已經跟呼吸一樣重要的網路和手機論文書籍站
China AIP的問題,透過圖書和論文來找解法和答案更準確安心。 我們找到下列免費下載的地點或者是各式教學
China AIP的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦Animasaun, Isaac Lare,Shah, Nehad Ali,Wakif, Abderrahim寫的 Ratio of Momentum Diffusivity to Thermal Diffusivity: Introduction, Meta-Analysis, and Scrutinization 和於淥的 邊緣奇跡:相變和臨界現象(修訂版)都 可以從中找到所需的評價。
另外網站Type 039C AIP conventional submarine - GlobalSecurity.org也說明:China apparently resumed construction of Type 039 Yuan-class diesel-electric attack submarines (SSK) after a three year hiatus, ...
這兩本書分別來自 和科學出版社所出版 。
國立臺灣科技大學 應用科技研究所 蘇威年、黃炳照、陳瑞山、吳溪煌所指導 Haylay Ghidey Redda的 用於高性能超級電容器和無負極鋰金屬電池的碳基和聚合物基複合電解質 (2021),提出China AIP關鍵因素是什麼,來自於垂直排列碳奈米管 (VACNT)、電化學雙層電容器 (EDLC)、二氧化鈦 (TiO2)、凝膠聚合物電解質 (GPE)、柔性固態超級電容器 (FSSC)、無陽極鋰金屬電池和超離子導體 (NASICON)。
而第二篇論文國立臺灣科技大學 機械工程系 陳炤彰、呂立鑫所指導 Mai Phuoc Trai的 電致動力輔助化學機械拋光製程中 有效粒子之動能研究 (2021),提出因為有 電致動力輔助化學機械拋光、有效粒子分析、粒子動能、材料移除率、表面粗糙度、非均勻度的重點而找出了 China AIP的解答。
最後網站AIP Supplement則補充:Civil Aviation Authority – Macao, China. AIP SUP 08/20. 2. Macao - Hong Kong IFR Routes. 2.1 General. 2.1.1 The helicopter IFR routes (J ...
Ratio of Momentum Diffusivity to Thermal Diffusivity: Introduction, Meta-Analysis, and Scrutinization
為了解決China AIP 的問題,作者Animasaun, Isaac Lare,Shah, Nehad Ali,Wakif, Abderrahim 這樣論述:
Isaac Lare Animasaun is a Lecturer in the Department of Mathematical Sciences, The Federal University of Technology, Akure, Nigeria. His research interests are Mathematical Modeling, Boundary Layer Analysis, and Heat & Mass Transfer, Dynamics of Newtonian and Non-Newtonian fluid, fluid flow through
porous or non-porous media, Approximate and analytical solutions of Differential Equations, and educational research (survey research). He has published more than Ninety (100) articles through international and local refereed journals. The Statistics show that he has seventy-four (101) published pap
ers indexed in Scopus (33 h-index) and forty-three (43) indexed in Web of Science (20 h-index). A few among the Journals he has served as a Reviewer and number of reviews are the Arabian Journal for Science and Engineering, Springer (125), Neural Computing and Applications, Springer (61), Heat Trans
fer - Asian Research, Wiley (41), and Journal of Thermal Analysis ad Calorimetry, Springer (14). He won the 2019 Outstanding Reviewer Awards from Physica Scripta, IOP Publishing, and Four awards from Publon to his credit. He was awarded the renowned Professor Aderemi Kuku Young Scientist Prize in Ma
thematical Sciences by the Nigerian Young Academy in 2020. (NYA). Dr. Nehad Ali Shah is an Assistant Professor in the Department of Mathematics, Lahore Leads University. His research interest is Fluid Dynamics (i.e. Newtonian and non-Newtonian fluids, Heat and Mass transfer, Viscoelastic models with
memory, Fractional thermoelasticity). His Research expertise was attracted by Ton Duc Thang University, Ho Chi Minh City, Vietnam, and led to his role as a part-time researcher in their Faculty of Mathematics & Statistics. He is the recipient of the Pre-PhD Quality Research Award from Abdus Salam S
chool of Mathematical Sciences, GC University Lahore, Pakistan, in the year 2018. He was also a recipient of a research invitation by Prof. Haitao Qi, Vice Dean of School of Mathematics and Statistics, Shangdong University of Weihai China, and Prof. Shaowei Wang, Dean of Department of Engineering Me
chanics, School of Civil Engineering, Shandong University, Jinan, P. R. China. He has more than 70 published research papers in different high reputed journals. He has served as a Reviewer of many manuscripts submitted to more than 20 international journals.Dr. Wakif is a Lecturer in the Laboratory
of Mechanics, Faculty of Sciences Aïn Chock, University Hassan II - Casablanca, B. P. 5366, Mâarif, Casablanca, Morocco. His research interests are peristaltic blood flow, nanofluids, boundary layer flows, natural, forced, mixed convection MHD/EHD flow in nanofluids, heat and mass transfer in mixtur
es, numerical, analytical and semi-analytical methods, linear and nonlinear stability analysis. Dr. Wakif is a board member of the International Journal of Applied and Computational Mathematics, Journal of Computational Applied Mechanics, Mathematical Methods in the Applied Sciences, Progress in Com
putational Fluid Dynamics, and Thermal Science. Some of the journals that have benefited from his review skills and the number of the completed assignment are Journal of Thermal Analysis and Calorimetry (39), Physica A: Statistical Mechanics and Its Applications (19), Scientia Iranica (9), Internati
onal Journal of Applied and Computational Mathematics (8), International Communications in Heat and Mass Transfer (5), Journal of the Brazilian Society of Mechanical Sciences and Engineering (5), and Physica Scripta (5). Seventeen (17) of his publications were published through various journals inde
xed in Web of Science. He won the Top Reviewer Awards in Physics and Cross-Field by Publon Academy in the year 2019.Dr. B Mahanthesh is currently an Associate Professor at the Center for Mathematical Needs, Department of Mathematics, CHRIST (Deemed to be University), Bangalore-560029, India. His res
earch covers various topics, including fluid mechanics, nanofluid dynamics, optimization techniques, response surface methodology, and sensitivity analysis. He is a member of the editorial board of renowned academic journals. He is an active reviewer for many renowned journals. He has edited a book
entitled Mathematical Fluid Mechanics, has four book chapters and has published over 150 research articles in many renowned international journals. His scientific metrics according to (https: //bit.ly/2Eod25I) Google Scholar show H-Index = 42, Citations Index = 4150, i10-index = 96. He has organized
several conferences and delivered key research papers in various countries and international conferences.Dr. R. Sivaraj is working as a Senior Assistant Professor in the Department of Mathematics, School of Advanced Sciences, Vellore Institute of Technology, India. His area of research is in Fluid
Dynamics, and he works on non-Newtonian fluids, MHD, heat transfer, and porous media. He has published 34 research papers in highly reputed International Journals. Under his guidance, two scholars received a Ph.D. degree, and presently four scholars are working. He received the VIT Research Award co
ntinuously for the years 2012-2018 and a travel grant from the Royal Society of London and CSIR, India. He worked at Guangdong University of Technology, Guangzhou, China, under the Faculty Exchange Programme. He visited the National Defense University of Malaysia, Kuala Lumpur, Malaysia, as a Visiti
ng Scientist. He delivered lectures on fluid dynamics applications at the University of the West Indies, St. Augustine, Trinidad, West Indies. He delivered an invited lecture in international conferences and seminars organized by the University of Botswana, the National University of Singapore, and
Universiti Putra Malaysia. He attended over 20 National and International conferences in India and abroad. He was invited to deliver lectures in several conferences, workshops, seminars, and guest lectures, and he has organized several international conferences, seminars, workshops to promote the re
search activities. He served as a reviewer for 39 scientific journals. He served as one of the editors for the book Applied Mathematics and Scientific Computing published by Springer book series Trends in Mathematics, Advances in Fluid Dynamics published by Springer book series Lecture Notes in Mech
anical Engineering and the proceedings Recent Trends in Pure and Applied Mathematics published by AIP Conference Proceedings. He is the Joint Secretary of Academia for Advanced Research in Mathematics Society.Olubode Kolade Koriko is a Professor in the Department of Mathematical Sciences, The Federa
l University of Technology, Akure, Nigeria. His research interests fall within the scope of mathematical modelling, boundary layer analysis, heat and mass transfer, dynamics of Newtonian and non-Newtonian fluid, flow through porous or non-porous media, and Differential Equations. He is a member of t
he Society for Industrial and Applied Mathematics, Nigeria Association of Mathematical Physics, and Nigeria Mathematical Society. Also, he has served various journals as a Reviewer. He had served as an External Examiner of more than five (5) Ph.D. students. More so, he has produced two Ph.D. Student
s. The Statistics show that he has many published papers indexed in Scopus and Web of Science. He was among the recipients of the Commonwealth Scholarship and Fulbright Junior Research Fellowship.
用於高性能超級電容器和無負極鋰金屬電池的碳基和聚合物基複合電解質
為了解決China AIP 的問題,作者Haylay Ghidey Redda 這樣論述:
尋找具有高容量、循環壽命、效率和能量密度等特性的新型材料,是超級電容器和鋰金屬電池等綠色儲能裝置的首要任務。然而,安全挑戰、比容量和自體放電低、循環壽命差等因素限制了其應用。為了克服這些挑戰,我們設計的系統結合垂直排列的碳奈米管 (Vertical-Aligned Carbon Nanotubes, VACNT)、塗佈在於VACNT 的氧化鈦、活性材料的活性炭、凝膠聚合物電解質的隔膜以及用於綠色儲能裝置的電解質。透過此研究,因其易於擴大規模、低成本、提升安全性的特性,將允許新的超級電容器和電池設計,進入電動汽車、電子產品、通信設備等眾多潛在市場。於首項研究中,作為雙電層電容器 (Electr
ic Double-Layer Capacitor, EDLC) 的電極,碳奈米管 (VACNTs) 透過熱化學氣相沉積 (Thermal Chemical Vapor Deposition, CVD) 技術,在 750 ℃ 下成功地垂直排列生長於不銹鋼板 (SUS) 基板上。此過程使用Al (20 nm) 為緩衝層、Fe (5 nm) 為催化劑層,以利VACNTs/SUS生長。為提高 EDLC 容量,我們在氬氣、氣氛中以 TiO2 為靶材,使用射頻磁控濺射技術 (Radio-Frequency Magnetron Sputtering, RFMS) 將 TiO2 奈米顆粒的金紅石相沉積到 V
ACNT 上,過程無需加熱基板。接續進行表徵研究,透過掃描電子顯微鏡 (Scanning Electron Microscopy, SEM)、能量色散光譜 (Energy Dispersive Spectroscopy, EDS)、穿透式電子顯微鏡 (Transmission Electron Microscopy, TEM)、拉曼光譜 (Raman Spectroscopy) 和 X 光繞射儀 (X-Ray Diffraction, XRD) 對所製備的 VACNTs/SUS 和 TiO2/VACNTs/SUS 進行研究。根據實驗結果,奈米碳管呈現隨機取向並且大致垂直於SUS襯底的表面。由拉
曼光譜結果顯示VACNTs表面上的 TiO2 晶體結構為金紅石狀 (rutile) 。於室溫下使用三電極配置系統在 0.1 M KOH 水性電解質溶液中通過循環伏安法 (Cyclic Voltammetry, CV) 和恆電流充放電,評估具有 VACNT 和 TiO2/VACANT 複合電極的 EDLC 的電化學性能。電極材料的電化學測量證實,在 0.01 V/s 的掃描速率下,與純 VANCTs/SUS (606) 相比,TiO2/VACNTs/SUS 表現出更高的比電容 (1289 F/g) 。用金紅石狀 TiO2 包覆 VACNT 使其更穩定,並有利於 VACNT 複合材料的side w
ells。VACNT/SUS上呈金紅石狀的TiO2 RFMS沉積擁有巨大表面積,很適合應用於 EDLC。在次項研究,我們聚焦在開發用於柔性固態超級電容器 (Flexible Solid-State Supercapacitor, FSSC) 的新型凝膠聚合物電解質。透過製備活性炭 (Activated Carbon, AC) 電極的柔性 GPE (Gel Polymer Electrolytes) 薄膜,由此提升 FSSC 的電化學穩定性。GPE薄膜含有1-ethyl-3-methylimidazolium bis(trifluoromethylsulfony)imide, poly (vin
ylidene fluoride-cohexafluoropropylene) (EMIM TFSI) with Li1.5Al0.33Sc0.17Ge1.5(PO4)3 (LASGP)作為FSSC的陶瓷填料應用。並使用掃描式電子顯微鏡 (SEM)、X 光繞射、傅立葉轉換紅外光譜 (Fourier-Transform Infrared, FTIR)、熱重力分析 (ThermoGravimetric Analysis, TGA) 和電化學測試,針對製備的 GPE 薄膜的表面形貌、微觀結構、熱穩定性和電化學性能進行表徵研究。由SEM 證實,隨著將 IL (Ionic Liquid) 添加到主體聚合
物溶液中,成功生成具光滑和均勻孔隙表面的均勻相。XRD圖譜表明PVDF-HFP共混物具有半結晶結構,其無定形性質隨著EMIM TFSI和LASGP陶瓷填料的增加而提升。因此GPE 薄膜因其高離子電導率 (7.8 X 10-2 S/cm)、高達 346 ℃ 的優異熱穩定性和高達 8.5 V 的電化學穩定性而被用作電解質和隔膜 ( -3.7 V 至 4.7 V) 在室溫下。令人感到興趣的是,採用 LASGP 陶瓷填料的 FSSC 電池具有較高的比電容(131.19 F/g),其對應的比能量密度在 1 mA 時達到 (30.78 W h/ kg) 。這些結果表明,帶有交流電極的 GPE 薄膜可以成為
先進奈米技術系統和 FSSC 應用的候選材料。最終,是應用所製備的新型凝膠聚合物電解質用於無陽極鋰金屬電池 (Anode-Free Lithium Metal Battery, AFLMB)。此種新方法使用凝膠聚合物電解質獲得 AFLMB 所需電化學性能,該電解質夾在陽極和陰極表面上,是使用刮刀技術製造14 ~ 20 µm 超薄薄膜。凝膠聚合物電解質由1-ethyl-3-methylimidazolium bis(trifluoromethyl sulfonyl)imide 作為離子液體 (IL), poly(vinylidene fluoride-co-hexafluoropropylene
) (PVDF-HFP)作為主體聚合物組成,在無 Li1.5Al0.33Sc0.17Ge1.5(PO4)3 (LASGP) 作為陶瓷填料的情況下,採用離子-液體-聚合物凝膠法 (ionic-liquid-polymer gelation) 製備。在 25℃ 和 50℃ 的 Li+/Li 相比,具有 LASGP 陶瓷填料的 GPE 可提供高達5.22×〖10〗^(-3) S cm-1的離子電導率,電化學穩定性高達 5.31 V。改良的 AFLMB於 0.2 mA/cm2 和50℃ 進行 65 次循環後,仍擁有優異的 98.28 % 平均庫侖效率和 42.82 % 的可逆容量保持率。因此,使用這種
陶瓷填料與基於離子液體的聚合物電解質相結合,可以進一步證明凝膠狀電解質在無陽極金屬鋰電池中的實際應用。
邊緣奇跡:相變和臨界現象(修訂版)
為了解決China AIP 的問題,作者於淥 這樣論述:
將帶領讀者進入千奇百怪、絢麗多彩的「相變世界」:從物質三態變化、鐵磁、鐵電、液晶相變,到玻色一愛因斯坦凝聚、超流和超導。書中還把平衡態相變的概念推廣到其他系統,包括幾何相變和非平衡相變。全書通過對相變和臨界現象的介紹,闡述熱力學和統計物理的基本概念,從熵的引入、統計配分函數,到對稱破缺、標度律和普適性。同時也描述了研究相變現象的基本理論方法,包括平均場近似、標度分析、重正化群、統計模型精確解和計算機數值模擬等,還介紹了相變研究的最新進展,如有限系統的臨界現象和量子相變。 《邊緣奇跡:相變和臨界現象(修訂版)》為理論物理的基礎讀物,內容豐富、敘述生動、插圖精彩,可供具有理工
科大學初年級文化程度的讀者閱讀。
電致動力輔助化學機械拋光製程中 有效粒子之動能研究
為了解決China AIP 的問題,作者Mai Phuoc Trai 這樣論述:
摘要AbstractAcknowledgementTable of ContentsList of FiguresList of TablesNomenclatureChapter 1 INTRODUCTION1.1 CMP background1.2 Motivation1.3 Objective1.4 Dissertation contribution and scope1.5 Dissertation outlineChapter 2 LITERATURE REVIEW2.1 Previous studies of EKF-CMP in PML2.2 CMP components2.2
.1 Pad parameter2.2.2 The role of diamond dressing on pad asperity or roughness2.2.3 Wafer parameter2.2.4 Particle-slurry parameter2.2.5 The role of slurry flow on passivated surface layer2.3 Overview slurry flow2.3.1 Analysis on mechanics for contact area2.3.2 Analysis on lubrication region2.3.3 An
alysis on hydrodynamic flow pressure2.3.4 Analysis on slurry flow velocity2.3.5 Lubrication model in CMP2.4 CMP performance2.4.1 Preston equation2.4.2 Parameters affecting MRR2.5 Summary of literature reviewChapter 3 EKF-CMP THEORY AND MODEL3.1 EKF theory3.1.1 Electro-kinetic force (EKF)3.1.2 Elect
ric double layer (EDL)3.1.3 Zeta potential3.1.4 Electro-osmosis flow (EOF)3.2.5 EKF-CMP definition3.2 Physical module in COMSOL applying 3D-EOF model3.2.1 Electric current module3.3.2 Laminar flow module3.3.3 Particle tracing module3.3 Development of 3D-EOF model3.3.1 Definition of effective particl
e3.2.2 Model of 3D-EOF in COMSOL3.2.3 Assumption of 3D-EOF model3.4 Result and discussion3.4.1 EOF verification between theory and simulation3.4.2 Analysis on effective particle3.5 Summary of Chapter 3Chapter 4 PARTICLE KINETIC ENERGY FOR EKF-CMP4.1 Role of particle kinetic energy4.2 Research method
4.2.1 3D-EOF simulation model development4.2.2 Assumptions of 3D-EOF simulation model4.2.3 Definition of particle kinetic energy4.2.4 3D-EOF model for PIV test4.3 Result and discussion4.3.1 PIV results of 3D-EOF for IC-1000 pad4.3.2 Investigation of particle kinetic energy4.4 Summary of Chapter 4Cha
pter 5 TRANSLATIONAL-ROTATIONAL KINETIC ENERGY OF PARTICLE IN EKF-CMP5.1 Statement of translational-rotational kinetic energy of particle in EKF-CMP .2 Material and method5.2.1 Physical mechanism of EKF-CMP5.2.2 3D model development for EKF-CMP5.2.3 Assumption of novel 3D model for EKF-CMP5.2.4 M
athematical equation of TKE & RKE of particle5.3 Result and discussion5.3.1 Analysis on PIV result of 3D-EOF for IC-1400 pad5.3.2 Analysis on results of relative velocity5.3.3 Analysis on translational-rotational kinetic energy of particle5.4 Summary of Chapter 5Chapter 6 EKF-CMP EXPERIMENT6.1 EKF-C
MP experiment system6.2 Result and discussion6.2.1 Discussion on EKF-CMP efficiency for Cu blanket wafer at 1.5 psi6.2.2 Discussion on EKF-CMP efficiency for Cu blanket wafer at 2.5 psi6.2.3 Discussion on EKF-CMP performance for glass wafer6.5 Summary of Chapter 6Chapter 7 CONCLUSION AND RECOMENDATI
ON7.1 Conclusion7.2 RecommendationReferenceAppendix A Matlab program of effective particle analysisAppendix B Matlab program of particle kinetic energyAppendix C Matlab program of translational and rotational kinetic energy’s particleAppendix D Results of particle tracing in 3D model without groove
in COMSOLAppendix E Results of particle tracing in 3D model with x-y groove in COMSOLAppendix F Results of particle tracing in 3D model with concentric circle groove in COMSOLAppendix G Results of Cu surface roughness after CMP and EKF CMP at 1.5 psiAppendix H Results of Cu surface roughness after C
MP and EKF CMP at 2.5 psiAppendix I Results of Glass surface roughness after CMP and EKF CMP at 3.5 psiAppendix J Measuring and experimental equipment in PMLBiography of Author