你看見的世界其實是媒體資訊建構的論文書籍站
Physical activity gu的問題,透過圖書和論文來找解法和答案更準確安心。 我們挖掘到下列精選懶人包
Physical activity gu的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦寫的 Nanoporous Carbons for Soft and Flexible Energy Devices 和的 Petrogenesis and Exploration of the Earth’s Interior: Proceedings of the 1st Springer Conference of the Arabian Journal of Geosc都 可以從中找到所需的評價。
這兩本書分別來自 和所出版 。
國立陽明交通大學 材料科學與工程學系所 柯富祥所指導 杜博瑋的 磁敏釋放控制微膠囊並應用於金屬離子螢光感測 (2021),提出Physical activity gu關鍵因素是什麼,來自於微膠囊、雙乳化、釋放控制、熒光感測、磁性奈米顆粒。
而第二篇論文國立臺北護理健康大學 護理研究所 李梅琛所指導 余秋菊的 行動裝置教育方案於腦中風患者之成效 (2021),提出因為有 行動裝置、教育方案、腦中風、自我照顧知識、自我效能、憂鬱、滿意度的重點而找出了 Physical activity gu的解答。
Nanoporous Carbons for Soft and Flexible Energy Devices
為了解決Physical activity gu 的問題,作者 這樣論述:
Francesca Borghi is a Post-doctoral researcher in the Department of Physics at the University of Milano, and at the Interdisciplinary Centre for Nanostructured Materials and Interfaces. She graduated in Physics in 2011 from the University of Milano, and after that obtained her PhD in Physics in 2015
from the same university. Her main work deals with the characterization of the interfacial chemico-physical properties of nanostructured thin films, produced by low-energy clusters beam deposition in the gas phase. In particular, she uses atomic force microscopy for the characterization of the firs
t stage of growth of thin films in the sub-monolayer regime (metallic oxides, carbon, gold) and for the study of the structural and functional properties of granular thin films (surface charge density, elastic and electrical properties). In this frame, she won a national fellowship (Centro Universit
ario Cattolico) supporting the development of micro- and nano-structured networks for the characterization of the in-vitro behavior of spatially confined neuronal cells. Her research activity focuses also on the study of the structural, mechanical and electrical properties of ionic liquids confined
in porous matrices. She also developed a new approach for the characterization of the surface area and porosity of thin films by adsorption gas measurements.Francesca Soavi is an Associate Professor at the Department of Inorganic Chemistry "Giacomo Ciamician" of the University of Bologna. She gradua
ted with a degree in Chemistry in 1996 and in 2002 received her PhD in Chemical Sciences, with a Thesis on "Electrochemistry of materials for Energy Conversion and Storage". She is serving as a past-Chair of Division 3 ’Electrochemical Energy Storage and Conversion’ at the International Society of E
lectrochemistry. She is a co-author of more than 120 publications and she is involved in the knowledge transfer of research products by the StartUp BETTERY srl, that she co-founded in 2018. She has been awarded prestigious prizes in the context of electrochemistry of materials for energy storage/con
version devices. In 2019 she was the recipient of the Premio dei Premi prize awarded by COTEC-Fondazione per l’innovazione and the Senate of the Italian Republic.Paolo Milani is a Full Professor in the Department of Physics at the University of Milano. He graduated in Physics from the University of
Pavia (Italy) in 1984 and received his Docteur es Sciences (PhD) in 1991 from the Ecole Polytechnique Federale of Lausanne. In 1992, he founded the Molecular Beams and Nanocrystalline Materials Laboratory at the University of Milano. His research focuses on cluster-assembled nanostructured materials
for neuromorphic systems, stretchable electronics, biomedicine and soft robotics. He has published more than 250 papers in peer-reviewed journals, several review papers and a monograph on supersonic cluster beam deposition for the synthesis of nanostructured thin films. Prof. Milani was the recipie
nt of the U. Campisano Award, awarded to him from the Italian Institute for the Physics of Matter in 2000, for his contributions to the field of the synthesis and characterization of nanostructured materials. In 2006 he received the L. Tartufari Prize, awarded to him by the Lincei National Academy.
Currently, Prof. Milani serves as the Director of the Interdisciplinary Center for Nanostructured Materials and Interfaces at the University of Milano.
磁敏釋放控制微膠囊並應用於金屬離子螢光感測
為了解決Physical activity gu 的問題,作者杜博瑋 這樣論述:
微膠囊化技術因其在材料科學中的結構和功能性提供眾多優點而近年來受到廣泛的 關注。超分子化學是一門關注分子間非共價鍵作用力的化學學科,從中延伸出了很多 重要的概念和研究方向,例如分子螢光光探針,其螢光特性由其自身的分子結構決定, 但也容易受到環境因素的影響。在該方向上,本論文進行了詳細的研究,解釋了微膠 囊化技術與超分子化學完美的平衡組合,使其具有更好的穩定性和新穎的應用。首先 我們導入超分子化學概念通過一鍋反應合成的芘基衍生物,2((芘1亞甲基) 胺) 乙醇奈 米顆粒,和通過改質的磁性奈米顆粒用作觸發釋放元素通過雙乳化溶劑蒸發法包覆在 聚己內酯聚合物基質構建的微型膠囊中。用於檢測三價陽
離子的開關感測器通過新型 的螢光響應與磁場控制釋放機制被很好地整合在整個系統中,並且在外部震盪磁場下 可以有效地發生熱能與動能的轉換。(1) 通過一鍋法成功合成了具有聚集誘導光增強特性和三價陽離子感測能力的芘基衍 生物螢光探針。我們使用重結晶技術來提高該螢光探針化合物的純度,純度評估由螢 光光譜的半高寬的值確定。通過核磁共振光譜,紫外可見光光譜,螢光光譜和熱重分 析研究了選擇性螢光探針的特性。其聚集誘導光增強特性和對於三價陽離子 (鐵/鋁/鉻) 的選擇開關特性都表現完整且性能良好。在使用這種螢光探針作為核心材料被封裝在 微膠囊中之前,本節充分地研究了其基本特性,穩定的紫外可見光及螢光光譜的結果
是在溶劑 (乙腈) 和水 (100:900; 體積比) 的比例下進行的,強力的激發光在 505 nm,也 分別顯示出其對於三價鐵/鋁/鉻金屬陽離子優異的選擇性。(2) 為了成功通過外部震盪磁場觸發微膠囊的破裂,我們將利用共沉澱法合成並通過 檸檬酸修飾以達到避免團聚現象並提高其穩定性的磁性奈米顆粒嵌入聚合物基質中。 通過由動態光散射所測量到的粒徑分佈和界面電位以及掃描電子顯微鏡觀察到的圖 像,顯示出經過修飾的磁性奈米顆粒具有良好的分散特性和相對未修飾顆粒較小的粒 徑分佈。經過修飾的磁性奈米顆粒和選擇性熒光探針分子通過雙乳化結合溶劑蒸發法 成功封裝在微膠囊中,並通過光學顯微鏡,掃描電子顯微鏡,動
態光散射儀,熱重分i析儀,X 光散射儀,和核磁共振光譜儀對其表面形貌和特征進行了全面的研究。其結 果分別表明被修飾的磁性奈米顆粒和選擇性熒光探針確實有被微膠囊封裝在內,與此 同時,本節還深入討論了殼材料的高分子量的大小,雙乳化的內部水相濃度,以及在 分離微膠囊的離心過程中的離心速率的選擇,對合成微膠囊形貌以及包封效率的影響。 我們發現當聚合物外殼採用的分子量為 80,000 的聚己內酯時,所合成的微膠囊比其他 兩種較低分子量的顯示出更好的包覆效率和更加均勻的形狀,這主要是由於採用較高 分子量的高分子時,其油相在膠囊雙乳化狀態下的固化過程可以提供更好的穩定性。 此外,將溶解在乙腈中 10 mM
的熒光探針化合物作為內部水相的濃度與其他兩種濃度 (0.1 mM, 1 mM) 相比之下,也證明該濃度下所合成的微膠囊具有更好的均勻性和包覆 效率,因為較低濃度的內部水相會導致膠囊外殼內外滲透壓的不穩定。令人驚訝的是, 我們還發現在分離微膠囊的過程中,較高的離心速率會導致微膠囊的多孔性結構的產 生,這種現象可以通過調整較低的離心速率來消除。該策略同時也為未來開發新型多 孔性結構微膠囊的設計提供了一種新的途徑。在本節中,包覆了被修飾後的磁性奈米 顆粒和選擇性螢光探針的微膠囊的釋放行為和感測滴定分別以六十攝氏度的水浴加熱, 機械破壞,和超聲波粉碎的方式模擬其在磁場破裂的條件下進行,並且分別在不同狀
態下完美地測試了其結果。(3) 最後我們巧妙地設計了通過使用外部震盪磁場的方式來觸發芘基席夫鹼螢光 探針在微膠囊中的新型磁感應釋放機制。為了控制膠囊外殼的破裂,分散在乙腈/水 (900:100; 體積比) 中新合成的磁敏微膠囊通過直接感應加熱暴露在高頻磁場下。這些微 膠囊被成功觸發破裂釋放出所包覆的選擇性螢光探針,表現出優異的聚集誘導光增強 特性,和良好的選擇性開關螢光信號用於檢測三價金屬陽離子 (鐵/鋁/鉻)。被釋放的螢 光探針的檢測極限為:2.8602 × 10−6 M (三價鋁離子), 1.5744 × 10−6 M (三價鉻離子),和 1.8988 × 10−6 M (三價鐵離子)。
該感測器平台也表現出優異的精確度和再現性,如變 異係數所示 (三價鐵離子 ≤ 2.79%, 三價鉻離子 ≤ 2.79%, 三價鋁離子 ≤ 3.76%),各金屬離 子的回收率分別為:96.598.7% (三價鐵離子), 96.799.4% (三價鉻離子), 和 94.798.9% (三價鋁離子)。以上結果也充分說明了本文所述的控制釋放平台對於三價金屬陽離子 (鐵/鋁/鉻) 活性和實際樣品中的偵測,在未來環境監測甚至生物醫學方面的應用有一定 的價值和潛力。
Petrogenesis and Exploration of the Earth’s Interior: Proceedings of the 1st Springer Conference of the Arabian Journal of Geosc
為了解決Physical activity gu 的問題,作者 這樣論述:
Prof. Dr. Basem Zoheir is a full Professor of Mineralogy and Economic Geology at Benha University (Egypt), and now AvH fellow at Kiel Univ. (Germany). He was a DAAD doctorate at the Univ. of Munich (Germany), visiting researcher at the universities of Tubingen, TU Clausthal, Geneva, Stockholm, Graz,
TU Lulea, and a fulbrighter at the USGS DFC-Denver. Basem has published around 42 articles in international peer-reviewed ISI journals. He served as a reviewer and guest editor for a number of Geoscience journals, and as an examiner for several research funding institutions. Aside the academic work
, Basem provided consultations to national and international mining companies exploring for gold in the Nubian Shield.Dr. Domenico M. Doronzo holds a B.Sc., a M.Sc., and a Ph.D. degree (in 2011) in Earth Sciences from Università degli Studi di Bari Aldo Moro, Italy. Theses and specialties related to
the degrees are physical volcanology, experimental and computational fluid dynamics, petrology, and natural hazards. Then he has worked in volcanology and sedimentology, fluid dynamics and combustion, environmental sciences, and rock physics in the United States, Italy, and Mexico. He is currently
a contract Researcher at Consejo Superior de Investigaciones Cientificas, Spain. Particularly, he has received the Rittmann Medal (in 2014) from Associazione Italiana di Vulcanologia, which is assigned to the best young Italian volcanologist. His research interests focus on integrating theory, field
, numerical modeling, experiments and laboratory to study geological processes and products in volcanic areas from fluid dynamic and natural hazard perspectives. Particularly, he studies pyroclastic energy currents, sand and dust storms, turbidity currents, man-made environmental phenomena, and geor
esources. He has recently coordinated the Topical Collection on Dust for the Arabian Journal of Geosciences. He is an Associate Editor of the Arabian Journal of Geosciences responsible for evaluating submissions in the fields of Petrology, Volcanology, and Georesources, and also is an Assistant Edit
or supporting the Editor-in-Chief.Prof. Dr. Emanuela Schingaro holds a B. in Physics (1990), a Ph.D. in Earth Sciences (1994) from Università degli Studi di Bari (Italy).Presently she is associate professor of Mineralogy at Department of Earth and Environmental Sciences of Università degli Studi di
Bari ALDO MORO (Italy). The scientific activity is mainly focused in the field of the mineralogical crystallography (single crystal and powder X-ray diffraction). Research interests: crystal chemical characterization of complex silicate minerals; relationships between crystal chemistry and geologic
environments/petrogenetic conditions; clay minerals characterization; structure and disorder in rare mineral phases; thermal behavior of minerals and their solid state transformations. Collaboration with scientific societies: 2002-2004 Counselor of Italian Society of Mineralogy and Petrology (SIMP);
2007--2012 Counselor of the Gruppo Nazionale di Mineralogia (GNM); 2015-2017 Component of the Teaching Committee of the Associazione Italiana di Cristallografia (AIC) - Italian Association of Crystallography. From 1/12/2015 to 1/11/2018 Elected as Representative of the Scientific Area 04 (Earth Sci
ences ) in the Academic Senate. From 31/10/2014 to present: member of the Task Force of University of Bari Research. In 2018 she joined the AJGS as an Associate Editor responsible for evaluating submissions in the field of Mineralogy.Dr. John S. Armstrong-Altrin holds a MSc in Geology (1993) from Ma
durai Kamaraj University (V.O.Chidambaram College, Tuticorin, Tamil Nadu, India) and a Ph.D in Geology with a specialization in Sedimentology (1999) from University of Madras (India). He has completed his postdoctoral research (2003) at the Renewable Energy Institute (IER), Temixco, Mexico. He is cu
rrently a senior researcher at the Institute of Marine Sciences and Limnology of the National Autonomous University of Mexico, Mexico City. His research interests focus on sediment provenance, geochemistry, tectonic environments, and U-Pb geochronology of zircon grains. He has conducted a good numbe
r of research projects on coastal and deep-sea sediments of the Gulf of Mexico. He has published more than 60 research articles in indexed refereed Journals. He is one of the Associate Editors in the AJGS and responsible for evaluating submissions in the fields of geochemistry, sediment provenance,
sedimentology and tectonics.
行動裝置教育方案於腦中風患者之成效
為了解決Physical activity gu 的問題,作者余秋菊 這樣論述:
背景與目的:衛生福利部統計2019年腦血管疾病是造成臺灣地區民眾十大死因的第4名,腦中風發生的6個月內有超過25%的病患導致嚴重失能,慢性疾病皆是腦中風的致病危險因子,針對這些疾病的治療及控制是可降低腦中風的發生率,故需長時間監控及配合慢性疾病藥物治療,改變飲食習慣及建立良好的健康生活型態,提供病患出院返家後疾病相關知識。護理人員扮演著教育者的角色,傳統護理指導大部份給予紙本單張及口頭教育,然而現今資訊科技的進步及行動網路3C產品的普及化,可提供即時、個別化,是目前臨床照護上最即時及有效率的方式。因此,本研究探討行動裝置教育方案於腦中風病患提升自我照顧知識、自我效能及避免憂鬱之成效。研究方法
:本研究在臺灣北部某醫學中心之神經內科病房及老年醫學病房進行收案,採兩組前、後測,隨機、單盲之實驗性研究設計,收案82位,包括實驗組40位(行動裝置教育方案)及控制組42位(常規護理),分別於住院48小時內進行前測及介入,出院前24小時進行後測之施測。研究問卷包含腦中風自我照顧知識量表(Stroke Self-Care Knowledge)、腦中風自我效能量表(Stroke Self-Efficacy Questionnaire, SSEQ)、貝克憂鬱量表(Beck Depression Inventory, BDI)、健康指導內容滿意度之視覺類比量表(Visual Analogue Scal
e, VAS ),以套裝統計軟體SPSS 20.0版進行統計分析,進行描述性統計及推論性統計。描述性統計以次數分配、百分比、平均數、標準差、最大值及最小值呈現研究對象之人口學資料及疾病特徵;推論性統計以獨立樣本t檢定、卡方比較兩組在人口學基本屬性、疾病特徵、腦中風自我照顧知識、腦中風自我效能、憂鬱及介入措施滿意度之差異,運用廣義估計方程式(generalized estimating equation, GEE)檢定兩組之前、後測腦中風自我照顧知識、腦中風自我效能及憂鬱改善成效,再以獨立樣本t檢定統計比較兩組介入措施滿意度之差異。研究結果:本研究之研究對象為老年、男性、已婚、退休、高中職、佛道
教為主,共病指數(Charlson Comorbidity Index, CCI)平均值為2.28,過去病史以高血壓為主、其次為糖尿病。行動裝置教育方案介入後兩組腦中風自我照顧知識於組別主效果( β = 6.88, SE = .78, p < .001)、時間主效果( β = -6.15, SE = .71, p < .001)、組別與時間交互作用( β = -6.93, SE = .89, p < .001)皆呈統計學上顯著差異;腦中風自我效能(SSEQ)於組別主效果( β = 16.80, SE = 2.46, p < .001)、時間主效果( β = -33.66, SE = 2.78,
p < .001)、組別與時間交互作用( β = -6.46, SE = 4.02, p < .001)皆呈統計學上顯著差異;憂鬱(BDI)改善成效於組別主效果( β = -7.29, SE = 1.50, p < .001)、時間主效果( β = 8.37, SE = 1.77, p < .001)、組別與時間交互作用( β= 5.28, SE = 2.09, p < .001)皆呈統計學上顯著差異;以獨立樣本t檢定統計方式比較實驗組(行動裝置教育方案)與控制組(常規護理)的介入措施滿意度,呈統計學上顯著差異( p < .05),即表示此行動裝置教育方案介入措施的滿意度比常規護理有明顯成
效。結論:本研究結果證實透過行動裝置教育方案於腦中風患者,可以有效提升腦中風自我照顧知識、腦中風自我效能程度成改善憂鬱程度,行動裝置教育方案較傳統口頭健康指導有較高的介入滿意度。臨床與實務應用:在實證依據基礎下,使用行動裝置教育方案於腦中風患者之成效更較傳統口頭健康指導成效佳,且具有統計學上顯著差異。因應3C化數位時代來臨,手機及網路使用普及化,希望能藉由腦中風行動裝置教育方案方便性、健康指導內容生動性,且有具個別性的優點,能促進提升臨床護理人員在病患住院期間提供返家後健康指導內容,更能減少的時間人力成本。對於需要長期復健治療之腦中風患者更能提供持續性的照護內容,藉由操作行動裝置教育方案過程,
更可以促進患者與家人之間的親情互動,值得在臨床上推廣。