走在汽車革命的路上論文書籍站
Contaminant的問題,透過圖書和論文來找解法和答案更準確安心。 我們找到下列包括價格和評價等資訊懶人包
Contaminant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 Multifaceted Bio-Sensing Technology 和的 Industrial Applications of Biopolymers and Their Environmental Impact都 可以從中找到所需的評價。
另外網站a bioadsorbent for chemical contaminant remediation - RSC ...也說明:Chemical contaminants such as heavy metals, dyes, and organic oils seriously affect the environment and threaten human health. About 2 million tons of waste ...
這兩本書分別來自 和所出版 。
國立臺灣海洋大學 食品科學系 張君如、凌明沛所指導 黃桂霞的 臺灣民眾攝食養殖文蛤之安全風險與健康效益評估 (2021),提出Contaminant關鍵因素是什麼,來自於文蛤、無機砷、鉛、危害商數、致癌風險、每週建議攝取量、抗氧化、抑制 α-amylase、抑制 sucrase、脂質累積。
而第二篇論文國立臺北科技大學 環境工程與管理研究所 曾昭衡所指導 李承恩的 各室內空氣清淨機制之去除細菌效能評估 (2021),提出因為有 細菌、室內空氣清淨機制、CADR值的重點而找出了 Contaminant的解答。
最後網站Contaminant Definition & Meaning - Merriam-Webster則補充:The meaning of contaminant is something that contaminates. How to use contaminant in a sentence.
Multifaceted Bio-Sensing Technology
為了解決Contaminant 的問題,作者 這樣論述:
Multifaceted Bio-sensing Technology introduces the different types of biosensors, their construction materials, configurations, production methods, and their uses in bioelectrochemical fuel cells (BEFC). It focuses on recent progress in the production of biosensing platforms/interfaces, their int
egration, design and fabrication, and their multifaceted applications in bioelectrochemical systems. The chapters explore the integration of genetic elements such as DNA, enzymes, and whole cells within these systems, and address environmental applications including wastewater contaminant detection,
toxicity, and bioremediation. Throughout, the book shows how rapid, minuscule, and affordable biocomponents can be produced for a variety of energy and environmental applications. This book provides a practical introduction to the production of biocomponents for bioelectrochemical devices and envir
onmental monitoring, and will be a useful reference for graduates and researchers involved in the application of bioelectrochemical systems, as well as those working more broadly in bioenergy, electrochemistry, biology, environmental engineering, and multidisciplinary research across those areas.
Contaminant進入發燒排行的影片
ซื้อเกมได้ที่ https://store.epicgames.com/legendauser/phoenix-point
Phoenix Point
พากย์ไทย แปลไทย เนื้อเรื่อง
Phoenix Point is a strategy video game featuring a turn-based tactics system that is developed by Bulgaria-based independent developer Snapshot Games. It was released on December 3, 2019 for macOS and Microsoft Windows, with Xbox One and PlayStation 4 ports arriving in 2020.
Phoenix Point is intended to be a spiritual successor to the X-COM series that had been originally created by Snapshot Games head Julian Gollop during the 1990s.
Phoenix Point is set in 2047 on an Earth in the midst of an alien invasion, with Lovecraftian horrors on the verge of wiping out humanity. Players start the game in command of a lone base, Phoenix Point, and face a mix of strategic and tactical challenges as they try to save themselves and the rest of humankind from annihilation by the alien threat.
Between battles, the aliens adapt through accelerated, evolutionary mutations to the tactics and technology which players use against them. Meanwhile, multiple factions of humans will pursue their own objectives as they compete with players for limited resources in the apocalyptic world. How players resolve these challenges can result in different endings to the game.
In 2022, Earth's scientists discovered an extraterrestrial virus in permafrost that had begun to melt. Only about one percent of the virus's genome matched anything recorded by scientists up to that time.[3] Named the Pandoravirus, humans and animals who came into contact with it mutated into horrific abominations. By the late 2020s, a global apocalypse began when melting polar icecaps released the Pandoravirus into the world's oceans. The alien virus quickly dominated the oceans, mutating sea creatures of every size into hybrid alien monsters capable of crawling on to land.
The oceans transformed in alien ways after which the Pandoravirus began to infect the world's landmasses with an airborne mutagenic mist. The mist was both a microbial contaminant and a conduit that networked the hive-mind of the Pandoravirus. Humanity was not prepared; everyone who failed to reach high ground where the mist could not reach succumbed to it. The monstrosities of this future world are intended to evoke themes of tentacles and unknown horror familiar to fans of H. P. Lovecraft. Likewise, the works of John Carpenter influence the themes of science fiction horror, particularly related to the mist that both hides alien monsters and creates them.
The game starts in 2047. The alien mist and monsters created by the Pandoravirus have overwhelmed and destroyed worldwide civilization, reducing the remnants of humanity to isolated havens that are sparsely spread across the planet. The Pandoravirus controls the oceans, contaminating all sea life, and has brought humans to the brink of extinction on land. Various factions control the havens of humanity, and they each have very different ideas of how to survive the alien threat.
臺灣民眾攝食養殖文蛤之安全風險與健康效益評估
為了解決Contaminant 的問題,作者黃桂霞 這樣論述:
文蛤是國人經常食用的水產品,具有保肝、抗氧化、抗癌及降膽固醇等機能,但養殖環境之重金屬會蓄積於文蛤體中,並依其暴露濃度及暴露族群可能對攝食民眾造成不同程度之危害,因此民眾茫然於食用文蛤是利是弊?本研究採集彰化縣、雲林縣與臺南市之養殖文蛤生樣品24件、熟樣品25件,分別以感應耦合電漿質譜法分析其鎘、鉻、銅、鉛、鐵、錳、硒與鋅之濃度,以高效液相層析再以感應耦合電漿質譜法分析其無機砷與甲基汞之濃度,結合風險評估模式、國家攝食資料庫、美國國家環境保護局與美國加州環境保護局等相關數據,推估國人各年齡層攝取養殖文蛤之食品安全風險。結果顯示,熟文蛤之無機砷平均濃度 (0.609 mg/kg) 高於衛生福利
部食品藥物管理署訂定之食品中污染物質及毒素衛生標準限量標準 (0.5 mg/kg)。整體而言,各年齡層族群攝入文蛤中無機砷所造成之非致癌風險高於其他重金屬,以0-3歲與3-6歲族群為例,攝入熟文蛤中無機砷之危害商數分別為 1.29 與 1.13,可能對人體造成色素沉著症與角化症。此外,本研究亦評估各年齡層族群攝入文蛤中無機砷與鉛之致癌風險,其中無機砷對人體造成之致癌風險大於鉛,0-3歲攝入熟文蛤中無機砷之致癌風險為5.79×10-4,長期食用可能會造成罹患皮膚癌之風險。另一方面將文蛤樣品以0.05% 蛋白酶於37C水解12小時製備水解物 (Hard clam hydrolysate, HCH
)。體外試驗顯示35 mg/mL HCH具抗氧化活性,其清除DPPH能力相當於 117.49 μM Trolox、螯合亞鐵離子能力相當於 95.62 μg/mL EDTA、還原力相當於 97.26 μg/mL Vitamin C。2.19 μg/mL HCH之 α-amylase抑制率為21.75%,但不具α-glucosidase抑制活性。人類腸道Caco-2 細胞以2.19 μg/mL HCH 處理具抑制sucrase 活性 ,相當於 62.5 μg/mL Acarbose。人類肝臟HepG2細胞以HCH處理無法促進葡萄糖攝入,但2.19與17.50 µg/mL HCH可延緩油酸誘導之脂質
蓄積。綜上,除了0-3歲與3-6歲族群攝入熟文蛤中無機砷外,各年齡層攝入文蛤中重金屬之危害商數皆小於1,為可接受風險;各年齡層族群攝入文蛤中無機砷與鉛之致癌風險,皆為不可接受風險。然而,文蛤蛋白水解物具抗氧化、降血糖及延緩非酒精性脂肪肝等活性,建議各年齡層族群適量攝取,每人每週可攝入熟文蛤量,0-3歲、3-6歲、6-12歲、12-16歲、16-18歲、19-65歲、65歲以上分別為 0.95、1.51、2.77、4.22、4.61、4.94及4.66 g/週。本研究成果可提供各年齡層攝取臺灣養殖文蛤之每週建議攝取量、呈現該食用量養殖文蛤潛在之人體健康效益。
Industrial Applications of Biopolymers and Their Environmental Impact
為了解決Contaminant 的問題,作者 這樣論述:
Dr. Abdullah Al Mamun has been working in the area of polymer science, chemistry and rheology of polymeric materials, natural fibre composites, and biodegradable materials for over 15 years. He obtained his Ph.D. in Biobased Material Composites Engineering in 2011 from the University of Kassel, Germ
any. His recent research work focuses on the development of cheap, multifunctional material for automobile applications, optimization of the compounding, moulding and forming process, and improvement of price/performance property of final products. Dr. Mamun has published several research papers in
peer-reviewed journals, books, and technical conference proceedings relevant to biobased materials, polymers, advance composites, and analysis of material. He is a member of the German Chemical Engineers Association, the Bio-Environmental Polymer Society, and National Plastic Engineering. He is a me
mber of the editorial board of the Greener Journal of Science, Engineering and Technological Research, the Greener Journal of Agricultural Sciences, and the Greener Journal of Biological Sciences.Dr. Jonathan Y. Chen has been working in the area of textile science and engineering for over 30 years.
Dr. Chen obtained his Ph.D. in Textile Engineering in 1995 from the University of Leeds, England. He is currently a professor in the School of Human Ecology and an affiliated faculty member of the Texas Materials Institute at The University of Texas at Austin. His current research focuses on the dev
elopment of bio-functional micro/nano cellulose fiber for medical textiles and energy saving apparels; production and evaluation of biobased nonwoven composites for automotive interior manufacture; and fabrication and characterization of activated carbon fiber materials for use in protective garment
s, water/air filtration, bio- and chemical-contaminant cleanup, and noise absorption and insulation. Dr. Chen is Fellow of The Textile Institute (CText FTI) and a member of the Bio-Environmental Polymer Society. He is serving the editorial boards for the Journal of Industrial Textiles and the Journa
l of Biobased Materials and Bioenergy. He has published numerous research papers in peer-reviewed journals, books, and technical conference proceedings relevant to textile materials, polymers, composites, bioresource technologies, and material testing.
各室內空氣清淨機制之去除細菌效能評估
為了解決Contaminant 的問題,作者李承恩 這樣論述:
摘要 iABSTRACT iii誌謝 v目錄 vi表目錄 x圖目錄 xii1 第一章 緒論 11.1 研究背景與動機 11.2 研究目的 21.3 研究流程 22 第二章 文獻回顧 42.1 我國室內空氣品質法規 42.1.1 生物氣膠特性及種類 52.1.2 細菌對人體之危害 52.1.3 生物氣膠採樣方法 92.2 空氣清淨機檢測標準 122.2.1 日本JEM 1467 檢測標準 122.2.2 中國GB/T 18801-2015檢測標準 152.2.3 中國GB 21551.3-2010檢測標準 172.2.4 中華民國CNS-7619檢測標準
182.2.5 美國AHAM AC-1檢測標準 202.2.6 AHAM AC-1之改良方法 232.2.7 臭氧排放濃度測試規範 242.3 空氣清淨機制去除原理 262.3.1 HEPA濾網 262.3.2 靜電濾網 272.3.3 光觸媒 282.3.4 靜電集塵(Electrostatic Precipitator, ESP) 292.3.5 UVC、UVA 312.3.6 二氧化氯、次氯酸 322.3.7 臭氧 342.3.8 負離子 353 第三章 研究方法 373.1 實驗規劃 373.2 實驗設備與儀器 383.2.1 室內空氣品質測試艙(Cha
mber) 383.2.2 室內空氣清淨設備 393.2.3 採樣儀器與設備 473.3 細菌實驗方法與流程 553.3.1 菌株破管與活化 553.3.2 培養基配置 583.3.3 採樣步驟 603.3.4 分析計算 643.4 細菌自然衰退率與淨化效能計算 673.4.1 細菌自然衰退率計算 673.4.2 室內空污淨化效能CADR值計算 683.5 室內二氧化氯、次氯酸容許暴露濃度計算 693.5.1 空氣中二氧化氯容許暴露濃度計算 693.5.2 空氣中次氯酸容許暴露濃度計算 704 第四章 結果與討論 724.1 各室內空氣清淨機制去除細菌實驗 72
4.1.1 細菌於測試艙內之自然率退曲線 734.1.2 細菌及PM2.5自然衰退濃度對比 734.1.3 HEPA濾網去除細菌之效能評估 754.1.4 靜電濾網去除細菌之效能評估 764.1.5 光觸媒濾網去除細菌之效能評估 774.1.6 靜電集塵去除細菌之效能評估 784.1.7 紫外線(UVC、UVA)去除細菌之效能評估 794.1.8 霧化消毒劑(二氧化氯、次氯酸)去除細菌之效能評估 804.1.9 臭氧去除細菌之效能評估 814.1.10 負離子去除細菌之效能評估 824.2 不同室內空氣清淨機制之去除細菌綜合比較 834.2.1 不同室內空氣清淨機制之去除
細菌效能綜合比較 834.2.2 不同室內空氣清淨機制去除細菌之CADR值綜合比較 854.2.3 各吸入型空氣清淨機制之CADR值換算為相同規格比較 884.2.4 細菌與PM2.5 CADR值比較 924.3 空氣清淨機臭氧空間濃度評估 934.4 空氣清淨機臭氧排放濃度評估 984.5 各空氣清淨機制去除細菌之能源效率綜合比較 1015 第五章 結論與建議 1035.1 結論 1035.2 建議 1046 參考文獻 1057 附件一 : 檢測儀器校正報告書 112附錄A 細菌去除實驗數據 113