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Advanced Materials for Biomechanical Applications

為了解決Stainless steel的問題，作者 這樣論述：

This book, Advanced Materials for Biomechanical Applications, provides in-depth knowledge about cross rolling of biomedical alloys, cellulose, magnetic iron oxide nanoparticles, magnesium-based nanocomposites, titanium, titanium alloys, stainless steel, and improved biodegradable implants materials

for biomechanical applications like joint replacements, bone plates, bone cement, artificial ligaments and tendons, dental implants for tooth fixation, and hip implants.It comprehensively covers advancements in materials including graphene-reinforced magnesium metal matrix, magnesium and its alloys,

and 2D nanomaterials. The text discusses important topics including advanced materials for biomechanical applications, design, and analysis of stainless steel 316L for femur bone fracture healing, design and manufacturing of prosthetic dental implants, a biomechanical study of low cost prosthetic l

eg and energy harvesting mechanism for walking applications.The text will serve as a useful text for graduate students, academic researchers, and general practitioners in areas including materials science, manufacturing engineering, mechanical engineering, and biomechanical engineering. Dr. Ashwan

i Kumar received Ph.D. (Mechanical Engineering) in the area of Mechanical Vibration and Design. He is currently working as Senior Lecturer, Mechanical Engineering (Gazetted Officer Class II) at Technical Education Department, Uttar Pradesh (Government of Uttar Pradesh) India since December 2013. He

has worked as Assistant Professor in Department of Mechanical Engineering, Graphic Era University Dehradun India from July 2010 to November 2013. He has more than 11 years of research and academic experience in mechanical and materials engineering. He is Series Editor of book series ＂Advances in Man

ufacturing, Design and Computational Intelligence Techniques＂ published by CRC Press (Taylor & Francis) USA. He is Associate Editor for International Journal of Mathematical, Engineering and Management Sciences (IJMEMS) Indexed in ESCI/Scopus and DOAJ. He is editorial board member of 4 international

journals and acts as review board member of 20 prestigious (Indexed in SCI/SCIE/Scopus) international journals with high impact factor i.e. Applied Acoustics, Measurement, JESTEC, AJSE, SV-JME, and LAJSS. In addition he has published 85 research articles in journals, book chapters and conferences.

He has authored/co-authored cum edited 13 books of Mechanical and Materials Engineering. He is associated with International Conferences as Invited Speaker/ Advisory Board/Review Board member. He has delivered many invited talks in webinar, FDP and Workshops. He has been awarded as Best Teacher for

excellence in academic and research. He has successfully guided 12 B.Tech., M.Tech and Ph.D. thesis. In administration he is working as coordinator for AICTE, E.O.A., Nodal officer for PMKVY-TI Scheme (Government of India) and internal coordinator for CDTP scheme (Government of Uttar Pradesh).He is

currently involved in the research area of Machine Learning, Advanced Materials, Machining & Manufacturing Techniques, Biodegradable Composites, Heavy Vehicle Dynamics and Coriolis Mass Flow Sensor. Prof. Mangey Ram received the Ph.D. degree major in Mathematics and minor in Computer Science from G.

B. Pant University of Agriculture and Technology, Pantnagar, India. He has been a Faculty Member for around thirteen years and has taught several core courses in pure and applied mathematics at undergraduate, postgraduate, and doctorate levels. He is currently the Research Professor at Graphic Era

(Deemed to be University), Dehradun, India & Visiting Professor at Peter the Great St. Petersburg Polytechnic University, Saint Petersburg, Russia. Before joining the Graphic Era, he was a Deputy Manager (Probationary Officer) with Syndicate Bank for a short period. He is Editor-in-Chief of Internat

ional Journal of Mathematical, Engineering and Management Sciences; Journal of Reliability and Statistical Studies; Journal of Graphic Era University; Series Editor of six Book Series with Elsevier, CRC Press-A Taylor and Frances Group, Walter De Gruyter Publisher Germany, River Publisher and the Gu

est Editor & Associate Editor with various journals. He has published 250 plus publications (journal articles/books/book chapters/conference articles) in IEEE, Taylor & Francis, Springer Nature, Elsevier, Emerald, World Scientific and many other national and international journals and conferences. A

lso, he has published more than 50 books (authored/edited) with international publishers like Elsevier, Springer Nature, CRC Press-A Taylor and Frances Group, Walter De Gruyter Publisher Germany, River Publisher. His fields of research are reliability theory and applied mathematics. Dr. Ram is a Sen

ior Member of the IEEE, Senior Life Member of Operational Research Society of India, Society for Reliability Engineering, Quality and Operations Management in India, Indian Society of Industrial and Applied Mathematics, He has been a member of the organizing committee of a number of international an

d national conferences, seminars, and workshops. He has been conferred with ＂Young Scientist Award＂ by the Uttarakhand State Council for Science and Technology, Dehradun, in 2009. He has been awarded the ＂Best Faculty Award＂ in 2011; ＂Research Excellence Award＂ in 2015; ＂Outstanding Researcher Award

＂ in 2018 for his significant contribution in academics and research at Graphic Era Deemed to be University, Dehradun, India. Recently, he has been received the Excellence in Research of the Year-2021 Award＂ by the Honourable Chief Minister of Uttarakhand State, India. Dr. Yogesh Kumar Singla associ

ated with Case Western Reserve University, USA has done his Ph.D. from IIT Roorkee. He has more than 6 years of research and teaching experience. He is working in the area of Manufacturing, Welding, Surface Engineering, Tribology, Materials Characterization, Welding Metallurgy and Mechanical Behavio

r of Metals. He has 10 SCI publications and 05 Scopus Indexed publications. Apart from this, 4 SCI papers are in-process. In his career, he has successfully guided 1 Ph.D. and 4 M.E. theses. He is a reviewer of many SCI journals of Elsevier and Springer having impact factor ranging from 0.7-5.289. H

e is about to submit one patent on solar dryer. He has given many expert talks at State and Central Level Institutes/Universities. He also has the experience of conducting 10 days Faculty Development Program. In addition to this, he is an Editor of two International Books entitled ＂Advanced Computat

ional Methods in Mechanical and Materials Engineering＂ and ＂Advanced Materials for Bio-Mechanical Applications＂ to be published by CRC Press (Taylor & Francis Group https: //taylorandfrancis.com/books/) in 2021.

Stainless steel進入發燒排行的影片

台中港區微粒、金屬元素之乾沉降污染物預測、排放來源及健康風險評估之研究

為了解決Stainless steel的問題，作者高偉順 這樣論述：

本研究是使用PS-1採樣器與乾沉降板來蒐集大氣中的懸浮微粒及其附屬重金屬汙染物之濃度及乾沉降，採樣時間於2020年1月至12月於台中梧棲港區來進行。本研究並藉由使用ICP-OES分析儀來分析附著於懸浮微粒上之汙染物的重金屬濃度及乾沉降。再者，本研究亦使用Global model來推估並比較不同粒徑所計算出來之懸浮微粒及其附屬重金屬汙染物之乾沉降通量，其值並與實際之乾沉降值作一比較。除此之外，本研究並利用逆軌跡分析方法來推測台中港區採樣點之可能汙染源。最後，本研究更以風險評估之方法來計算該特徵採樣點之致癌風險值。研究結果顯示，總懸浮微粒濃度與乾沉降通量其最高值均發生於冬季，而重金屬濃度與乾沉降

之最高值則分別為重金屬Cu，Ni。此外，乾沉降模式之研究結果顯示，Global collection model之模式推估乾沉降通量以重金屬元素Pb可得到最佳之乾沉降推估結果。再者，重金屬元素Pb 乾沉降通量之最佳預測結果則出現在 以16 μm 的微粒尺寸作為計算之乾沉降速度則其乾沉降通量能有最佳之推估結果。而逆軌跡分析之結果顯示，本研究之主要汙染氣團於6、7、8月是來自採樣點的南方，其餘月份皆來自於採樣點之北方。而在健康風險評估結果顯示該採樣點之金屬元素Cr的致癌風險值結果高於1×10-4，上述值高於致癌風險監管機構US/EPA之標準。因此，未來宜持續監測觀察上述重金屬Cr元素於台中港區之濃

度及致癌風險值。

Grand Teton Day Hikes & National Park Map [Map Pack Bundle]

為了解決Stainless steel的問題，作者National Geographic Maps - Trails Illust 這樣論述：

- Waterproof - Tear-Resistant - Topographic MapsThe Tetons evoke a sense of inspiration and aspiration in all who visit. Established in 1929, Grand Teton National Park now encompasses and protects 310,000 acres (485 square miles) for everyone to enjoy. This two title Map Pack Bundle helps explorers

of all levels see everything this astounding park has to offer. The map pack includes an overview map that shows the entire park as well as a Day Hikes map guide. With this combination of maps visitors can feel comfortable planning a trip to a park with options for everyone, from multi-day backpack

trips to short hikes on the shores of Jackson Lake.The Grand Teton National Park Day Hikes Topographic Map Guide includes seventeen diverse hikes for all hiking enthusiasts, from the easy, 1.1 mile long Schwabacher Landing to the strenuous, 12.9 mile long Granite Canyon with almost a mile of elevati

on loss. Each hike has a detailed map, a trail profile visualizing the changes in elevation, and a short summary of the interesting features encountered along the trip. Buy the Map Pack and save 15%!The Grand Teton Day Hikes and National Park Map Pack includes: Map 202:: Grand Teton National ParkMap

1704:: Grand Teton National Park Day HikesEvery Trails Illustrated map is printed on ’Backcountry Tough’ waterproof, tear-resistant paper. National Geographic’s Topographic Map Guide booklets are printed on ’Backcountry Tough’ waterproof, tear-resistant paper with stainless steel staples. A full UT

M grid is printed on the map to aid with GPS navigation.Map Scale = 1:50,000Sheet Size = 25.5 x 37.75Folded Size = 4.25 x 9.25

應用自開發之程序控制系統於電漿電解氧化製程以探討氧化膜性能提升機制之研究

為了解決Stainless steel的問題，作者黃冠諭 這樣論述：

誌謝 I中文摘要 II英文摘要 IV目次 VI圖目次 X表目次 XVIIIChapter.1 前言 11.1 電漿電解氧化技術的發展背景 11.2 研究動機 4Chapter.2 電漿電解氧化處理 52.1 電漿電解氧化(PEO) 52.1.1 電漿電解氧化機制原理 62.1.2 膜層電擊穿機制 112.1.3 電漿電解氧化之電源參數影響 152.1.4 PEO製程的物理/化學反應機制 182.2 PEO氧化膜層特性 252.2.1 膜層的反應與形成機制 252.2.2 PEO處理中常見的基材金屬 292.3 PEO製程常見的電解

質成分 342.4 程序控制法 382.5 應用於Mn摻雜TiO2光催化劑薄膜 402.5.1 揮發性有機汙染物 402.5.2 光催化反應機制 412.5.3 Mott-Schottky方程 442.5.4 二氧化鈦光觸媒 462.5.5 二氧化鈦光觸媒的製備方法 512.5.6 提升二氧化鈦光觸媒光吸收效能之技術 542.6 應用於HA與L乳酸鈣於生醫改質氧化膜層 572.6.1 PEO於生醫改質之發展與應用 572.6.2 PEO生醫改質中常見的金屬植體 582.6.3 氫氧基磷灰石與L-乳酸鈣於生醫改質之用途 592.7 研究目的與實

驗規劃 61Chapter.3 程序控制法於PEO製程之應用 633.1 實驗方法 633.1.1 程序控制系統與設備 633.1.2 實驗設計 643.1.3 Mn: TiO2光催化劑實驗流程設計 683.1.4 以懸浮液搭配程序控制PEO製備TiO2膜層之流程設計 713.1.5 以離子溶液液搭配程序控制PEO製備TiO2膜層之流程設計 743.2 實驗基材選用與藥品準備 773.3 程序控制法於PEO製程基本分析 793.3.1 電源系統監控分析 793.3.2 膜層表面形貌與成分分析 793.3.3 孔徑與孔隙率分析 793.3.4

晶體結構相組成分析 803.3.5 紫外光－可見光吸收光譜分析 813.3.6 載子濃度分析 813.3.7 X射線光電子能譜分析 823.3.8 懸浮微粒之粒徑大小分析 83Chapter.4 多階段程序控制於PEO處理製備摻雜Mn: TiO2光催化劑 844.1 Mn: TiO2光催化劑特性探討 844.1.1 第一步驟製程設計對二氧化鈦膜層影響 844.1.2 不同含浸濃度錳離子對於二氧化鈦特性比較 904.1.3 不同電源模式含錳離子之二氧化鈦特性差異 1034.1.4 含浸法對錳離子含量之影響與離子機制之探討 1144.2 光觸媒催化效能測

試 119Chapter.5 以懸浮液搭配多階段程序控制PEO進行TiO2膜層製備 1215.1 HA於多階段程序控制PEO之影響 1215.1.1 單階段程序控制於PEO膜層特性之探討 1215.1.2 雙階段程序控制於PEO膜層特性之探討 1225.1.3 多階段程序控制於PEO膜層特性之探討 1295.2 HA於增加陽極氧化前處理之影響 1415.2.1 陽極處理膜層之特性探討 1415.2.2 陽極處理－多階段程序控制PEO膜層特性探討 142Chapter.6 以離子溶液搭配多階段程序控制PEO進行TiO2膜層製備 1626.1 電解液A於PE

O不同階段製程之膜層特性探討 1626.1.1 電解液A之乳酸鈣於雙階段PEO製程影響 1626.1.2 電解液A之乳酸鈣於三階段PEO製程影響 1706.2 電解液B於PEO不同階段製程之膜層特性探討 1736.2.1 電解液B之乳酸鈣於雙階段PEO製程影響 1736.2.2 電解液B之乳酸鈣於三階段PEO製程影響 182Chapter.7 結論與未來展望 1917.1 結論 1917.2 未來展望 192參考文獻 193