kuliah infra merah-lengkap
DESCRIPTION
ft ir,spektra,analisis struktur senyawa kimiaTRANSCRIPT
Infrared (IR) SpectroscopyInfrared (IR) Spectroscopy Lies between microwaves and visible light.Lies between microwaves and visible light. Most used units: Most used units: m and wave numberm and wave number Most useful range: 2.5Most useful range: 2.5m - 16m - 16mm IR region is lower in photon energy than visible light (below red – IR region is lower in photon energy than visible light (below red –
produces heating as with a heat lamp)produces heating as with a heat lamp) 2.5 2.5 10 1066 m to 2.5 m to 2.5 10 1055 m region used by organic chemists for m region used by organic chemists for
identifying functional groups. identifying functional groups. IR energy in a spectrum is usually measured as wavenumber (cmIR energy in a spectrum is usually measured as wavenumber (cm-1-1), ),
the inverse of wavelength and proportional to frequency:the inverse of wavelength and proportional to frequency: Wavenumber (cmWavenumber (cm-1-1) = 1/) = 1/(cm)(cm) Specific IR absorbed by organic molecule related to its structureSpecific IR absorbed by organic molecule related to its structure
IR region and vicinity
Infrared Energy ModesInfrared Energy Modes IR energy absorption corresponds to IR energy absorption corresponds to
specific modes, corresponding to specific modes, corresponding to combinations of atomic movements, combinations of atomic movements, such as bending and stretching of such as bending and stretching of bonds between groups of atoms called bonds between groups of atoms called “normal modes”“normal modes”
Energy is characteristic of the atoms in Energy is characteristic of the atoms in the group and their bondingthe group and their bonding
Corresponds to Corresponds to vibrations and and rotationsrotations
Hukum Hooke :
3700 - 2500 cm-1: X-H stretching (X = C,N,O,S) 2300 - 2000 cm-1: C X stretching (X = C or N) 1900 - 1500 cm-1: C=X stretching (X = C, N, O) 1300 - 800 cm-1: C-X stretching (X = C, N, O)
Molecular Vibrations1. Absorption of infrared radiation corresponds to energy
changes on the order of 8-40 KJ/mole (2-10 Kcal/mole2. The frequencies in this energy range correspond to the
stretching and bending frequencies of the covalent bonds with dipole moments.
3. Stretching (requires more energy than bending)a. Symmetricalb. Asymmetrical
4. Bendinga. Scissoring (in-plane bending)b. Rocking (in-plane bending)c. Wagging (out-of-plane bending)d. Twisting (out of plane bending)
Infrared Energy Modes
Stretching – A rhythmical movement along the bond axis such that the interatomic distance is increasing or decreasing.
C—H HC H
HC H
SymmetricStretch
(2853 cm-1)
AsymmetricStretch
(2926 cm-1)
For the Methylene Group (CH2):
In any group of three or more atoms – at least two of which are identical - there are two modes of stretching or bending: Symmetric and Asymmetric
Bending – A change in bond angle between bonds with a common atom orA movement of a group of atoms with respect to the remainder of the molecule
H H C
H H C
HC H
HC H
Scissoring~1450 cm-1
(In Plane)
Rocking~750 cm-1
(In Plane)
Wagging~1250 cm-1
(Out of Plane)
Twisting~1250 cm-1
(Out of Plane)
Thus, no two molecules of different structure will have exactly the same natural frequency of vibration, each will have a unique infrared absorption pattern or spectrum.
Two Uses:1. IR can be used to distinguish one compound from
another.2. Absorption of IR energy by organic compounds will
occur in a manner characteristic of the types of bonds and atoms in the functional groups present in the compound; thus, infrared spectrum gives structural information about a molecule.
The absorptions of each type of bond (N–H, C–H, OH, C–X, C=O,C–O, C–C, C=C, CC, CN, etc.) are regularly found only in certain small portions of the vibrational infrared region, greatly enhancing analysis possibilities.
Common Structural Units
O H
O H
N H
C Hsp
sp2
sp3
C H
C H
sp2
sp3
C O
C O
1200
1025-1200
2850-2950
3000-3100
3350-3500
3310-3320
2500-3600
3200-3600(alcohols)
(carboxylicacids)
Stretching Vibrations
C C
C O
Aldehydes and ketones
Carboxylic acids
Acid anhydrides
Acyl halides
Esters
Amides
1620-1680
1710-1750
1800-1850 and 1740-1790
1700-1725
1770-1815
1730-1750
1680-1700
Stretching Vibrations (Double Bonds)
Bending Vibrations (Diagnostic)Alkenes:
cis-disubstituted
trans-disubstituted
trisubstituted
665-730
960-980
790-840
Stretching Vibrations Triple Bonds)
C C
C N
Substituted derivatives of benzene
monosubstituted
ortho-disusbstitutedmeta-disubstitutedpara-substituted
730-770 and 690-710
735-770750-810 and 680-730790-840
2100-2200
2240-2280
Serapan gugus fungsional pada Infra merah
Regions of the Infrared SpectrumRegions of the Infrared Spectrum►4000-2500 cm4000-2500 cm-1-1 N-H, C-H, O-H (stretching) N-H, C-H, O-H (stretching)
3300-3600 N-H, O-H3300-3600 N-H, O-H 3000 C-H3000 C-H
►2500-2000 cm2500-2000 cm-1-1 C CC and C C and C N (stretching) N (stretching)►2000-1500 cm2000-1500 cm-1-1 double bonds (stretching) double bonds (stretching)
C=O 1680-1750C=O 1680-1750 C=C 1640-1680 C=C 1640-1680 cmcm-1-1
►Below 1500 Below 1500 cmcm-1-1 “fingerprint” region “fingerprint” region
The Infrared SpectrumA plot of absorption intensity (% Transmittance) on the y-
axis vs. frequency on the x-axis. Transmittance (T) - the ratio of the radiant power
transmitted by a sample to the radiant power incident on the sample.
Absorbance (A) - the logarithm to base 10 of the reciprocal of the Transmittance.
A = log10 (1 / T)
Frequency - The x-axis is represented by two scales:
1. Wavelength (2.5 to 25 ) (Bottom)
2. Wavenumber (4000 cm-1 to 400 cm-1) (Upper)
Methyl Isopropyl Ketone
Spectra Infrared
Regions of the Infrared Spectrum
IR Spectrum Peak Characteristics1.Primary Examination Regions of the Spectrum
High Frequency Region - 4000 to 1300 cm-1
Intermediate (Fingerprint Region) - 1300 to 900 cm-1
2.High Frequency Region (Functional Group Region) Characteristic Stretching frequencies of such groups
as: =CH, OH, NH, C=O, CO, CN, CC, C=C
3.The Fingerprint Region Absorption patterns frequently complex Bands originate from interacting vibrational modes Valuable when used in reference to other regions Absorption unique for every molecular species Effective use comes from experience
Spectra Infrared
IR Spectrum Peak Characteristics (con’t)Shape
Sharp (narrow) Broad
Intensity Weak (w) Medium (m) Strong (s)
Note: Peak intensity is dependent on amount of sample and sensitivity of instrument; therefore, the
actual intensity can vary from spectrum to spectrum
Infrared Spectroscopy (IR)
Infrared Spectra of Hydrocarbons
• C-H, C-C, C=C, C C have characteristic peaks
Hexane
Alkenes
1-Hexene
Alkynes
IR: Aromatic Compounds
• Weak C–H stretch at 3030 cm1
• Weak absorptions 1660 - 2000 cm1 range• Medium-intensity absorptions 1450 to 1600 cm1
Phenylacetylene
Cyclohexane or Cyclohexene?
The infra-red spectrum for a simple carboxylic acid
Ethanoic acid
carbon-oxygen double, C=Ocarbon-oxygen single, C-O
oxygen-hydrogen, O-Hcarbon-hydrogen, C-H
carbon-carbon single, C-C
IR: Alcohols
Infrared Absorption Spectrum of Ethanol
dilute t-butanol in choloroform t-butanol
IR: Carbonyl CompoundsIR: Carbonyl Compounds Strong, sharp C=O peak 1670 to 1780 cmStrong, sharp C=O peak 1670 to 1780 cm11
Exact absorption characteristic of type of Exact absorption characteristic of type of carbonyl compoundcarbonyl compound 1730 cm1730 cm11 in saturated aldehydes in saturated aldehydes 1705 cm1705 cm11 in aldehydes next to double bond or in aldehydes next to double bond or
aromatic ringaromatic ring
C=O in KetonesC=O in Ketones 1715 cm1715 cm11 in six-membered ring and acyclic ketones in six-membered ring and acyclic ketones 1750 cm1750 cm11 in 5-membered ring ketones in 5-membered ring ketones 1690 cm1690 cm11 in ketones next to a double bond or an aromatic ring in ketones next to a double bond or an aromatic ring
C=O in EstersC=O in Esters 1735 cm1735 cm11 in saturated esters in saturated esters 1715 cm1715 cm11 in esters next to aromatic in esters next to aromatic
ring or a double bondring or a double bond
The infra-red spectrum for an esterEthyl ethanoate
Practice problem:
Phenylacetaldehyde
The infra-red spectrum for a ketonePropanone
AminesAmines
The infra-red spectrum for a primary amine1-aminobutane
Analyzing the Spectrum – A Suggested Approach
Step 1. – Check for the presence of the Carbonyl group (C=O) at 1715 cm-1. If molecule is conjugated, the strong (C=O) absorption will be shifted to the right by ~30 cm-1, i.e. ~1685 cm-1
If the carbonyl absorption is present, check for: Carboxylic Acids - Check for OH group (broad
absorptionnear 3300-2500 cm-1)
Amides - Check for NH group (1 or 2 absorptions near 3500 cm-1)
Esters - Check for C-O group (medium absorptions near 1300-1000 cm-1)
Anhydrides - Check for 2 C=O absorptions near 1810 and 1760 cm-1
Aldehydes - Check for Aldehyde CH group (2 weak absorptions near 2850 and 2750 cm-1)
Ketones - Ketones (The above groups have been eliminated)
Isobutyric AcidIR SpectrumCarboxylic Acids
C4H8O2
BenzamideIR SpectrumAmides
C7H7NO
Methyl BenzoateIR SpectrumEsters
C8H8O2
Nonanal
C9H18O
IR SpectrumAldehydes
Methyl Isopropyl KetoneIR SpectrumKetones
C5H10O
Step 2. - If the Carbonyl Group is Absent Check for Alcohols, Amines, or Ethers.
Alcohols & Phenols - Check for OH group (Broad absorption near 3600-3300 cm-1
Confirm present of CO near1300-1000 cm-1
Amines - Check for NH stretch (Medium absorptions) near 3500 cm-1
Primary Amine - 2 Peaks
Secondary Amine - 1 Peak
Tertiary Amine - No peaks
N-H scissoring at 1560 - 1640 cm-1
Ethers - Check for C-O group near 1300- 1000 cm-1 and absence of OH
IR SpectrumAlkynes (CC)
Propargyl Alcohol
HC CCH2OHC3H4O
2-NaphtholIR SpectrumAlcohols & Phenols
C10H9O
n-butylamineIR SpectrumAmines
C4H11N
IR SpectrumEthers
Butyl Ether
C8H18O CH3(CH2)3 – O – (CH2)3CH3
Step 3. – Refine the Structure Possibilities by Looking for Double Bonds, Triple Bonds and Nitro Groups
Double Bonds - C=C is weak absorption near 1650 cm-1
Aliphatics occur on right side of 3000 cm-1.Unsaturated C=C or CC bonds
show an absorption on the left side of 3000 cm-1.
Triple Bonds - CN (medium, sharp absorption near 2250 cm-1
CC (weak, sharp absorption near 2150 cm-1
Nitro Groups - Two strong absorptions 1600-1500 cm-1
and 1390-1300 cm-1
Step 3 (Con’t)Aromatic Ring Absorptions
Aromatic unsaturated C=C bonds show an absorption on the left side of 3000 cm-1, but the aromaticity must be verified in the overtone region (1667 - 2000cm-1) and the out-of-plane (OOP) region (900 - 690 cm-1)
Medium to strong absorption in region 1650 - 1450 cm-1
Many weak combination and overtone absorptions appear between 2000 and 1667 cm-1
The relative shapes and numbers (1 - 4) of the overtone absorptions can be used to tell whether the aromatic ring is monosubstituted or di-, tri-, tetra-, penta-, or hexasubstituted.Positional (ortho-, meta-, para-) isomers can also be distinguished.Note: A strong carbonyl absorption can overlap these ovetone bands, making them unusable.
Step 3 (Con’t)Aromatic Ring Absorptions (Con’t)
The unsaturated =C-H “Out-of-Plane (OOP) bending absorptions in the region 900 – 690 can also be used to determine the type of ring substitution.
The number of absorptions and their relative positions are unique to each type of substitution.
Although these absorptions are in the “fingerprint” region they are particularly reliable for rings with alkyl group substitutions.
They are less reliable for polar substituents.
BenzonitrileIR SpectrumNitriles
C7H5N
IR SpectrumAlkynes (CC)
Propargyl Alcohol
HC CCH2OHC3H4O
Nitro BenzeneIR SpectrumNitro Compounds
C6H5NO2
Step 4. If none of the above apply then the compound is most likely a hydrocarbon.
Generally, very simple spectrum
Hydrocarbons - Check for main absorptions nearright side of 3000 cm-1
Decane
CH3(CH2)8CH3
IR SpectrumAlkane
C10H22
Sample PreparationSample Preparation1.1. IR spectra of liquids. IR spectra of liquids.
IR spectra of liquid compounds may be obtained either IR spectra of liquid compounds may be obtained either from the neat liquid or from a solution of the liquid in an from the neat liquid or from a solution of the liquid in an appropriate solvent. It is generally desirable to obtain the appropriate solvent. It is generally desirable to obtain the spectrum from the neat liquid, if possible, since spectrum from the neat liquid, if possible, since interference by solvent absorption is thereby avoided. interference by solvent absorption is thereby avoided.
2. IR spectra of solids. 2. IR spectra of solids. - The Mull Method. In this method, the solid sample is - The Mull Method. In this method, the solid sample is thoroughly ground up, using an agate mortar and pestle, thoroughly ground up, using an agate mortar and pestle, with a weakly absorbing, non-volatile liquid to form a thick with a weakly absorbing, non-volatile liquid to form a thick paste, called a mull. paste, called a mull.
- - The KBr pellet Method. In this method, the solid sample The KBr pellet Method. In this method, the solid sample is finely pulverized with pure, dry KBr, the mixture is is finely pulverized with pure, dry KBr, the mixture is pressed in a hydraulic press to form a transparent pellet, pressed in a hydraulic press to form a transparent pellet, and the spectrum of the pellet is measured.and the spectrum of the pellet is measured.