Presentation is loading. Please wait.

Presentation is loading. Please wait.

CVEN 5424 Environmental Organic Chemistry Lecture 24 – Redox Reactions: Reduction.

Published byBertram Hunter Modified over 8 years ago

Similar presentations

Presentation on theme: "CVEN 5424 Environmental Organic Chemistry Lecture 24 – Redox Reactions: Reduction."— Presentation transcript:

1 CVEN 5424 Environmental Organic Chemistry Lecture 24 – Redox Reactions: Reduction

2 Announcements  Reading  Chapter 14, Sections 14.1-14.3  Problem sets  PS 8 due Thursday  PS 9 out Thursday Office hours (starting next week) Tuesday 11:30 am-1 pm Wednesday 9-10 am by appointment

3 Reduction Reactions  Predicting kinetics with rate LFERs  k R  redox potential (Marcus)  E H 1 ; usually first electron transfer (Eqn. 14-38) log k R E H 1 / 0.059

4 Reduction Reactions  Predicting kinetics with rate LFERs  k R  redox potential (Marcus)  E H 1 ; usually first electron transfer (Eqn. 14-38) log k R E H 1 / 0.059 Reduction: faster at higher E H (lower {e - }); able to give e - to compound at lower {e - }

5 Reduction Reactions  Predicting kinetics with rate LFERs  k R  redox potential (Marcus)  E H 1 ; usually first electron transfer  k R   (Hammett) (Eqn. 14-38) log k R E H 1 / 0.059 log k R  Reduction: faster at higher E H (lower {e - }); able to give e - to compound at lower {e - }

6 Reduction Reactions  Predicting kinetics with rate LFERs  k R  redox potential (Marcus)  E H 1 ; usually first electron transfer  k R   (Hammett) (Eqn. 14-38) log k R E H 1 / 0.059 log k R  Reduction: faster at higher E H (lower {e - }); able to give e - to compound at lower {e - } Reduction: faster at higher  ; easier to give electrons if more e - - withdrawing

7 Reduction Reactions  reductive dehalogenation (C reduced, X released)  R—X  R—H  R—CHX—CHX—R  R—CH=CH—R

8 Reduction Reactions  Reduction of carbon: reductive dehalogenation  R—X  R—H CCl 4 + H + + 2 e - = CHCl 3 + Cl - R—CHX—CHX—R  R—CH=CH—R

9 Reduction Reactions  Reduction of carbon: reductive dehalogenation  reducing conditions (e.g., anoxic)  promote breakdown of RX, removal of halogens  usually, products are less toxic  aliphatic (C 1 and C 2 ) – fast  olefinic (R=R-X) – relatively fast  aromatic (Ar-X) – slow (e.g., PCBs, chlorinated benzenes)  most reductants capable of reducing RX  high redox potentials mean easy to reduce

10

11

12

13 Reduction Reactions  Reductive dehalogenation  rate affected strongly by  ease of breaking the C—X bond  C—X bond strength  stability of carbon radical formed  electron-withdrawing substituents stabilize carbon radical

14 Reduction Reactions  Reductive dehalogenation  rate affected strongly by  ease of breaking the C—X bond  C—X bond strength  stability of carbon radical formed  electron-withdrawing substituents stabilize carbon radical  rate affected weakly by  tendency of C—X to accept electron (electronegativity)  stabilization of carbon radical by geminal halogen

15 Reduction Reactions  Rank the following three halogenated ethanes by order of reductive dehalogenation rate from slowest to fastest: compound X electro- negativity bond strength (kJ mol -1 ) 1,2-dibromoethane2.96281 1,2-dichloroethane3.16339 1,2-diiodoethane2.66216

16 compound t 1/2 (h) X electro- negativity bond strength (kJ mol -1 ) 1,2-dichloroethane>>9503.16339 1,2-dibromoethane552.96281 1,2-diiodoethane0.42.66216 << slowestfastest Reduction Reactions

17  Predicting kinetics – one example Reductive dehalogenation k R  bond strength and electron withdrawal BS: C—X bond strength (kcal mol -1 )  *: Taft constant (Table 12.4, SGI, 1993) BE: C—C or C=C bond energy (kcal mol -1 ) Peijnenburg et al. (1991) Science of the Total Environment 109/110, 283-300.

18 Reduction Reactions

19 compoundBS (kcal mol -1 ) ** BE (kcal mol -1 ) tetraiodoethene55.53.5253.8 1,2-diodoethane55.51.7663.2 1,2-dichloro-1,2-dibromoethane68.04.1463.2 hexachloroethane81.06.3063.2 2,3-dibromobutane68.01.8463.2 1,2-dibromoethane68.02.0463.2  -hexachlorocyclohexane 81.03.1563.2 tetrachloromethane81.04.2063.2 sym-tetrachloroethane81.04.2063.2 tetrachloroethene81.04.2053.8  -hexachlorocyclohexane 81.02.1063.2 1,2-dichloroethane81.02.1063.2 1,1-dichloroethene81.02.1053.8 1,2-dichloroethene81.02.1053.8 perfluorohexane1085.5063.2 perfluorodecaline1084.4063.2 Peijnenburg et al. (1991) Science of the Total Environment 109/110, 283- 300. Reduction Reactions

20  Example: 1,1,2,2-tetrachloroethane a.k.a., “sym-tetrachloroethane”  C-X bond strength, BS = 81 kcal mol -1  stronger C-X bond (e.g., C-F)  slower rate  Taft constant,  * = 4.20  more electron-withdrawing  faster rate  C-C bond energy, BE = 63.2 kcal mol -1  stronger C-C bond  faster rate Reduction Reactions

21  Example: 1,1,2,2-tetrachloroethane a.k.a., “sym-tetrachloroethane”  BS = 81 kcal mol -1   * = 4.20  BE = 63.2 kcal mol -1 Reduction Reactions

22  reductive dehalogenation (C)  R—X  R—H  R—CHX—CHX—R  R—CH=CH—R  quinone reduction (C reduction)  O=Ar=O  HO—Ar—OH

23 Reduction Reactions  Reduction of carbon: quinone reduction  O=Ar=O  HO—Ar—OH

24 Reduction Reactions  reductive dehalogenation (C)  R—X  R—H  R—CHX—CHX—R  R—CH=CH—R  quinone reduction (C)  O=Ar=O  HO—Ar—OH  nitroaromatic reduction (N reduction)  Ar—NO 2  Ar—NH 2  aromatic azo reduction (N reduction)  Ar-N=N-Ar  2 Ar—NH 2

25 Reduction Reactions  Reduction of nitrogen: nitroaromatic reduction  Ar—NO 2  Ar—NH 2  aromatic azo reduction  Ar-N=N-Ar  2 Ar—NH 2

26 Reduction Reactions  Reduction of nitrogen: nitroaromatic reduction

27 Reduction Reactions  reductive dehalogenation (C)  R—X  R—H  R—CHX—CHX—R  R—CH=CH—R  quinone reduction (C)  O=Ar=O  HO—Ar—OH  nitroaromatic reduction (N)  Ar—NO 2  Ar—NH 2  aromatic azo reduction (N)  Ar-N=N-Ar  2 Ar—NH 2  sulfoxide reduction (S reduction)  R—S(=O)—R  R—S—R

28 Reduction Reactions  Reduction of sulfur  sulfone reduction  R—S(=O) 2 —R  R—S(=O)—R  sulfoxide reduction  R—S(=O)—R  R—S—R sulindac (a NSAID) sulfide sulfoxide sulfone

29 Reduction Reactions  Need electron donors for reduction  aqueous species  H 2 S, HS -  Fe(II)  Mn(II)  NH 3  minerals, etc.  sulfide minerals (e.g., pyrite)  Fe(II) minerals (e.g., biotite)  Fe(0) in remediation

30 reduction of organic contaminants oxidation of reductants

31 Reduction Reactions  Zero-valent iron  permeable reactive barrier remediation  other metals also (Sn, Zn, etc.)  iron metal is oxidized  “rusting”  corrosion  Fe 0 = Fe 2+ + 2 e -  E H 0 (W) ~ -0.6 V  Promotes reductive dechlorination

32 Reduction Reactions  Permeable reactive barrier  maintain redox potential (Fe 0 supply)  avoid clogging  Commercialization  ARS Technologies ARS Technologies

33 CCl 4 + H + + 2 e - = CHCl 3 + Cl - Fe(0) = Fe 2+ + 2 e - CCl 4 + H + + Fe(0) = CHCl 3 + Cl - + Fe 2+ CHCl 3 + H + + Fe(0) = CH 2 Cl 2 + Cl - + Fe 2+ CH 2 Cl 2 + H + + Fe(0) = CH 3 Cl + Cl - + Fe 2+ CH 3 Cl + H + + Fe(0) = CH 4 + Cl - + Fe 2+

34 Reduction Reactions  Demonstrations for ZVI  halogenated alkanes, alkenes  DDT, DDD, DDE  pentachlorophenol  triazines (e.g., atrazine, RDX)  metals  Cr(VI), As(V)  U(IV)

35 Fe

36  Fe(0) reduction of chlorinated compounds:  methanes  ethanes  propanes  ethenes (Johnson et al., 1996, ES&T 30, 2634-2640) Reduction Reactions

37  Accounting for Fe(0) surface area  better correlation indicates surface process (Johnson et al., 1996, ES&T 30, 2634-2640) Reduction Reactions

38  Rate of reduction by Fe(0)  depends on compound concentration  depends on iron surface area, a s (m 2 g -1 )  k obs (h -1 )= k SA (L m -2 h -1 )  a Fe(0) (m 2 L -1 ) (Johnson et al., 1996, ES&T 30, 2634-2640) Reduction Reactions

39  Fe(0) mechanism(s)?  A) direct electron transfer from Fe(0) at surface  B) reduction by Fe 2+ generated by Fe(0), resulting in metal corrosion  C) catalyzed hydrogenolysis by H 2 formed by reduction of H 2 O during corrosion iron surface, mineral surface, or organic matter Reduction Reactions

40  LFER?  relating k SA to two-electron redox potential (E) of compounds ? (Johnson et al., 1996, ES&T 30, 2634-2640) Reduction Reactions

41  More representative redox potentials (Scherer et al., 1998, ES&T 32, 3026-3033) Reduction Reactions

42  LFERs  E LUMO, R 2 = 0.83  E 1, R 2 = 0.81 (Scherer et al., 1998, ES&T 32, 3026-3033) Reduction Reactions

43 Next Lecture  Oxidation Reactions

Download ppt "CVEN 5424 Environmental Organic Chemistry Lecture 24 – Redox Reactions: Reduction."

Similar presentations

Based on McMurry’s Organic Chemistry, 7th edition

Based on McMurry’s Organic Chemistry, 7th edition
10. Organohalides Based on McMurry’s Organic Chemistry, 7 th edition.

10. Organohalides Based on McMurry’s Organic Chemistry, 7 th edition.
CHAPTER 7 Haloalkanes.

CHAPTER 7 Haloalkanes.
Organic Reactions A detailed study of the following:

Organic Reactions A detailed study of the following:
Substitution Reactions of Alkyl Halides: Chapter 8

Substitution Reactions of Alkyl Halides: Chapter 8
Nomenclature and Properties of Alkyl Halides

Nomenclature and Properties of Alkyl Halides
Unit 4 Nomenclature and Properties of Alkyl Halides Synthesis of Alkyl Halides Reactions of Alkyl Halides Mechanisms of S N 1, S N 2, E1, and E2 Reactions.

Unit 4 Nomenclature and Properties of Alkyl Halides Synthesis of Alkyl Halides Reactions of Alkyl Halides Mechanisms of S N 1, S N 2, E1, and E2 Reactions.
Chapter 3: Acid-Base Chemistry Reaction Classification: Substitution: Addition: Elimination: Rearrangement: We’ll deal with these later…

Chapter 3: Acid-Base Chemistry Reaction Classification: Substitution: Addition: Elimination: Rearrangement: We’ll deal with these later…
Chapter 10. Alkyl Halides. What Is an Alkyl Halide An organic compound containing at least one carbon-halogen bond (C-X) –X (F, Cl, Br, I) replaces H.

Chapter 10. Alkyl Halides. What Is an Alkyl Halide An organic compound containing at least one carbon-halogen bond (C-X) –X (F, Cl, Br, I) replaces H.
10. Alkyl Halides Based on McMurry’s Organic Chemistry, 6 th edition.

10. Alkyl Halides Based on McMurry’s Organic Chemistry, 6 th edition.
Chapter 25: Functonal Groups and Organic Reactions.

Chapter 25: Functonal Groups and Organic Reactions.
Organic Reactions Dr. M. Abd-Elhakeem Faculty of Biotechnology Organic Chemistry Chapter 3.

Organic Reactions Dr. M. Abd-Elhakeem Faculty of Biotechnology Organic Chemistry Chapter 3.
Radicals There are 7 valence electrons around the C in this species. Would you expect this species to be stable? a. no b. yes c.not enough information.

Radicals There are 7 valence electrons around the C in this species. Would you expect this species to be stable? a. no b. yes c.not enough information.
FUNCTIONAL GROUPS Chemistry 122. Functional Groups In the previous chapter, the only organic compounds we looked at were hydrocarbons There were cases.

FUNCTIONAL GROUPS Chemistry 122. Functional Groups In the previous chapter, the only organic compounds we looked at were hydrocarbons There were cases.
Chlorination of Higher Alkanes: Relative Reactivity and Selectivity 3-6 The chlorination of ethane proceeds by a radical chain process analogous to that.

Chlorination of Higher Alkanes: Relative Reactivity and Selectivity 3-6 The chlorination of ethane proceeds by a radical chain process analogous to that.
Mechanisms One of the most practical aspects of organic chemistry is the study and application of chemical reactions. Due to the large number of reactants.

Mechanisms One of the most practical aspects of organic chemistry is the study and application of chemical reactions. Due to the large number of reactants.
Chapter 6 Alkyl Halides: Nucleophilic Substitution and Elimination

Chapter 6 Alkyl Halides: Nucleophilic Substitution and Elimination
1 Degradation of organic biocides What happens to biocides when they enter the environment? Two related aspects: 1)Chemical stability (mechanism & rate.

1 Degradation of organic biocides What happens to biocides when they enter the environment? Two related aspects: 1)Chemical stability (mechanism & rate.
John E. McMurry www.cengage.com/chemistry/mcmurry Paul D. Adams University of Arkansas Chapter 10 Organohalides.

John E. McMurry Paul D. Adams University of Arkansas Chapter 10 Organohalides.
Reactions of Benzene and its Derivatives

Reactions of Benzene and its Derivatives

Similar presentations

Ads by Google