課程資訊
課程名稱
 高等電化學
Advanced Electrochemistry 
開課學期
 109-1 
授課對象
 生物資源暨農學院  生物產業機電工程學研究所  
授課教師
 陳林祈 
課號
 BME7908 
課程識別碼
 631 M9480 
班次
  
學分
 3.0 
全/半年
 半年 
必/選修
 選修 
上課時間
 星期五7,8,9(14:20~17:20) 
上課地點
 生機201 
備註
 限修過基礎電化學課程且成績及格者進階選修
總人數上限:10人 
Ceiba 課程網頁
 http://ceiba.ntu.edu.tw/1091advec 
課程簡介影片
 
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課程概述

本課程是專為從事電化學相關研究領域(如化學感測、生物晶片、能源元件、光電元件、光電催化與電鍍等領域)碩博士班學生所設計之高等課程,將教授Bard and Faulkner所著電化學領域經典教科書Electrochemical methods(2001版)後半部進階內容與當代電化學課題。授課內容含括擴散方程、流體力學、交流頻譜、掃描探針與同步光譜化學等技術在電化學分析領域之應用原理以及固態電極、化學修飾電極與半導體電極等電化學理論與應用,為研究生日後深入應用電化學、創新電化學應用乃至發展新電化學理論深化學術基礎。

<教師簡介>
授課教師研究領域為生物感測、奈米電化學與核酸適體,其在電化學領域有逾20年的研究經驗,所研究過的課題含括嵌入型電極電化學、電致色變材料與元件、半導體電極、太陽能電池、生物燃料電池、奈米觸媒電催化、以及近期的酵素電極、適體修飾電極與固態離子選擇電極等電化學感測技術。
 

課程目標
 讓修課學生學習並具備應用以下所列進階電化學知識之能力
․ 擴散方程於電分析化學之應用與理論模型發展
․ 流動分析與交流頻譜等高敏度電化學分析理論
․ 微觀尺度電極界面現象與複雜電化學反應機制
․ 固態電極、化學修飾電極與半導體電極之電化學理論
․ 新穎電化學分析技術原理與應用  
課程要求
 1. Students must complete a fundamental electrochemistry course or equivalent in advance.
2. Students must read through the textbook and complete the homework assignments.
3. Term paper (manuscript equivalent) is requested as the final exam-equivalent learning assessment.  
預期每週課後學習時數
  
Office Hours
 另約時間 備註: by appointment only 
指定閱讀
 Bard and Faulkner, Electrochemical Methods: Fundamentals and Applications, Wiley (2001). 
參考書目
 1. Wang (2006), Analytical Electrochemistry (3rd ed.), Wiley.
2. Atkins and Paula (2011), Physical Chemistry for the Life Sciences (2nd ed.),
Oxford.
3. Skoog, Holler, and Nieman (1998) Principles of Instrumental Analysis (5th
ed.), Saunders.
4. Electrochimica Acta: https://www.journals.elsevier.com/electrochimica-acta/
5. Electrochemistry Communications:
https://www.journals.elsevier.com/electrochemistry-communications/
6. Journal of Electroanalytical Chemistry:
https://www.journals.elsevier.com/journal-of-electroanalytical-chemistry
7. Journal of the Electrochemical Society:
http://jes.ecsdl.org/
8. Electroanalysis:
https://onlinelibrary.wiley.com/journal/15214109
 
評量方式
(僅供參考)
  
No.
項目
百分比
說明
1. 
 Homework Assignments 
60% 
  
2. 
 In-Class Discussions 
10% 
  
3. 
 Term Paper 
30% 
  
 
課程進度
週次
日期
單元主題
第1週
 09/18  Lecture 1: Basic Electrochemistry Review
1.1. Electrochemical potential and thermodynamics
(a) Simple Nernst equation (2.1.3, 2.1.5, 2.1.6) vs. the binary solution model for insertion electrochemistry (paper)
(b) Electrochemical potential equilibrium and applications to liquid junction and selective membrane (2.2.4, 2.2.5, 2.3, 2.4)
1.2. Electrochemical current and reaction kinetics
(a) Electrode kinetics (3.2, 3.3)
(b) Implications of the Bulter-Volmer model for the one-step, one-electron process (3.4)
(c) Applications to GOR (paper) 
第2週
 09/25  Lecture 2: Diffusion-Controlled Currents
2.1. Basics of mass Transfer (4.1, 4.2, 4.4)
2.2. Potential step under diffusion control (5.2, 5.8)
2.3. Diffusion-controlled currents at ultramicroelectrodes (5.3, 5.9)
2.4. General theory of controlled current methods (8.2)
2.5. Diffusivity determination and non-linear diffusion behaviors (paper)  
第3週
 10/02  No class (mid-autumn festival) 
第4週
 10/09  No class (national day) 
第5週
 10/16  Lecture 3: Voltammetry for Reversible Systems
3.1. Sampled-current voltammetry (5.4.1, 5.4.2)
3.2. Voltammetry for Nernstian systems (6.2)
3.3. Convolutive or semi-integral techniques (6.7)
3.4. Polargraphy (7.1.2)
3.5. Pulse voltammetry (7.3)  
第6週
 10/23  Lecture 4: Methods Involving Forced Convection
4.1. Theoretical treatment of convective systems (9.2)
4.2. Rotating disk electrode (9.3)
4.3. Convection at UMEs (9.7)
4.4. Electrodynamics and related phenomena (9.8) 
第7週
 10/30  Lecture 5: Electrochemical Impedance Spectroscopy
5.1. AC electrochemistry (10.1)
5.2. Faradaic impedance (10.2)
5.3. Kinetic parameterization (10.3)
5.4. Electrochemical impedance spectroscopy (10.4)
5.5. AC voltammetry (10.5)  
第8週
 11/06  Lecture 6: Bulk Electrolysis Methods
6.1. Flow electrolysis (11.6)
6.2. Thin-layer electrochemistry (11.7)
6.3. Stripping analysis (11.8)  
第9週
 11/13  Lecture 7: Electrode Reactions with Coupled Homogeneous Chemical Reactions
7.1 Classification of reactions (12.1)
7.2 Theory for transient voltammetry (12.3) 
第10週
 11/20  Lecture 8: Double-Layer Structure
8.1. Thermodynamics of the double layer (13.1)
8.2. Experimental evaluation of surface excess (13.2)
8.3. Models for double-layer structure (13.3) 
第11週
 11/27  Lecture 9: Studies at Solid Electrodes
9.1. Solid electrodes (13.4)
9.2. Specific adsorption (13.5)
9.3. Effect of adsorption of electroinactive species (13.6)
9.4. Double-layer effects on electrode reaction rates (13.7)  
第12週
 12/04  Lecture 10: Chemically Modified Electrodes (I)
10.1. Types, preparation, and properties of films and modified electrodes (14.1, 14.2)
10.2. Electrochemical responses of adsorbed monolayers (14.3) 
第13週
 12/11  Lecture 11: Chemically Modified Electrodes (II)
11.1. Overview of processes at modified electrodes (14.4)
11.2. Blocking layers (14.5)
11.3. Other methods of characterization (14.6) 
第14週
 12/18  Lecture 12: Scanning Probe Techniques
12.1. Scanning tunneling microscopy (16.2)
12.2. Atomic force microscopy (16.3)
12.3. Scanning electrochemical microscopy (16.4) 
第15週
 12/25  Lecture 13: Spectroelectrochemistry
13.1. Ultraviolet and visible spectroscopy (17.1)
13.2. Vibrational spectroscopy (17.2) 
第16週
 2021/01/01  No class (new year) 
第17週
 2021/01/08  Lecture 14: Other Coupled Characterization Methods
14.1. Electron and ion spectrometry (17.3)
14.2. Magnetic resonance methods (17.4)
14.3. Quartz crystal microbalance (17.5)
14.4. X-ray methods (17.6) 
第18週
 2021/01/15  Lecture 15: Photoelectrochemistry at Semiconductor Electrodes
15.1. Band theory (3.6)
15.2. Semiconductor electrodes (18.2.2)
15.3. Current-potential curves at semiconductor electrodes (18.2.3)
15.4. Photoeffects at semiconductor electrodes (18.2.4)
15.5. Surface photocatalytic processes at semiconductor particles (18.2.5)