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Electrochemical Phenomena in the Cathode Impedance Spectrum of Pem Fuel Cells: Fundamentals and Applications

為了解決PEM fuel cell的問題，作者Cruz-Manzo, Samuel,Greenwood, Paul 這樣論述：

Electrochemical Phenomena in the Cathode Impedance Spectrum of PEM Fuel Cells: Fundamentals, Modelling, and Applications establishes how the electrochemical and diffusion mechanisms of a polymer electrolyte membrane fuel cell (PEMFC) are related to electrochemical impedance spectroscopy (EIS) mea

surements using physics-based impedance models derived from fundamental electrode and diffusion theories. The contribution of the different phenomena occurring at the different layers comprising the cathode on the impedance response of the PEMFC is revealed through EIS-modelling analysis. The relati

on between EIS measurements and polarisation curves representing the performance of PEMFCs is established. Insight is gained into how the EIS response of the PEMFC changes at different operating conditions e.g. relative humidity, load demand, gas reactant stoichiometry and temperature using physics-

based impedance models. The application of impedance models with EIS measurements carried out in the individual cells comprising a PEMFC stack is demonstrated, while recent modelling approaches and other impedance models reported in the literature to represent the EIS response of the PEMFC are also

considered and discussed.

Direct Alcohol Fuel Cells for Portable Applications: Fundamentals, Engineering and Advances

為了解決PEM fuel cell的問題，作者Pinto, Alexandra M. F. R./ Oliveira, Vania B./ Falcao, Daniela S 這樣論述：

Direct Alcohol Fuel Cells for Portable Applications: Fundamentals, Engineering and Advancespresents the fundamental concepts, technological advances and challenges in developing, modeling and deploying fuel cells and fuel cell systems for portable devices, including micro and mini fuel cells. The au

thors review the fundamental science of direct alcohol fuel cells, covering, in detail, thermodynamics, electrode kinetics and electrocatalysis of charge-transfer reactions, mass and heat transfer phenomena, and basic modeling aspects. In addition, the book examines other fuels in DAFCs, such as for

mic acid, ethylene glycol and glycerol, along with technological aspects and applications, including case studies and cost analysis. Researchers, engineering professionals, fuel cell developers, policymakers and senior graduate students will find this a valuable resource. The book's comprehensive co

verage of fundamentals is especially useful for graduate students, advanced undergraduate students and those new to the field.Provides a comprehensive understanding of the fundamentals of DAFCs and their basic components, design and performancePresents current and complete information on the state-o

f-the-art of DAFC technology and its most relevant challenges for commercial deploymentIncludes practical application examples, problems and case studiesCovers the use of other fuels, such as formic acid, ethylene glycol and glycerol Alexandra M. F. R. Pinto obtained her PhD on Combustion in 1991,

after which she focused her activities on the transport phenomena area with particular interest in Mass Transfer and Characterization of two-phase flow patterns using advanced optical techniques. She integrated the know-how acquired with other skills of her core formation in chemical engineering in

to energy applications, in particular direct methanol and ethanol fuel Cells, microbial fuel cells, PEM fuel cells and hydrogen generators and storage systems. Dr. Pinto develops her research activities in the CEFT-Transport Phenomena Research Centre since its foundation in 1997, where she is presen

tly the leader of the Energy Group. She was principal investigator in nine national projects and participated in other 12 projects, including two with industry partners. She has also been a member of European Network FCTESTNET (Fuel Cell Testing and Standardisation Network). Currently, Dr. Pinto is

a professor at Renewable Energies and Chemical Engineering Laboratory of the Chemical Engineering Department of Porto University (DEQ-FEUP), Portugal, where she is director of the Doctoral Program in Chemical and Biological Engineering.

交聯聚苯并咪唑製備與性質探討及陰離子交換 膜燃料電池之應用

為了解決PEM fuel cell的問題，作者黃詩雯 這樣論述：

本研究以m-PBI 及2,2'-dimethylpoly(oxyphenylene benzimidazole) (Me-OPBI)為高分子主鏈，並於側鏈導入四級胺基團與末端炔官能基，以進料比、溫度與時間調控陰離子交換膜之離子交換容量與交聯比例，接著利用疊氮-炔環加成反應，將末端炔與1, 3-二疊氮丙烷進行交聯，並探討不同接枝率、交聯程度、交聯時間對於薄膜性質之影響，以及硫醇-烯加成反應與疊氮-炔環加成反應進行交聯後性質之比較。以m-PBI 為主鏈之聚苯并咪唑起初在接枝過程遇溶解度不佳之問題，IEC 若低於2.85 mmol/g 即無法溶於有機溶劑中，將乙基導入結構中可有效改善溶解度，且可調

IEC 範圍可擴大從0.76 至2.65 mmol/g。交聯後之薄膜吸水率介於10-45%，溶脹率為0.3-17%，結果顯示交聯可使尺寸穩定性更佳且有效抑止吸水率，於乾溼膜狀態亦有良好之機械性質。導入乙基後之氫氧根離子傳導率在80°C 下可提升至106.7 mS/cm，並更進一步利用AFM、SAXS 分析薄膜之離子簇尺寸。高IEC之薄膜在60°C 1 M KOH 鹼性環境中720 小時後，80°C 之傳導率還保有大於80%。電池功率的部分，以操作溫度60 ℃、氫氣/氧氣量測下可得到576.9 mWcm-2 之單電池功率密度。將本研究與硫醇-烯加成反應進行交聯後的薄膜比較性質，顯示疊氮-炔環加成

反應進行交聯之薄膜具有良好之熱性質與鹼性穩定性。本研究同時以Me-OPBI 含有醚鏈的主鏈高分子進行薄膜性質之探討，交聯後薄膜之長度與厚度溶脹率分別只有3.2%及5.3%，吸水率只有25%，80 °C 下之陰離子傳導率可達140.2 mS/cm。薄膜在60°C 1 M KOH 鹼性環境中720 小時後，80°C 之傳導率損失小於20%。以上結果顯示本研究所製備之陰離子交換膜具備足夠性質應用於燃料電池。