Concept explainers
(a)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
(b)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
(c)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
(d)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
(e)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
(f)
Interpretation:
For the given species identify whether it withdraw electrons inductively or donates electrons by hyper conjugation, withdraws electrons by resonance or donates electrons by resonance.
Concept Introduction:
Electronic effect:
Electron donating groups decreases acidity by inductive effect (withdrawal of electrons through a sigma bond). Electron withdrawal increases acidity. Electron-donating substituents destabilize a base, and decrease the strength of its conjugate acid; electron-withdrawing substituents stabilize a base, which increase the strength of its conjugate base.
Rule: The strength of a base depends on the stability of its conjugate acid.
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Chapter 7 Solutions
Essential Organic Chemistry (3rd Edition)
- 2. For each of the following compounds draw a three-dimensional representation. a) (S)-2-chlorobutane b) (2R, 3S)-2,3-dibromohexane c) (R)-1,1,2-trimethylcyclohexanearrow_forwardBe sure to answer all parts. Name the following compound according to substitutive IUPAC nomenclature. OH (select) (select) (select) (select) 7 of 11 Next> < Prev C F5 PrtSc F6 F4 F7 F10 F8 F9 F3 F11 F12 & # 4 3 7 9 0 CO LO ASTarrow_forward1. For each compound, label the chemical equivalent hydrogens. Include cis-trans hydrogens on rings when they are inequivalent. Example: H₂C Br -CH₂ H₂C H₂C 8 CH₂CH₂ CH₂ CH₂arrow_forward
- 1) Which of the following Newman projections does not represent 2-methylhexane? CH3 CH(CH)2 H CH2CH3 H,C, H yOH,CH,CH,CH, H. H. CH3 CH2CH,CH, H. CH3 H. ČH,CH, CH,CH, 1 2 4 a. 1 b. с. 3 d. 4.arrow_forward1. Draw the most and least stable Newman projections for the following molecules (focus on C2 and C3). a. 2-chloro-2-fluoropentane b. 2,2-dimethylbutane c. 2-chloro-2-methylpentane d. 1,2-dibromoethanearrow_forward5. Chairs and E2 b. a. Draw the line-bond structure of (1R, 2S,3S)-1-ethyl-2-iodo-3-isopropylcyclohexane. Draw both chair flips of (1R, 2S,3S)-1-ethyl-2-iodo-3-isopropylcyclohexane. Showing all calculations, determine which is the more stable conformation. C. Which chair flip is able to undergo E2 elimination? Justify your answer. d. Show the product of such an E2 elimination using NaOEt as base.arrow_forward
- Without drawing out the structures, label each pair of compounds as enantiomers or diastereomers. a. (2R,3S)-hexane-2,3-diol and (2R,3R)-hexane-2,3-diol b.(2R,3R)-hexane-2,3-diol and (2S,3S)-hexane-2,3-diol c.(2R,3S,4R)-hexane-2,3,4-triol and (2S,3R,4R)-hexane-2,3,4-triolarrow_forwardFor centuries, Chinese herbal medicine has used extracts of Ephedra sinica to treat asthma. Ephedra as an"herbal supplement" has been implicated in the deaths of several athletes and has recently been banned as a dietary supplement. Phytochemical investigation of this plant resulted in isolation of ephedrine, a very potent dilator of the air passages of the lungs. Ephedrine also has profound effects on the cardiovascular system. The natu- rally occurring stereoisomer is levorotatory and has the following structure. Assign an Ror S configuration to each chiral center. H NHCH3 Ephedra sinica, the source of ephedrine, a potent bronchodilator. HO H CH3 Ephedrine [a -41arrow_forwardA. B. C. Me CH3 ClC H ¿ OH NH₂ H Br-C-C H3C H Br CH3 Comparing structure pair in B OH Comparing structure pair in C [Select] Me HC CI Comparing structure pair in A [Select] [Select] Same structure drawn differently Enantiomers Diastereomers NH₂ Br H3C CH3 Br HC-CCH3 H For the following two structures compared in parts A and B, determine whether they are enantiomers OR diastereomers OR the same structure drawn differently (non-bonding electrons not included for clarity).arrow_forward
- Rank the following groups in order of decreasing priority. a.−COOH, −H, −NH2, −OH b.−H, −CH3, −Cl, −CH2Cl c. −CH2CH3, −CH3, −H, −CH(CH3)2 d.−CH=CH2, −CH3, −C≡CH, −Harrow_forward4.) Which molecule in each pair is more stable? Hint: consider the potential resonance contributors CH₂ 1+ a. CH₂CH₂CCH₂ or CH₂CH₂CH=CHCH₂ b. CH₂ CH=CH₂ or CH CH=CHCH₂ 0™ c. CH3CHCH=CH₂ or CH₂C=CHCH3 +NH₂ d. 0™ CH₂ or +OH NH₂ CH₂ NH₂arrow_forwardWhat is the degree of unsaturation of C8H10ClNO? a. 4 b. 5 c. 6 d. 7arrow_forward
Organic Chemistry: A Guided InquiryChemistryISBN:9780618974122Author:Andrei StraumanisPublisher:Cengage Learning