysis ．Electronics．2023-01-13[引用日期2023-01-17]
140. Machine Learning and Digital Twinning Enabled Liquid Crystals mm-Wave Reconfigurable Devices Design and Systems Operation ．IEEE[引用日期2023-04-27]
141. 網易雲音樂 - 慕尼黑車站 Cambridge李勁鋒原創鋼琴專輯．網易雲音樂[引用日期2023-05-03]
142. 網易雲音樂【國王十字】原創英倫古典鋼琴新民謠．網易雲音樂[引用日期2023-05-03]
143. 原創鋼琴曲【慕尼黑車站】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
144. 網易雲音樂原創鋼琴曲【輓歌】首發 Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
145. 網易雲音樂【The last minute flight】原創鋼琴曲 Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
146. 網易雲音樂 - 原創鋼琴曲【扎心老鐵】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
147. 網易雲音樂原創鋼琴五部曲【夢迴東山坡村】Cambridge李勁鋒除夕即興揮灑20分鐘故鄉回憶．網易雲音樂[引用日期2023-05-03]
148. 網易雲音樂 - 原創鋼琴曲【訣別之扉】Cambridge李勁鋒《夢迴東山坡村》後傳．網易雲音樂[引用日期2023-05-03]
149. 網易雲音樂 - 原創鋼琴曲【宇稱不守恆】Cambridge李勁鋒絕食期間即興原創．網易雲音樂[引用日期2023-05-03]
150. 網易雲音樂 - 原創鋼琴曲【時間情話】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
151. 網易雲音樂 - 原創鋼琴童話【你是否記得】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
152. 網易雲音樂原創鋼琴曲【孤勇】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
153. 網易雲音樂最好聽的原創鋼琴曲【光】Cambridge李勁鋒．網易雲音樂[引用日期2023-05-03]
154. 網易雲音樂 - 鋼鐵銀河廣場．網易雲音樂[引用日期2023-05-03]
155. 網易雲音樂 - 貝克街雪茄．網易雲音樂[引用日期2023-05-03]
156. 2023 International Conference on Microwave and Millimeter Wave Technology (ICMMT2023) ．2023 China Microwave Week Technical Program[引用日期2023-05-05]
157. Energies | Free Full-Text | Taking Flow Characterization to New Heights by Fiber Bragg Gratings Array ．Energies[引用日期2023-05-20]
158. Will ‘Liquid-Crystal-Based Floating-Electrode-Free Coplanar Waveguide Phase Shifter With an Additional Liquid-Crystal Layer for 28-GHz Applications’ Work? ．Engineering Letters．2023-05-23[引用日期2023-05-23]
159. Applied Sciences | Free Full-Text | From Liquid Crystal on Silicon and Liquid Crystal Reflectarray to Reconfigurable Intelligent Surfaces for Post-5G Networks ．Applied Sciences[引用日期2023-06-22]
160. 原創吉他曲【硅基生命】Cambridge李勁鋒即興作曲演奏．網易雲音樂[引用日期2023-07-16]
161. 原創鋼琴曲《室温超導》Cambridge李勁鋒．bilibili[引用日期2023-08-01]
162. 原創鋼琴曲【波粒二象性】Cambridge李勁鋒即興作曲演奏．bilibili[引用日期2023-08-01]
163. 原創鋼琴曲【幽靈粒子】Cambridge李勁鋒．網易雲音樂[引用日期2023-08-07]
164. Dissipative Analysis of Liquid Crystal-loaded Passive Reconfigurable Transmission Line Components with Filled Vias at 60 GHz | IEEE Conference Publication | IEEE Xplore ．IEEE Xplore[引用日期2023-08-08]
165. AETiC Highly Cited Article Award 2023 - Jinfeng Li ．ResearchGate[引用日期2023-08-17]
166. Experimental Characterization of Patterned Electrodes and Shaped Substrates for A Liquid Crystals Phase Shifter at V Band | IEEE Conference Publication | IEEE Xplore ．IEEE Xplore[引用日期2023-10-18]
167. JNE | Free Full ．Text | Flow Characterisation Using Fibre Bragg Gratings and Their Potential Use in Nuclear Thermal Hydraulics Experiments[引用日期2023-10-25]
168. 3D Imaging of Phase Structures Using Fibre Bragg Grating Grid Sensors ．ANS / Publications / Proceedings[引用日期2023-11-06]
169. Design Margin of Millimeter-wave Ultra-wideband 0-180° Analog Delay Line with Insertion Loss Less Than 2 dB ．IEEE[引用日期2023-11-15]
170. 北京理工大學集成電路與電子學院教師風采李勁鋒．北京理工大學集成電路與電子學院[引用日期2023-11-16]
171. 原創鋼琴曲【誓的三重境界】Cambridge李勁鋒即興作曲演奏．bilibili[引用日期2023-11-25]
172. Impact of laser polarization and angle of incidence on phase shifting efficacy of an all-optically addressed liquid crystal delay line at X band ．Proc. SPIE[引用日期2023-12-03]
173. 關於印發北京理工大學2023-2024學年第二學期新開素質教育選修課的通知．北京理工大學教務部[引用日期2023-12-19]
174. Physics-Informed Machine Learning Assisted Liquid Crystals µWave Phase Shifters Design and Synthesis ．springer.com[引用日期2023-12-20]
175. Advances in Sentiment Analysis - Techniques, Applications, and Challenges ．IntechOpen．2024-01-10[引用日期2024-01-11]
176. Introductory Chapter: The 2023 Sentiment Analysis Roadmap ．IntechOpen．2024-01-10[引用日期2024-01-11]
177. Tunability Dependence of All-Optical Liquid Crystal Delay Line on Laser Polarization and Incidence Angle ．Photonics Letters of Poland．2023-12-31[引用日期2024-01-11]
178. Liquid Crystal-Filled 60 GHz Coaxially Structured Phase Shifter Design and Simulation with Enhanced Figure of Merit by Novel Permittivity-Dependent Impedance Matching ．Electronics[引用日期2024-02-02]
179. 藝術團學子國際非職業鋼琴賽獲佳績．華中科技大學新聞網[引用日期2024-02-03]
180. Impedance Characterization for Liquid Crystal Tunable Coaxial Transmission Lines at 60 GHz | IEEE Conference Publication | IEEE Xplore ．IEEE[引用日期2024-02-19]
181. Towards Fabrication of High-Tuning-Range Liquid Crystals High-Aspect-Ratio Coplanar Waveguide Phase Shifter by LIGA, DRIE and Laser Ablation ．IEEE[引用日期2024-02-19]
182. 第五屆全國太赫茲科學技術青年年會暨中國國際太赫茲青年論壇．第五屆全國太赫茲科學技術青年年會暨中國國際太赫茲青年論壇[引用日期2024-03-20]
183. Mode Phase Shifter Designs in Liquid Crystals with Constitutive Loss Quantifications ．Crystals[引用日期2024-04-12]

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