2120 ME 2 – Chemistry – Flashcards
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Unlock answersneopentane
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-branched alkane that looks like a cross |
Newman projection |
-ethane has relatively ree rotation around the carbon-carbon bond -such rotation leads to the formation of different conformers -ethane has two conformers -**the staggered conformation has C-H bonds on adjacent carbons as far apart from each other as possible -NEWMAN PROJECTION is a type of drawing that depicts the conformation of a specific conformer -the eclipsed conformation has all C-H bonds on adjacent carbons directly on top of each other Conformational Analysis -An analysis of the energy changes associated with a molecule undergoing rotation about single bonds dihedral angle = tortional angle -stability b/w different conformers is related to the repulsive van der Waals forces |
Ring Strain |
Relative Stability of Cycloalkanes
-heats of combustion per CH2 unit reveal cyclohexane (658.7KJ/mol) has no ring strain and other cycloalkanes have come ring strain -cyclopentane and cycloheptane are second most stable
-cyclopentadecane also very very low (659 KJ/mol)
angle strain is caused by bond angles different from 109.5 degrees -tortional strain is caused by exlipsing C-H bonds on adjacent carbons -cyclopropane has both a high angle and tortional strain
****molecules can bend to relieve tortional strain*** |
Conformations (of cyclohexane) |
Chair Conformation -has no ring strain -all bond angles are 109.5 and all C-H bonds are perfectly staggered
Boat Conformation -is less stable because of flagpole interactions and tortional strain
Twist Conformation -intermediate in stability b/w the boat and chair |
Substituted Cycloalkanes |
-there are axial and equatorial hydrogen atoms
-axial hydrogens are perpendicular to the average plane of the ring -equatorial hydrogens lie around the perimeter of the ring
**C-C bonds and equatorial C-H bonds are all drawn in sets of parallel lines -the axial hydrogens are drawn straiht up and down
Methyl cyclohexane is more stable with the methyl equatorial -an axial methyl has an unfavorable 1,3 diaxial interaction with axial C-H bonds 2 carbons away -A 1,3-diaxial interaction is the equivalent of 2 gauche butane interactions
GENERALLY -substituted cyclohexane is more stable with the substituent equatorial
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Disubstituted Cycloalkanes |
-these can exist as pais of cis-trans stereoisomers (diastereomers) -CIS- groups on same side of ring -TRANS- groups on opposite side of ring
-Trans-1,4-kimethylcyclohexane prefers a trans-diequatorial conformation***
-Cis-1,4-dimethylcyclohexane exists in an axial-equatorial conformation
-if one group is larger than the other, the large one will exist in the equatorial position (when 1,3) |
order of priority |
1. acid (-COOH) 2. ester 3. amide (-CONR2) 4. nitrile (-CN) 5. Aldehyde (-CHO) 6. Ketone (-CO-) 7. Alcohol (-ROH) 8. Phenol (ArOH) 9. Thiol (SH) 10. Amine (-NR2) 11. ether (ROR) 12. alkene 13. alkyne 14. alkyl, aryl, halide, etc
All Elephants Are Nice And Keen Although Pheasants Thwart All Elephants All All All |
Alcohol nomenclature |
-take the alkane name, drop the -e and add -ol
-when it is priority, the carbon bonded to "OH" is #1 on the ring |
Thiol Nomenclature |
-take alkane name and add thiol -ie. ethanethiol -ie. 2,3-pentanedithiol
SMELL -ethanethiols- the smell added to natural gas or propane -butanethiol- skunk scent .. detectable at 10ppb... causes nausea
-removal of thiol smell can be done by adding H2O2 or CL2 bleach
SULFIDES -contains RSR groups respectively -never cited as principal groups and common nomenclature is often used -take alkane name of longest chain as principal group and treat remainig SR as alkylthio group -ie. 3-methylthiononane |
Ether Nomenclature |
-contains ROR group -never cited as principal groups and commen nomenclature is often used
-take alkane ame of longest chain as principal group and treat remaining OR as alkoxy group (ie. replace -ane with -oxy)
ie. ethoxy ethane ie. 2-ethoxy-2-methylpropane |
Amines nomenclature |
-take alkane name, drop -e and add -amine
- if more than one group on amine, principal name comes from group containing the longest chain, the other is treated as a substituent |
Aldehyde and Ketone Nomenclature |
Aldehydes -many common names are used for simple aldehydes (ie. acetone, acetaldehyde)
-take alkane name, drop the -e and add -al
ie. octanal
Ketones -take alkane name, drop the -e and add -one
BOTH -when attached to a ring, suffix = carboxaldehyde - -when a carbonyl group is a substituent, its position is designated by oxo
****aldehyde takes priority over ketone |
Carboxylic Acid Nomenclature |
-common nomenclature is widely used for simple acids... e. acetic acid -take alkane name, drop the -e and add -oic acid
-butanoic acid = rancid butter
-for acids attached to rings, add carboxylic acid to the alkane name
NOTE: priority rating to determine principal group if more than one heteroatom in molecule acids>aldehyde>ketone>OH>SH |
Ester Nomenclature and Lactones |
take acid name, drop the -ic and add -ate -nae the substituent on the carboxylate oxygen first, and name it as an alkyl or aryl group
2-methyl-2-butenyl ethanoate is the flabor in juicy fruit gum.... flavor of raspberris, bananas, and pineapple also (or smell?)
-when attached to rings, keep alkane name and add carboxylate
ie. methyl 2-iodocyclopentanecarboxylate
lactones -cyclic esters... cmmon nomenclature used -ie. gamma or beta lactone.. (see slide) |
Acid Halides and Anydrides nomenclature |
-Acid Halides -take acid name, drop -oic and add -oyl plus halide -ie. pentanoyl chloride
-when attached to rings, named as alkanecarbonyl halide -ie. cyclopentanecarbonyl chloride
ANHYDRIDES (hydrogens lost) -take acid name and add anhydride -if R1=R2, just name one side -if R1does not =R2, cite two parent acids in alphabetical order -ie. butanoic propanoic anhydride |
Nitrile and Amide Nomenclature and Lactams |
NITRILES -ie. 3-methylbutanenitrile
-when attached to rings, keep alkane name and add carbonitrile -ie. 3-methylcyclohexanecarbonitrile
AMIDES -take name, drop the -oic and add -amide -ie. 3-chlorobutanamide -substitution on nitrogen (other than H) is designated with the letter N -ie. N,N-dimethylbutanamide
-when attached to rings, keep alkane name and add carboxamide ie. 2-ethylcyclobutanecarboxamide
LACTAMS -common nomenclature used (beta/gamma.. see slide) |
Nomenclature of Benzene and Derivatives |
-nomenclature for benzene derivatives follows the same rules used for other substituted hydrocarbons -some monosubstituted benzenes have well established common names (phenol, anisole, toluene)
-for disubstituted benzenes, the positions of the substituents may be designated in two ways:
a)IUPAC system: numerical designations are made in the same manner as other ompound classes; b)older, popular system o (ortho)[1,2-] m (meta) [1,3-] p(para) [1,4-]
**can't used o/m/p if more than 2 groups ; -when there is a principal group on benzene, the principal name is used; -sometimes benzene is a substituent - ; COMMON DERIVATIES OF PHENOL 3-methylphenol = meta-cresol 1,3-benzenediol = resorcinol (antiseptic) 1,4-benzenediol = hydroquinone urushiol = poison ivy.. causes itching ; O-phenylphenol = lysol ; |
Enantiomers, Chiral Molecules, and Stereogenic Centers |
chiral molecule - not superposable on its mirror image -can exist as a pair of enantiomers ; pair of enantiomers - a chiral molecule and its mirror image ; achiral molecule - superposable on its mirror image -does not have enantiomer pairs ; **a molecule /w a single tetrahedral carbon bonded to four different groups will always be chiral -a molecule /w more than one tetrahedral carbon bonded to four different groups is not always chiral -****switching two groups at the tetrahedral center leads to the enantiomeric molecule in a molecule with one tetrahedral carbon -keep any two the same and switch other two ; Stereogenic center (modern name for chiral) -an atom bearing groups of such nature that an interchange of any two groups will produce a stereoisomer -carbons at a tetrahedral stereogenic center are designated with an asterisk (*) ; ;The biological Importance of Chirality -the binding specificity of a chiral receptor site for a chiral molecule is usually only favorable in one way |
Tests for Chirality |
PLANES OF SYMMETRY -an imaginary plane that bisects a molecule in such a way that the two halves of the molecule are mirror images of each other -a molecule with a plane of symmetry cannot be chiral |
Nomenclature of enantiomers |
Use R/S system -also called the cahn-ingold-prelog system -the four groups attached to the stereogenic carbon are assigned priorities from highest to lowest -atoms directly attached to the stereogenic center are compared -atoms with higher atomic number are given higher priority ; -the molecule is rotated to put the lowest priority groups back -if the groups descend in priority in clockwise, then R -if descent in priority counterclockwise, then S ; special case: -if the lowest priority group points forward (towards you) no need to rotate, just reverse answer ; *groups with double or triple bonds are assigned priorities as if their atoms were duplicated or triplicated ; **if both carbons have same stereo name, then molecules are identical (in a neo) -if one is R and one S, then the two molecules are enantiomers |
optical activity of enatiomers |
-enantiomers have almost all identical physical properties (melting point, boiling point, density) -however, they rotate the plane of plane-polarized light in equal but opposite directions ; plane polarized light -oscillation of th electric fireld of ordinary light occurs in all possible planes perpendicular; to the; direction of propagation - if the light is passed through a polarizer only one plane emerges ; -an empty sample tube or one containing an achiral molecule will not rotate the plane-polarized light -an optically active substance (ie. one pure enantiomer) will rotate the plane polarized light -the amount the analyzer needs to be turned to permit liht through is called the observed rotation alpha -the standard value specific rotation ([alpha]) can be calculated ; ****** -i the analyzer is rotated to the right the rotation is positive and the molecule is dextrorotary (right handed-ness) -if the analyzer is rotated to teh let, the rotation is negative and the molecule is levorotatory (left handedness) ; specific rotation = observed rotation/ concentration times length of tube ; [alpha] = alpha/(c)(l) ; |
racemic mixture |
-when you have a 1:1 mixture of enantiomers -the net optical rotation will be zero -designated as (+/-) |
Molecules with more than 1 sterogenic center |
2n=#isomers ; -look at example in notes ; ; -the maximum number of stereoisomers available will not exceed 2n where n is equal to the number of stereogenic centers ; -the max number of diastereomers a chiral molecule can have is 2n-2 |
Meso Compounds and Fisher Projection |
-sometimes molecules with 2 or more stereogenic centers will have less than the maximum number of stereoisomes -this is due tothe existence of meso compounds ; meso compound: -achiral despite the presence of stereogenic centers, its is -not optically active -superposable on its mirror image -has a plane of symmetry ; NAMING -the molecule is manipulated to allow assignment of each stereogenic center separately ; ; FISCHER PROJECTION FORMULAS -can be used to give a 2D representation of chiral molecules -vertical lines represent bonds that project behind the plane of the paper -horizontal lines represent bonds that project out of the plane of the paper *old fashioned kiss |
Stereoisomerism of Cyclic compounds |
-may have planes of symmetry -if the case, then not chiral and not optically active ; |
Effects of Hybridization on Acidity, Reactions, and their mechanisms |
Effectss of Hyridization on Acidity -hydrogens connected to orbitals with more s character will be more acidic -s orbitals are smaller and closer to the nucleus that p orbitals -anions in hybrid orbitals with more s character will be held more closely to the nucleus and be more stabilized ; -willing to trade pi bond for sigma bond... triple bonds are therefore unstable ; triple bond = stronger acid and weaker base single = stronger base and weaker acid ; REACTIONS 4 types: susbstitutions additions eliminations rearrangements |
Cleavage of Covalent Bonds |
homolysis -bond breaks evenly ; heterolysis -one atom takes both electrons ; heterolytic reactions almost always occur at polar bonds -the reaction is often assisted by formation of a new bond to another molecule *bond to long pair or long pair to bond ; -reaction can occur to give a carbocation of carbanion depending on the nature of Z ; carbocations -carbocations have only 6 valence electrons and a positive charge - they readily react with any Lewis base to satisfy the otet around the electron-deficient carbon ; carbanions -carbanions have 8 valence electrons and a negative charge -they readily react with any Lewis acid to satisfy the octet around the electron rich carbon |
Organic Chemistry Terms for Lewis Acids and Bases ; |
electrophiles -(electron-loving reagents) -seek electrons to obtain a stable valence shell -are electron deficient themselves (ie carbocations) ; nucleophiles -seek a proton or some other positively charged center -are electron rich themselves (ie carbanions) ; -any organic compound containing an atom with a lone pair (O,N) can act as a base, ie a nucleophile ; -pi electrons are loosely held and available for reaction with strong acids (double to single bonds) |
A Step-Wise Mechanism for an Organic Reaction |
The Substitution Reaction of tert-Butyl Alcohol -the reaction has 3 steps -all steops are acid-base reactions ; Step 1 -is a bronsted acid-base reaction Step 2 -involves heterolytic cleavage of a bond -is a lewis acid base reactionin reverse Step 3 -is a lewis acid base reaction with chloride acting as a lewis base and the carbocation acting as lewis acid ; ; seee notes!!! |