Alkene Reactions, Alkene Addition Reactions, Alkene Reactions (Orgo Chps. 7 & 8), Ochem Alkene Addition Reagents, Alkene practice, alkene/alkynes, Alkene Additions, Reactive Intermediates, Organic Chemistry 1- CH8- Alkene Reactions, Alkene Reactions,...

Hammond's postulate

"For an endothermic reaction, the structure and energy of the transition state resembles the structure and energy of the product"

DMS- Dimethylsulfate

((CH3)2S)

Hydrohalogen

(1)an alkene p system accepts a proton (H+) from an acid (HX) [the acid transfers a proton to the alkene], generating a carbocation; (2) the halogen anion combines with the carbocation.

Cleavage of 1,2 diols

(Its own category)

Dihydroxylation

(hydroxylation) the addition of two hydroxyl groups, one at each carbon of the double bond; formally, an oxidation

Allylic System Resonance (2) *

(write down)

Benzylic System Resonance (4) *

(write down)

[Hot alkaline] Potassium Permanganate Oxidation

*Gives cleaved alkene using KMnO4/H+ or KMnO4/Δ to get a ketone/aldehyde

Ozonolysis

*Gives cleaved alkene using O3/DMS to get a ketone/aldehyde 1. O3 reacts with alkene - forms cyclopentane 1a. Cyclopentane breaks to form two C=O bonds ([C=O(+)-O(-)] and [C=O]) 1c. Cyclopentane reforms and gives a free O and the two carbonyl groups 2. Addition of DMS: O attaches to S (DMS has resonance)

Simmons-Smith Reaction

*Gives unsubstituted cyclopropanes 1. ch2I2 and Zn(Cu) becomes CH2I and ZnI to attack double bond 2. Form [cis] cyclopropane

Diazomethane

*Wolff Rearrangement? *Carboxyl reacts with CH2N2 to make methyl ether 1. H in carboxyl group is lost to C anion in CH2N2 2. O anion in carboxyl reacts with CH3 and CH3-N2 bond is lost to N --> gives methyl ether

Hydrogenation

*alkene to alkane via syn addition H2/catalyst (Pd/C) or (Pt)

Halohydrins From Alkenes

-Addition of HX -Another example of an electrophilic addition is the reaction of alkenes with hypohalous acids (HO-Cl or HO-Br) to yield 1,2 haloalcohols called _________ -Previously saw when Br₂ reacts with an alkene the cyclic bromonium ion intermediate (R₂Br+) reacts with the only nucleophile present, Br- ion •but, if the reaction is carried out in the presence of an additional nucleophile, the intermediate bromonium ion can be intercepted by the added nucleophile and diverted to a different product •In the presence of a high [water], water competes with Br- ions as a nucleophile and reacts with the bromonium ion intermediate to yield a bromohydrin

Hydration of Alkenes: Addition of H₂O by Oxymercuration

-Addition of H₂O by _____ -Water adds to alkene to yield alcohols through a process called ___ -Reaction occurs by treating the alkene with water and a strong acid catalyst (H₂SO₄) by mechanism similar to that of HX addition •Protonation of an alkene double bond yields a carbocation intermediate, which reacts with water to yield a protonated alcohol product ROH₂+ --Loss of H+ from protonated alcohol gives the neutral alcohol and regenerates the acid catalyst -In the lab, alkenes are often ____ by the oxymercuration-demurcuration procedure ---Oxymercuration: electrophilic addition of Hg2+ to the alkene on reaction with mercury (II) acetate (Hg(CH₃CO₂)₂) in aqueous tetrahydrofuran solvent ---Intermediate organomercury compound then treated with NaBH₄ and demurcuration occurs to produce an alcohol -Regiochemistry of the reaction corresponds to Markovnikov addition of water: •OH group attaches to the more highly substituted carbon atom •the H atom attaches to the less highly substituted carbon -The H that replaces mercury in the demercuration step can attach from either side of the molecule, depending on the exact circumstances

Hydroboration-Oxidation

-BH3 -H2O2, NaOH Adds OH anti markov syn addition

Oxymercuration-Reduction

-Hg(OAc)2, H2O -NaBH4 Followed by reduction Converts alkenes to alcohols markov (adds OH)

Hydration of Alkenes: Addition of H₂O by Hydroboration

-In addition to the oxymercuration-demurcuration method (yields Markovinkov product), a complementary method, _____ , is also useful -yields anti-Markovinkov product -______: reaction involves addition of a B-H bond of Borane (BH₃) to an alkene to yield organoborane intermediate (RBH₂) ---Oxidation of the organoborane by reaction of basic hydrogen peroxide (H₂O₂) then gives an alcohol -Borane is very reactive as a Lewis acid because the boron atom has only 6 electrons in its valence shell; In tetrahydrofuran solution, BH3 accepts an electron pair from a solvent molecule in a Lewis acid-base reaction to complete its octet and form a stable BH3-THF complex

Halohydrin From Alkene Mechanism

-Mechanism: product formed by reaction of alkene with X₂ in the presence of water (acts as a nucleophile) to react with intermediate R₂B+/R₂Cl+ ion instead of Br-/Cl- 1.) reaction of alkene with X₂ yields a bromonium/chloronium ion intermediate 2.) water acts as a nucleophile using a lone pair of electrons to open the bromonium/chloronium ion ring and form a bond to carbon; since oxygen donates its electrons, it now has a (+) charge 3.) Loss of a proton (H+) from oxygen then give H3O+ and the neutral bromohydrin/chlorohydrin addition product -few alkenes are soluble in water and bromohydrin formation is often carried out in a solvent such as aqueous dimethylsulfoxide (CH₃SOCH₃) using reagent N-bromosuccinimide (stable easily handled and slowly decomposes in water to yield Br₂ at a controlled rate) as a source of Br₂ -formation, like halogenation, is carried out by haloperoxidases in biology

Halohydrin Formation

-Solvent does not act as nucleophile -Solvent is H2O -ends with a halogen substituent and OH substituent -X2 and H2O Markov w/OH anti-addition

Halogenation of Alkenes

-addition of X₂ -Br₂ and Cl₂ add rapidly to alkenes to yield 1,2-dihalides through _______ -When performed on a cycloalkene only trans stereoisomer is formed rather than the mix of the cis/trans isomers expected if a planar carbocation intermediate were involved -Reaction occurs with stereochemistry (two halide atoms come from opposite faces of the double bond--one from the top and one from the bottom) -Reaction intermediate is not a carbocation but instead is a bromonium/chloronium ion (R₂B+ or R₂Cl+) by electrophilic addition of Br+/Cl+ to the alkene •formed in a single step by interaction of the alkene with Br₂+ and simultaneous loss of Br- -Primarily limited to marine organisms living in halide-rich environments •carried out by haloperoxidases (use H₂O₂ to oxidize Br- and Cl- ions to a bio equivalent of Br+ or Cl+) •yields a bromonium or chloronium ion intermediate just as in the lab and reaction with another halide completes the process

Halogenation

-adds X2 -only done for Cl2 and Br2 -F2 is too violent (many side products) -I2 undergoes addition but has very unstable product -solvent is CHCl3 -Anti addition -stepwise addition -no carbocation

stereoselective (in comparison to stereospecific)

-one stereoisomer formed more than others -rxn has a choice of pathways but one is preferred over the other

stereospecific

-stereochemistry of starting material determines stereochemistry of product -no choice involved

Hydrogenation

-typically H2 and Pt -gets rid of double bonds -Arene ring will be unchanged syn addition

Radical molecule reaction types

1. Abstraction (transfer) 2. addition to multiple bonds (produce radicals)

Hydroboration/Oxidation

1. BH3 (H-BH2) + THF / 2. H2O2 + NaOH *BH2 on LEAST substituted C of double bond *H2O2 replaces BH2 with OH (or simply just place OH on least substituted C)

Dichlorocarbene

1. Base (-O of NaOH) attacks H in chloroform to make H2O 2. C(Cl)3 loses a Cl to make a carbene 2. Carbene reacts w alkene to make dichlorocarbene cyclopropane

Radical-radical reaction types

1. Combination 2. Disproportionation

Radicals may be stabilized by:

1. Delocalisation 2. Adjacent groups (captodative effect) 3. Steric effects

Unimolecular radical reaction types

1. Fragmentation (ß-scission) 2. Rearrangement

hydrogenation/reduction (alkyne)

1. H2, Pd/C = alkane 2. H2, Lindlar's cat = cis alkene 3. Li, NH3 = trans alkene

Acid-Catalyst and Water

1. H3O attack on double bond (OH on more subt.) 2. H2O attack on carbocation, H2O attack on H2O to form OH and H3O+

Oxymercuration/Demercuration

1. Hg(OAc)2 followed by 2. NaBH4 *attack on double bond --> Mercurmium Ion Interm. *H2O attacks more substituted carbon (lose an H) *NaBH4 replaces Hg(OAc)2 with H

Nitrene reaction types

1. Insertion into CH bond 2. cycloaddition to alkenes and arenes 3. Hofmann Rearrangement (amide -> amine with loss of C)

Dihydroxylation

1. OsO4 attacks double bond to form cyclic, osmate ester 2. H2O2 attacks O-C bonds to form two syn/cis diols

Electron transfer reaction types

1. Oxidation 2. Reduction

Radical carbon to carbon bond formation types

1. Pinacol reaction (2 ketones -> diol) 2. addition to an unsaturated compound 3. intramolecular reactions

Radical Generation Types

1. Thermal cleavage of bonds 2. Photochemical cleavage of bonds 3. Electron transfer reactions (redox)

Alternatives to tributyltinhydride

1. Tributyl germanium hydride Bu3GeH - non-toxic and easier to remove -> not very stable so has to be made immediately before use from GeCl4 (expensive) and Bu3MgBr. 2. Tristrimethylsilyl silane (Me3Si)3SiH - non-toxic and easy to remove -> used under argon and is expensive. Also has a tendency for the (Me3Si)3Si radical to add directly to double bonds

Halogenation

1. X-X attack double bond to form cyclopropane intermediate 2. Add X ion to form trans-vicinal or anti-

Halohydrin Formation (Hypohalous acids)

1. X-X attack on double bond 2. H2O attack (twice) to form trans/anti *If alkene is NOT symmetrical, -OH is on the MORE substituted C. IF symmertrical, doesn't matter.

Autoxidation reaction examples

1. alkylarenes 2. ethers

bromination of (R)-4-tert-butylcyclohexene

1. bromine atoms must add in an axial manner, each bromonium ion intermediate reacts with bromide ion to give the same product. 2.the presence of the bulky tert-butyl group controls the orientation of the two bromine atoms adds to the ring.

Arynes - generation types

1. from aryl anions 2. from zwitterions 3. from aryl triflates

Nitrenes - generation types

1. from azides (contain N+=N-=N) 2. By α elimination reactions (base needed)

Arynes - reaction types

1. nucleophilic addition 2. 2,4-addition to 1,3-dienes 3. 2,2-addition to alkenes

Radicals - types of reaction

1. radical radical reactions 2. radical molecule reactions 3. Unimolecular radical reactions 4. Electron transfer reactions

Features of electrophiles

1. region of low electron density 2. lack of octet 3. relatively weak bond to atom that can make stable ion/molecule

Halohydrine(Br2/H2O)

1. trans-addition 2)it is limited to introducing the OH group at the more highly substituted carbon, according to Markovnikov; 3)carbocation rearrangements may interfere with or prevent the synthesis of a desired alcohol by that method

Disadvantages of tributyltinhydride

1. very difficult to remove tin residues after rxn is complete 2. tin v. toxic - so limited use in pharmaceutical synthesis

Oxymercuration

3 membered ring, markovnikov, syn and anti

Bromination

3-membered ring, N/A (regiochemistry), anti

Halohydrin formation

3-membered ring, markovnikov, anti

Chlorination

3-membered ring, n/a, anti

Hypohalous Acids via NBS/DMSO/Water *

?

Glycol

A compound with hydroxyl(-OH) groups on adjacent carbons.

enantioselective

A reaction that produces one enantiomer in preference to the other.

stereospecific reaction

A special type of stereoselective reaction in which the stereochemistry of the product is dependent on the stereochemistry of the starting material.

Roles of ABCN and Bu3SnH in the reduction of alkyl halides

ABCN is the initiator, tributyltin hydride is the radical carrier

Radicals - intramolecular reactions - reaction conditions

AIBN and tributyltinhydride (small amount), Br-hydrocarbon turns into hydrocarbon radical, PhMe as solvent

Hydrohalogen#2(trans)

Above is a two-step reaction - the first step is regiorandom (because the carbons are equivalent); in the second step one stereocenter is generated. Because this step is stereorandom, a racemate is formed.

Hydrohalogen#3(no chiral center, trans alkene)

Above is a two-step reaction - the first step is regiospecific, generating the more stable carbocation; in the second step a new stereocenter is generated. However, the addition of Br- is stereorandom; therefore a racemate is formed.

Mark

Acid catalyze hydration

Hydrohalogenation

Acid catalyze hydration and ___ have carbocation intermediates

H2O, H2SO4

Acid-catalyzed hydration Markovnikov Carbocation rearrangements possible Alkene -> Add H, OH

catalytic hydrogenation

Adding H2 (g) across a carbon-carbon double bond in the presence of a transition metal catalyst Product: alkane

Acid Catalyzed Hydration

Adding OH to break the pi bond and hydrogen is put on the most and least substituted carbon while OH is added to the tertiary (?) carbon

Radical Polymerization

Addition Reaction

Carbenes

Addition Reaction 1. Dichlorocarbene Addition 2. Simmons-Smith Reaction

Addition of Halogens (Cl2 or Br2)

Addition Reaction Anti-addition observed through a *halonium* intermediate

Hydroxylation by acid catalyzed epoxide hydrolysis

Addition Reaction Anti-stereochemistry occurs

Addition of HCl or HBr

Addition Reaction Markovnikov

Halohydrin Formation

Addition Reaction Markovnikov Anti-stereochemistry

Catalytic Hydrogenation

Addition Reaction Syn addition occurs

Epoxidation with a peroxyacid

Addition Reaction Syn addition occurs

Hydroxylation with OsO4

Addition Reaction Syn addition occurs

Hydroboration/Oxidation

Addition Reaction The addition of water via this process Non-Markovnikov

Oxymercuration

Addition Reaction The addition of water via this process Markovnikov

Reactions with Carbocation Intermediates (2)

Addition of HX to an Alkene Addition of water and an acid catalyst (has rearrangement)

Markovnikov Alcohol

Addition of X to more substituted C and H to C with more H's (Regioselective) ; most likely major product

Acid Catalyzed Hydration

Addition of water across double bond, needs a strong acid catalyst, involved carbocation intermediates

X2/H2O

Adds 1 OH and 1 halogen, OH is markonikov, No carbocation intermediate

Acid Catalyzed Hydration features

Adds OH at more substituted carbon H2SO4 and H2O Carbocation intermediate markov addition

Halogenation

Adds halogens (Cl2 and Br2) No carbocation Adding 2 of the same halogen across the pi bond Anti addition and bridge intermediate Product= alkyl dihalide Ignore regiochemistry Can also give rise to meso compound if starting compound is symmetrical Arrow?

Reaction: Ozonolysis

Aldehyde

1) O3 2) Me2S

Aldehyde/Ketone

Reaction: Potassium Permanagante

Aldehydes are oxidized to Acids

42

Alkene pKa

1.Mg 2.Co2 3.HCL

Alkyl halide to carboxylic acid

Cl2, heat

Allylic halogenation Alkene -> Cl-C-C=C

Reaction: Addition of Halogens

Anti

Reaction: Anti Dihydroxylation

Anti

1) MCPBA (RCO3H) 2) H3O+

Anti Dihydroxylation Trans addition Epoxide intermediate Alkene -> Add OH, OH

Oxymercuration-Demercuration

Anti addition No carbocation H+ and OH across pi bond Form bridge intermediate Product= alcohol Regiospecific - only mark made Want reducing agent (NaBH4) Arrow?

1) RCO3H 2) H3O+

Anti addition adds OH to each double bonded C

X2

Anti addition adds halogen to each double bonded C

Reaction: Hydroboration-Oxidation

Anti-Markovnikov Syn

Hydroboration/Protonolysis*

Anti-Markovnikov Alc. 1.

HX ROOR

Anti-Markovnikov addition Mixed addition adds X to least substituted C

1) BH3 * THF or B2H6 2) H2O2, NaOH

Anti-Markovnikov addition Syn addition adds OH to least substituted C OH and H cis/syn

Halogen Addition/ Br2 Addition/ Bromination/ Alkene Addition (Br2)

Anti-addition halonium ion (bromonium ion) intermediate

Halohydrin (Bromohydrin) formation (Br2, H2O in excess)

Anti-addition substitution with inversion (OH adds on side opposite Br) OH adds on most substituted carbon, Br adds on least substituted halonium ion intermediate

halogenation (X2 w/ CCl4)

Anti-syn

Dihydroxylation (mcpba w/ H3O+)

Anti-syn addition

X2

Anti/trans "triangle" intermediate

π radical example

Benzyl (PhC•H2), PhO•, PhN•R, allyl

Radicals - addition to unsaturated compounds - reaction conditions

Best result if alkene has EWG substituent, AIBN and tributyltinhydride for initiation

Ozonanylsis

Break alkenes Every pi bond breaks to form double bonded oxygens (on both carbons) Get ketones, aldehydes, carboxcylic acids Reducing and oxidizing (more oxygens) Disub; monsub

Br2, CCl4

Bromination Anti addition Alkene -> Add Br, Br

Reduction of alkyl halides - initiation produces

Bu3Sn• radical

forms what in first step

C+ intermediate

Aldehyde

C=O and one alkyl group and an H

Ketone

C=O and two alkyl groups

Chloroform

CHCl3 -used in Dichlorocarbene rxn

Carbenes - structure and reactivity

Carbenes are neutral, electron deficient (6 e-) and highly reactive, with 2 non-bonded electrons. Most carbenes have triplet ground states as this is slightly lower in energy as both single electrons are in individual orbits. But if the adjacent atom has a lone pair then the ground state may be a singlet due to π donation. Electrophilic, since they are e- deficient.

Addition of HX

Carbocation, markovnikov, syn and anti

Hydration

Carbocation, markovnikov, syn and anti

Radical addition

Carbocation?, anti, syn+ anti

Creating Alcohols

Carbocations are reactive intermediates; they react with various nucleophiles, not just halide ions. H+ catalyzed addition of H2O leads to alcohols. (Use H2SO4 because - OSO3H is a poor Nu, doesn't add like Br-) The first step is equivalent to that of hydrohalogenation.

hyperconjugation

Carbocations of higher degree are more stable beacue of the ability of surrounding carbons to share electrons more effectively with the carbocation, and the effect of ______ (when an empty p-orbital can share e-s of antiperiplanar atoms).

sp2

Carbons in 1 double bond on an alkene are ___ hybridized.

sp3

Carbons with tetrahedral geometry are ___ hybridized.

stereospecific syn

Catalytic hydrogenation

Reaction: Olefin Metathesis

Cis and Trans

Ozonolysis

Cleavage with reductive or oxidative work ups

Ozonolysis (O3 w/ (CH3)2S) or (O3 w/ H2O2)

Cleaves pi-bond

1) O3 2) Me2S

Cleaves the C==C bond O== adds to each C in the original alkene

Hydrogenation

Concerted, N/a, syn

Hydroboration

Concerted, antimarkovnikov, syn addition

Dihydroxylation

Concerted, n/a, SYN

Cyclepropanation

Concerted, n/a, syn

Epoxidation

Concerted, n/a,syn

stereospecific syn

Dihydroxylation

Alkene + RCO3H

Direct epoxidation. draw RCO3H ring like with O-H towards alkene

Captodative effect

EWG/EDG may stabilise radical due to lower energy levels

halohydrin formation (X2 w/ H2O)

Enantiomers are present anti-markovnikov anti-syn NO CARBOCATION INTERMEDIATE!

atropisomers

Enantiomers that lack a chiral center and differ because of hindered rotation.

stereospecific syn

Epoxidation

Syn

Epoxidation addition

mCPBA

Epoxidation reagent

Alkene + C2H4O3 (peroxyacid)

Epoxide! ie O ring + CH3COOH

HBr with Peroxides

Favor non mark- least sub carbon Br is added to least substituted carbon Make tertiary radicals (stability) Make radical intermediate

X2, anti, neither

For a halogenation reaction, ____ is the reagent and the two atoms from that reagent add in a (syn/anti/either) addition. This product is (anti/not anti/neither) Markovnikov.

X2, H2O, anti, not anti

For a halohydration reaction, ____ & ___ are the reagents and the two groups from that reagent add in a (syn/anti/either) addition. This product is (anti/not anti/neither) Markovnikov.

HA, H2O, either, not anti

For an acid catalyzed hydration reaction, ____ & ___ are the reagents and the two groups from that reagent add in a (syn/anti/either) addition. This product is (anti/not anti/neither) Markovnikov.

H3C/Mgbr

Gringard reaction ketone or aldehyde to alcohol

Hydrohalogenation using the ROOR (peroxide or extreme heat or light)

H is added to the most substituted place and halogen is added to the least substituted place; not syn or anti

electrophile

H+ adds to sp2 C bonded to most H

Rank relative reactivity HCl HBr HI HF

HF < HCl < HBr < HI

Hydrohalogenation

Halogen to a hydrogen; Halogen is the most substituted while hydrogen is the least substituted; pi bond is broke; carbocations form so rearrangements happen (not syn or anti addition)

stereospecific. anti-addition because they add one at a time.

Halogenation

Anti

Halogenation addition

Anti

Halohydrin addition

Br2, H2O

Halohydrin formation Anti addition -OH more substituted Alkene -> Add Br, OH

Radicals formed when bond is broken...

Homolytically

Anti mark

Hydroboration

stereospecific syn

Hydroboration-oxidation

1) BH3, THF 2) H2O2, NaOH

Hydroboration-oxidation Anti-markovnikov Syn addition Alkene -> Add H, OH

Reactions that form Alcohols (4)

Hydroboration/Oxidation (anti-Markov. alc.) HBr and Peroxides (anti-Markov. alc.) Acid-Catalyst and water (Markov. alc.) Oxymercuration/Demercuration (Markov. alc.)

Reactions that require Stereochemistry (7) *

Hydroboration/Oxidation (cis/syn) Hydroboration/Protonolysis (syn) Halogens[X2] (trans- vicinal/anti) Hydrohydrin formation (trans/anti) Dihydroxylation (cis/syn) (Reverse) Epoxide (trans- dihydroxylation/anti) Hydrogenation (syn)

HBr, H2O2

Hydrobromination Anti-markovnikov Alkene -> Add H, Br

Syn

Hydrogenation

H2, Pt

Hydrogenation Syn addition Alkene -> Add H, H

HX

Hydrohalogenation Markovnikov Alkene -> Add H, X

Not stereospecific.

Hydrohalogenation AND Acid-catalyzed alkene hydration

halohydrin formation

If another nucleophile species (solvent) is present in the halogenation rxn, that nucleophiles can attack the cyclic halonium electrophile

How does the formation of a bromonium ion (R₂Br+) account for the observed anti-stereochemistry of addition to cyclopentene?

If bromonium ion is formed as a intermediate the large bromine atom might shield one side of the molecule; reaction with Br- ion in the 2nd step could then occur from the opposite unshielded side to give the trans product

Molozonide

In an ozonolysis reaction, an intermediate with molecular structure featuring a five-membered ring containing three adjacent oxygen atoms.

OH

In halohydrin formation, ___ is markonikov

Nitrenes must be generated...

In situ, since they are transient species.

Steric effects may...

Inhibit radical from reacting (stability: Isopropyl radical>>Methyl radical)

major

Is the product of this reaction the major or minor product?

minor

Is the product of this reaction the major or minor product?

CrO3, H2SO

Jones reagent turns primary alcohols into carboxylic acids, secondary into ketone

Reaction: Acid Catalyzed Hydration

Markovnikov

Reaction: Addition of Hydrogen Halides

Markovnikov

Reaction: Alkoxymercuration-Demercuration

Markovnikov

Reaction: Oxymercuration-Demercuration

Markovnikov

Acid Catalyzed Hydration (H2O, H3O+ or H2SO4)

Markovnikov carbocation intermediate rearrangements possible

Hydrogen Halide Addition (HBr)

Markovnikov carbocation intermediate rearrangements possible

Reaction: Halohydrin Formation

Markovnikov Anti

alkene + H2O/H2SO4

Markovnikov addition Mixed addition adds OH to most substituted C adds hydrogen to least substituted C

HX

Markovnikov addition Mixed addition adds halogen to most substituted C adds hydrogen to least substituted C

X2 H20

Markovnikov addition of OH Anti addition OH placed at most substituted C, X placed at least substituted C

Mark

Mercuration reduction

Oxymercuration

Mercury (Hg(OAC)2) added along with an H2O; also uses NABH4; adding H2o so HOH; adds OH on most substituted and puts hydrogen on the less substituted; markonikoiv; anti addition

ALkmercuration

Mercury (Hg(OAC)2) added along with an H2O; also uses NABH4; adding ROH so chain with OH; anti addition

Pinacol reaction - reaction conditions

Mg (to donate e-, and allow complexing), 80°C, benzene

1-bromo-butane

Name the product

butene

Name the reactant (all the way to the left)

Halohydrin Formation

No carbocation Halogen + OH = bridge intermediate Anti Addition Product = halide alcohol Regiospecific= one product- Mark OH on more substitued carbon Arrow?

Hydrogenation

No carbocation Product= alkane Add 2 H+ Syn addition Turn all alkenes to alkanes No regiochem Requires metal catalyst Arrow?

Epoxide Formation

No carbocation Product= epoxide Add Oxygen bridge No bridge intermediate Syn Addition No regiochemistry Does not change stereochemistry from alkene Either both cis/trans Arrow?

oximercuration/reduction

No rearrangements

Ozonolysis

O3 and SMe2 breaks double bonds

Vicinal

On adjacent carbons

(Reverse) Epoxide

Open an epoxide to get trans/anti-dihydroxylation 1. Add H3O+ to break cyclopropane bond 2. Add the H2O to the C that loses the bond after step 1 -Add H2O again to form OH from H2O attached -Anti-addition

dihydroxylation

OsO4 and tBuOOH adds 2 OH syn addition

Reaction with KMnO4 in acidic solution

Oxidative Cleavage of Alkenes

Reaction with ozone followed by zinc in acetic acid

Oxidative Cleavage of Alkenes Intermediates: [Molozonide] and Ozonide

Oxidative cleavage (KMnO4 w/ H3O+ or hot)

Oxidizes and cleaves

Mark

Oxymercuration

1) Hg(OAc)2, H2O 2) NaBH4

Oxymercuration-demercuration Markovnikov No carbocation rearrangements Alkene -> Add H, OH

anti-addition

Oxymercuration-reduction

Reactions that form Cyclopropane Intermediates (3)

Oxymercuration/Demercuration (mercurmium ion interm.) Halogenation (bromonium/chloroniumion interm.) Hydrohydrin Formation

1) O3 2) DMS

Ozonolysis Allene cleavage -> 2 C=O

Reaction: Polymerization

Polymer (lol)

Oxidative Cleavage

Puts an oxygen on either side of the break; can use KMNO3 & hot, can also use O3and H2O2 which forms an double bonded O from the double bond and with an OH

Autoxidation reaction (radical)

R3C-H + O2 ---> R3C-O-O-H (hydroperoxide) ---> alcohols, ketones, carboxylic acids formation of R-O-O• radical

Reduction of alkyl halides

RBr + Bu3SnH ---ABCN/∆---> RH + Bu3SnBr

nucleophile in addition of alcohol to alkene

ROH like CH3OH, adds to C+ forming a protanated ether

Hyrdohalogenation

Racemic Double bonds is nucleophile; H+ is electrophile Regioselect mark Form carbocation Arrow? Take H+ from less substituted carbon

Acid Catalyzed Hydration

Racemic Forms carbocation Regioselect mark Takes from acid - donates protons Addition of OH and the end Principle of Microsocpic Reversibility applies Arrow?

-2 chiral centers in products -Z and symmetric -no H's on Double Bond Br₂,H₂O

Racemic mix of R,R and S,S

Antimark

Radical hydrohaogenation

Why must the solvent be deoxygenated before use?

Radicals very reactive - no unwanted byproducts

LiAlH4

Reduces carboxylic acids and esters to alcohols

Halohydrin (X2 in water) (Mech type)

Regio: Markovnikov Stereo: Anti

HX addition to alkenes (Mech type)

Regio: Markovnikov Stereo: N/A

Oxymercuration-demercuration (Mech type)

Regio: Markovnikov Stereo: N/A

X2 in organic solvent (Mech type)

Regio: N/A Stereo: Anti

Ozonolysis (Mech type)

Regio: N/A Stereo: N/A Oxidative cleavage

Acid-catalyzed epoxide opening (Mech type)

Regio: N/A Stereo: anti

Catalytic hydrogenation (Mech type)

Regio: N/A Stereo: syn

Epoxidation (by peroxyacid) (Mech type)

Regio: N/A Stereo: syn

Osmylation (Mech type)

Regio: N/A Stereo: syn

Hydroboration (Mech type)

Regio: Non-Markovnikov Stereo: syn

H2/Pd

Removes double bond or triple bond

HX; ether Regio: Markovnikov Addn

Steps/reagents involved

Syn

Stereoselectivity w/ BH3

Both

Stereoselectivity w/ H-X

Anti

Stereoselectivity w/ HO-X

Anti

Stereoselectivity w/ Hg(OAc)2

Anti

Stereoselectivity w/ RS-Cl

Anti

Stereoselectivity w/ X2

NANH2

Strong base that is used for deportation of alkenes and elimination reactions (turns things into alkynes)

What affects reactivity of carbenes?

Substituents - EWGs makes carbenes more electrophilic EDG reduce electrophilicity and reactivity

Reaction: Alpha Elimination for Cyclopropanation

Syn

Reaction: Catalytic Hydrogenation

Syn

Reaction: Epoxidation

Syn

Reaction: Simmons Smith Cyclopropanation

Syn

Reaction: Syn Dihydroxylation

Syn

Hydroboration

Syn Addition No carbocation Regioselect non mark Only way to get primary OH group Adds H+ and OH across double bond Need H2O2 Arrow?

KMnO4, NaOH, cold

Syn Dihydroxylation Method 1 Alkene -> Add OH, OH

1) OsO4 2) H2O2

Syn Dihydroxylation Method 2 Alkene -> Add OH, OH

Syn Dihyroxylation

Syn addition 2 OHs = no regiochem Has the ability to make meso compounds Arrows (2 possible)?

H2 Pt (Pd/C)

Syn addition Removes the alkene with the addition of H to each double bonded C

1) OsO4 2) NaHSO3, H2O

Syn addition adds OH to each double bonded C

KMnO4 NaOH, cold

Syn addition adds OH to each double bonded C

Dihydroxylation (OsO4)

Syn addition diols (OsO4)

Dihydroxylation (KMnO4 w/ cold or base)

Syn addition diols! (KMnO4)

oxidation of alkenes by osmium tetroxide in the presence of peroxides

Syn hydroxylation of cis--butene gives meso-, -butanediol ; because the meso compound is achiral, the product is optically inactive. Syn hydroxylation of trans--butene gives racemic , -butanediol. Because the diol is formed as a racemic mixture, the product of the oxidation of the trans-alkene is also optically inactive. Thus, the osmium tetroxide oxidation of an alkene is stereospecific

Alkene halogenation

The addition of X2 (x=halogen) to alkenes, product is a vicinal dihalide

Stereochemistry of Halogenation(cis)

The bromonium ion formed from cis-butene is a meso species. Ring opening of a meso species by backside attack generates a racemic mixture.

Stereochemistry of Halogenation(trans)

The bromonium ion formed from trans-butene is a racemate. Ring opening by backside attack of a racemate generates a meso compound.

2, 3, carbon

The carbocation is rearranged from a ___ degree carbocation to a ___ degree carbocation by a 1,2-_____shift.

anti, either

The difference between the products of an oxymercuration demercuration reaction and a acid catalyzed hydration reaction is that oxymercuration demercuration produces (syn, anti, either) products, while acid catalyzed hydration produces (syn, anti, either) products.

Alkene halogenation regioselectivity

The nucleophile attacks the more substituted carbon first

solvent for Addition of Halogens to Alkenes

The reaction is commonly carried out in an inert solvent such as CH2Cl2, CHCl3, or CCl4.

HX

There are two reagent sets that can product hydrohalogenation. Which produces a markovnikov product?

HX, ROOR

There are two reagent sets that can product hydrohalogenation. Which produces an anti-markovnikov product?

Persistent Carbon Radicals may occur when...

There is enough stabilisation

Hygrohalogen#4(with one chiral center)

This is a two-step reaction - the first step is regiospecific, generating the more stable carbocation. In the second step a new stereocenter is generated; this is additional to the one alreadyexisting. Because this (second) step is stereorandom, a pair of diastereomers is formed.

Hygrohalogen#6(stereo select)

This is a two-step reaction - the second step is stereoselective, preferentially generating the anti- (or trans-) diastereomer. Reason: one methyl group hinders the approach of the nucleophile (Br-).

free radical substitution (bromination).

This method uses a series of repeating steps, which achieve the addition of H-Br in antiMarkovnikov fashion.

acid-catalyzed hydrohalogenation

This reaction is an example of ________.

X2 H2O

Trans/anti

Halohydrin Formation

Treatment of an alkene with chlorine (bromine) and water results in formation of a chlorohydrin (bromohydrin) having the halogen and hydroxyl groups on adjacent carbons. The mechanism involves nucleophilic attack of water on a bridged halonium ion. Net anti addition of the halogen and OH groups occurs. Consequently, product derived from a cycloalkene has the halogen and OH trans to each other.

Alkene + Br2/CCl4

Two bromines on neighboring C trans

Hydroboration

Uses BH3, THF & NAOH, H2O2 (sometimes H2O) is antimark so hydrogen adds to most substituted while oh adds to least; is syn addition

Dihydroxylation (Uses KMNO4 in cold conditions, dilute)

Uses KMNO4 in cold conditions, dilute

Hydrogenation

Using metals such as pt or pd along with H2; pi bond is broke and hydrogen atoms are added to each of the carbons; it is syn addition so both would be wedges or dashes

OH, H

What are the groups added in acid catalyzed hydration?

X, X

What are the groups added in halogenation?

OR, X

What are the groups added in halohydrin formation?

OH, H

What are the groups added in hydroboration oxidation?

H, X

What are the groups added in hydrohalogenation?

OH, OH

What are the groups added in hydroxylation?

OH, H

What are the groups added in oxymercuration demercuration?

1

What degree carbocation intermediate is formed?

2

What degree of carbocation intermediate is formed?

acid catalyzed hydration

What is the 4th blank from the top?

oxymercuration demercuration

What is the 5th blank from the top?

hydroboration oxidation

What is the 6th blank from the top?

hydroxylation

What is the 7th blank from the top?

hydrohalogenation

What is the first blank from the top?

hydrogenation

What is the last blank?

halogenation

What is the second blank from the top?

halohydrin formation

What is the third blank from the top?

methyl shift

Why is the minor product (top right) not observed when the reaction is done in the lab?

Halogenation

Without H, adding 2 halogens, break pi bond and puts 1 halogen on either carbon thats double bond; anti addition so added to oppose faces of pi bond; reaction is carried out with a solvent that doesnt react

H3C-PPh3, ether

Wittig reaction reduces ketones or aldehydes to alkene

Anti-Markovnikov Alcohol

X not on most substituted C; minor product

Nucleophiles

a chemical species that donates an electron pair to an electrophile to form a chemical bond in relation to a reaction. All molecules or ions with a free pair of electrons or at least one pi bond

Addition (Anti, Electrophilic, Syn)

a reaction involving an increase in the number of groups attached to the alkene and a decrease in the number of elements of unsaturation

Carbene

a reactive intermediate with a neutral carbon atom having only two bonds and two nonbonding electrons; methylene (:CH₂) is the simplest carbene

-E and symmetric H₂,Pd

achiral product

-Z and asymmetric H₂,Pd

achiral product

-Z and symmetric H₂,Pd

achiral product

-E and asymmetric H₂,Pd

achiral product (H₂,Pd)

requires

acid catalyst H2SO4

anti addition

add substituents to opposite sides of the face

syn addition

add substituents to same sides of the face

1)Hg(OAC)₂, H₂O/THF 2)NaBD₄

add, MN

Hydrohalogenation

adding a hydrohalogen (HCl, HBr, HI) carbocation intermediate markov addition

HBr and ROOR

addition of H and Br (anti-markovnikov)

H3O+ and H2Oor H2SO4 and H2O

addition of H and OH (markovnikov) rearrangements possible

HX

addition of H and X (markovnikov) rearrangements possible

1. Hg(OAC)2 + H2O 2. NaBH4

addition of OH (markovnikov) and H no rearrangements

1. Hg(OAc)2 + ROH 2. NaBH4

addition of RO (markovnikov) and H no rearrangements

Halogenation

addition of br2/cl2

H-Br/ROOR

adds 1 halogen,Antimarkonikov

X2/CCl4

adds 2 of the halogen, antiaddition

BH3, THF/NaOH,H20

adds OH, antimarkonikov

H2SO4/H20

adds OH, markonikov, h shift, Carbocation intermediate

HNO3/H2SO4

adds a para NO2 group

mcpba

adds epoxide ring

HX/CCl4

adds halogen, Markonikov, hydrogen shift, carbocation intermediate

Electrophilic Addition

an addition in which the electrophile (electron-pair acceptor) bonds to one of the double-bonded carbons first, followed by the nucleophile

Anti-Addition

an addition in which two groups add to opposite faces of the double bond (as in addition of Br₂)

Syn Addition

an addition in which two groups add to the same face of the double bond (as in osmium tetroxide dihydroxylation)

Important observations about achiral reactant

an optically active product (i.e., an enantiomerically pure compound or even an enantiomerically enriched compound) can never be produced from achiral starting materials and achiral reagents reacting under achiral conditions.

monomer and a trace of a base

anionic polymerization

X2 + H2O

anti addition of OH (markovnikov) and X and enantiomer

RCO3H + H+ +H2O

anti addition of OH and OH epoxide intermediate and enantiomer

X2

anti addition of X and X and enantiomer

Free Radical Addition (HBr, peroxides) - not HCl or HI

anti-Markovnikov (peroxide effect) free radical formation

hydroboration/oxidation

anti-Markovnikov addition

halogenation

anti-addition stereospecific

hydrohalogenation (HX w/ peroxide)

anti-markovnikov

What kind of a solvent is benzene?

aprotic

Solvent for Pinacol reaction

benzene

Carbocation Stability

benzylic~tertiary > allylic~secondary > primary

Dihydroxylation (OSO4)

breaks the pi bond and adds an OH to each of the carbons; syn addition

PhMgBR/H30+

can create an alcohol from a ketone

Reactive intermediates

carbocation, radical, carbanion

monomer and concentrated acid or BF3 and water

cationic polymerization

1) BH3 * THF or B2H6 2) H2O2, NaOH

cis

Ozonloysis (1. O3, 2. DMS or H202,H2O)

cleaves double bonds molozonide/ ozonide intermediate concerted (add O3) 2nd step can differ (depends if you add DMS or H202, H20)

PCC

create aldehyde from primary alcohol and ketone from secondary alcohol

More than one double bond

diene, triene, polyene, butene, etc

t-buok

elimination to form less substituted alkenes

racemic mixture

enantiomers formed in equal amounts (50/50)

product of adding an alcohol to an alkene

ether

Hygrohalogen#5(with two chiral centers)

first step is regiorandom: 2 enantiomers are formed, The addition of Br- is stereorandom: each enantiomer generates two diastereomers = 2 pairs of racemates. [ As you know, a compound with 2 non-equivalent stereocenters has four stereoisomers; all four are formed. ]

-2 chiral centers in products -Carbocation intermediate

four stereoisomers will be formed as products (E & Z don't matter here)

monomer and heat and ROOR

free radical polymerization

NaNH2 in Nh3

good for deprotanating alkynes and alcohols

Anti-addition mechanisms

halogenation, halohydrin formation

Stereospecific rxns

halogenation, halohydrin formation, dihydroxylation, hydrogenation, hydroboration

Syn-addition mechanisms

hydroboration, dihydoxylation, hydrogenation

Carbonyl

ketone or aldehyde

O3 (-78C) + Me2S

ketones and aldehydes (ozonide intermediates) and dimethyl sulfoxide

KMNO4 + heat + H2O

ketones and carboxylic acids

acid catalyzed hydration (H3O+)

markovnikov H-shift Carbocation intermediate

hydrohalogenation (HX w/ CCl4)

markovnikov H-shift Enantiomers are present since the nucleophile can attack from the top or bottom

Oxymercuration - Reduction (1. Hg(OAc)2, H2O - 2. NaBH4)

markovnikov no H-shift anti-syn

alkoxymercuration - Reduction (1. Hg(OAc)2, ROH - 2. NaBH4)

markovnikov no H-shift anti-syn

Hydrohalogenation of Alkenes, addition of X & OH

markovnikov, anti

Oxymercuration-Reduction, addition of H & OH

markovnikov, anti

Hydration of Alkenes, acid catalyzed, addition of H & OH

markovnikov, no stereoselectivity

Hydrohalogenation, addition of H & X

markovnikov, no stereoselectivity

Oxymercuration/Reduction (1. Hg(OAc)2, H2O, 2. NaBH4)

mercurinium ion intermediate Markovnikov no rearrangements OH goes on more substituted carbon substitution with inversion (H replaces the HgOAc but stereochemistry changes- goes on opposite side) first step is anti-addition

-2 chiral centers in products -E and symmetric Cl₂

meso form (R,S)

-2 chiral centers in products -E and symmetric -no H's on Double Bond Cl₂

meso form (R,S)

-2 chiral centers in products -Z and symmetric peroxyacid

meso form of epoxide

-2 chiral centers in products -Z and symmetric -no H's on Double Bond peroxyacid

meso form of epoxide

-2 chiral centers in products -Z and symmetric -no H's on Double Bond H₂,Pd

meso product (R,S)

Carbocation rearrangement

methyl group moves to carbocation intermediate leading to the halide being attached to the carbon with one hydrogen also attached

Inductive stabilization

more electrons surrounding CH3 to stabilize C+

π radicals are...

more stable, less reactive and longer-lived.

Reactivity w/ double bonds

more substituted dbl bond -> more reactivity (more stable -> more stable intermediate -> more reactivity)

2-bromo-butane

name the product

Halohydrin

needs a polar protic solvent like water; places halogen on least substituted carbon while solvent minus hydrogen on the more substituted carbon (example: h20, cut off a H and only place OH on the more substituted carbon) ; anti addition

Arynes are...

neutral intermediates derived from aromatic rings by removing two substituents (highly reactive)

Nitrenes - structure and reactivity

neutral, electron deficient (6 e-) and highly reactive although they have 4 (rather than 2 in carbenes) non-bonded electrons. Also exist in the singlet and triplet state.

Halogenation of Alkenes, Addition of X & X

no regioselectivity, anti

Catalytic hydrogenation, addition of H &H

no regioselectivity, syn

Syn-dihydroxylation (KMnO4 or OsO4), addition of OH and OH

no regioselectivity, syn

hydrohalogenation

non stereoselective (no facial selectivity) racemic mixture formed when achiral reactant diasteromers formed when chiral reactant

Hydroboration-Oxidation, addition of H & OH

nonmarkovnikov, syn

catalyzed alkene addition

not stereoselective (?)

stereoselective rxn

one in which particular stereoisomer formed in excess over others

racemic mixture(cis-2-butene+Br2)

one that has equal amounts of left- and right-handed enantiomers of a chiral molecule.

oxymercuration -reduction

oxymercuration: anti-addition reduction: not stereoselective some retention, some inversion

Ozonolysis

pi bond breaks to form two double bond oxygens

Electrophile

positively charged or neutral species having vacant orbitals that are attracted to an electron rich centre. It participates in a chemical reaction by accepting an electron pair in order to bond to a nucleophile.

rearrangements

possible

-2 chiral centers in products -Two groups added SYN or ANTI

product is affected by reactant stereochemistry

Markovnikov's Rule

provides most substituted alkyl halide

-2 chiral centers in products -E and asymmetric peroxyacid

racemic mix of R,R and S,S

-2 chiral centers in products -E and asymmetric -no H's on Double Bond H₂,Pd

racemic mix of R,R and S,S

-2 chiral centers in products -E and asymmetric -no H's on Double Bond peroxyacid

racemic mix of R,R and S,S

-2 chiral centers in products -E and symmetric peroxyacid

racemic mix of R,R and S,S

-2 chiral centers in products -E and symmetric -no H's on Double Bond H₂,Pd

racemic mix of R,R and S,S

-2 chiral centers in products -E and symmetric -no H's on Double Bond peroxyacid

racemic mix of R,R and S,S

-2 chiral centers in products -Z and asymmetric Cl₂

racemic mix of R,R and S,S

-2 chiral centers in products -Z and asymmetric -no H's on Double Bond Cl₂

racemic mix of R,R and S,S

-2 chiral centers in products -Z and symmetric Br₂, H₂O

racemic mix of R,R and S,S

-2 chiral centers in products -Z and symmetric Cl₂

racemic mix of R,R and S,S

-2 chiral centers in products -Z and symmetric -no H's on Double Bond Cl₂

racemic mix of R,R and S,S

-2 chiral centers in products -Z and asymmetric Br₂,H₂O

racemic mix of R,R and S,S (two pairs of enantiomers=4 products since no regioselectivity)

-2 chiral centers in products -Z and asymmetric -no H's on Double Bond Br₂,H₂O

racemic mix of R,R and S,S (two pairs of enantiomers → 4 products since no regioselectivity)

-2 chiral centers in products -E and asymmetric Cl₂

racemic mix of R,S and S,R

-2 chiral centers in products -E and asymmetric -no H's on Double Bond Cl₂

racemic mix of R,S and S,R

-2 chiral centers in products -E and symmetric Br₂,H₂O

racemic mix of R,S and S,R

-2 chiral centers in products -E and symmetric -no H's on Double Bond Br₂,H₂O

racemic mix of R,S and S,R

-2 chiral centers in products -Z and asymmetric peroxyacid

racemic mix of R,S and S,R

-2 chiral centers in products -Z and asymmetric -no H's on Double Bond H₂,Pd

racemic mix of R,S and S,R

-2 chiral centers in products -Z and asymmetric -no H's on Double Bond peroxyacid

racemic mix of R,S and S,R

-2 chiral centers in products -E and asymmetric Br₂,H₂O

racemic mix of R,S and S,R (two pairs of enantiomers=4 products since no regioselectivity)

-2 chiral centers in products -E and asymmetric -no H's on Double Bond Br₂,H₂O

racemic mix of R,S and S,R (two pairs of enantiomers=4 products since no regioselectivity)

-0 chiral centers in reactant -1 chiral center in products

racemic mixture

Diels-Alder Reaction -1 chiral center in product

racemic mixture -if substituents in dienophile are cis, then they will be cis in products -if substituents in dienophile are trans, then they will be trans in products

NBS, light, low Br2

radical substitution

hydroboration (alkyne)

reactant: (1) BH3 (2) NaOH, H2O2 (terminal) triple bond breaks one bond to H 2 bonds to O (internal) 2 products double bond to O can bond to either end

hydroboration (alkene)

reactant: (1) BH3 (2) NaOH, H2O2 product: anti markovnikov alcohol (least subbed alcohol) less hindered alkene reacts first 1. double bond breaks, one end to H, other end to BH2. 2. BH2 replaced with OH

dihydroxylation (alkene)

reactant: (1) OsO4 (2) NaHSO3 product: syn hydroxides double bond breaks and both ends bond with OH

alkyne preparation

reactant: (1) X2 (2) NaNH2 1. double bond breaks to bond with X on each end 2. strong base breaks bonds in (1) and forms triple bond

oxymercuration (alkene)

reactant: (1) compound with mercury and water (2) NaBH4 product: most subbed alcohol double bond breaks to form with mercury ion intermediate then breaks to form with H and OH

ozonolysis (alkyne)

reactant: (1) ozone (2) Zn, HOAc 1. triple bond splits compound into pieces 2. NaOH & H2O2 oxidize H to OH (terminal alkenes become CO2)

ozonolysis (alkene)

reactant: (1) ozone (2) Zn, HOAc breaks bond into halves at point where double bond occurs forms double bond to oxygen where double bond was broken if OH and H2O2 in reactant, H repalced with OH in products

alkyne alkylation (alkyne)

reactant: (1) strong base (NaNH2, nBuLi, LDA) terminal alkyne deprotonated by base hallide bonds with electron and R group attach bonds with compound

alkene hx addition (alkene)

reactant: HX double bond breaks and one end connects to H, other end connects to X can rearrange

HX addition (alkyne)

reactant: HX product: triple bond breaks to bond with two X and 2 H

hydration: HgSO4, water, H2SO (alkyne)

reactant: HgSO4, water, H2SO triple bond breaks other 2 bonds with O

alkene hydration 1: acid and water (alkene)

reactant: acid (sulfuric or phosphoric) and water product: most subbed alcohol double bond breaks to bond w/ H, other end bonds with OH-

alkene isomerization (alkene)

reactant: acid (sulfuric or phosphorous) most stable (most substituted) carbocation forms lose H and this leads to rearrangement

hydrogenation (alkene)

reactant: diatomic H, Pd/C product: syn addition of H to both sides of double bond

hallide addition (alkene)

reactant: diatomic X product: anti addition of X forms bromium or chloronium intermediate double bond breaks to form with partial positive X (both ends), then breaks to form trans with other X

halide addition (alkyne)

reactant: diatomic X (xs) product: forms 2 bonds with X at both ends of bond

halohydrin formation (alkene)

reactant: diatomic X, water product: anti addition of OH and X intermediate X ion intermediate

what happes to acid catalyst/nuc

regenerated to neutralize the protonated ether

Regiochemistry

regioisomers

Ortho-benzyne radical types

singlet (paired) and triplet (unpaired) diradicals

NBS/NCS

source of Br and Cl

H₃O⁺ Notice that an epoxide formed from an alkene first. Stereo - Anti Addn

steps/reagents involved (Anti Hydroxylation)

HIO₄; H₂O

steps/reagents involved (Cleavage of Two Diols)

CHCl₃, KOH

steps/reagents involved (Dichlorocarbene Addition)

mCPBA, CH₂Cl₂

steps/reagents involved (Epoxation)

X₂ Stereo - Anti Addn Halonium ion intermediate

steps/reagents involved (Halogenation)

X₂; H₂O Regio - OH goes on the more substituted carbon Stereo - Anti

steps/reagents involved (Halohydrin Formation)

1. BH₃, THF 2. H₂O₂, NaOH

steps/reagents involved (Hydroboration)

H₂, Pd/C or PtO₂ Regio - N/A Stereo - Syn Addition

steps/reagents involved (Hydrogenation)

1. O₃ 2. Zn/H₃O⁺

steps/reagents involved (Oxidative Cleavage)

KMnO₄, H₃O⁺

steps/reagents involved (Oxidative Cleavage)

1. Hg(OAc)₂, H₂O/THF 2. NaBH₄

steps/reagents involved (Oxymercuration)

CH₂I₂; Zn(Cu), Ether

steps/reagents involved (Simmons-Smith Reaction)

1. OsO₄ 2. H₂O₂ or NaHSO₃/H₂O

steps/reagents involved (Syn Hydroxylation)

epoxidation

stereospecific syn addition retention

dihydroxylation

stereospecific syn addition achiral reactant forms enantiomers chiral reactant forms diastereomers

Ru or MO

switch groups

hydrohalogenation (H2/pt)

syn addition

CHX3 + NaOH + H2O

syn addition cyclopropination and salt Alpha elimination and enantiomer

H2 + Pt or Pd or Ni

syn addition of H and H

1. BH3 THF 2. H2O2, -OH

syn addition of H and OR (anti-markovnikov) no rearrangements and enantiomer

OsO4 + H2O2

syn addition of OH and OH

KMNO4 (cold dilute) + H2O + -OH

syn addition of OH and OH and enantiomer

epoxidation (ROOH)

syn addition! mCPBA Enantiomers are possible

CH2I2 Zn, CuCl

syn cyclopropination Simmons-Smith, carbenoid intermediate and enantiomer

RCO3H

syn epoxidation and enantiomer

1)BH₃, THF 2)H₂O₂, -OH

syn, anti-MN

Catalytic Hydrogenation (H2, Pd/C)

syn-addition

hydroboration oxidation

syn-addition stereospecific (concerted addition -added at the same time ) enantiomers formed

Hydroboration/ Oxidation (1. BH3*THF, 2. H2O2, OH-)

syn-addition substitution with retention (OH replaces the BR2, on less substituted carbon) concerted no rearrangements anti-Markovnikov

Regioselectivity

the preference of one direction of chemical bond making or breaking over all other possible directions

Demercuration

the removal of a mercury species from a molecule; demercuration of the products of oxymercuration is usually accomplished using sodium borohydride (NaBH₄)

Hyperconjugation

the stabilising interaction that results from the interaction of the electrons in a σ-bond (usually C-H or C-C) with an adjacent empty or partially filled p-orbital or a π-orbital to give an extended molecular orbital that increases the stability of the system.

Carbene

two substituents and one lone pair

-1 nonparticipating, chiral centers in reactant -1 chiral center in products

unequal amounts of diastereomers

Solvent must be...

unreactive to radicals and deoxygenated before reaction