Summary

This document provides an overview of infrared spectroscopy, a technique used in organic chemistry to identify functional groups in molecules. It describes the principles behind IR spectroscopy and explains how different types of molecular vibrations are associated with various functional groups.

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INFRARED SPERCTROSCOPY STRUCTURE DETERMINATION OF ORGANIC COMPOUNDS THROUGH IR SPECTROSCOPY Electromagnetic Radiation The source from where we get the light is Sun or Sunlight. Sunlight is a form of the electromagnetic radiation given off by the Sun. Radiation from the Sun, whi...

INFRARED SPERCTROSCOPY STRUCTURE DETERMINATION OF ORGANIC COMPOUNDS THROUGH IR SPECTROSCOPY Electromagnetic Radiation The source from where we get the light is Sun or Sunlight. Sunlight is a form of the electromagnetic radiation given off by the Sun. Radiation from the Sun, which is more popularly known as sunlight, is a mixture of electromagnetic waves ranging from Broadcast waves, Radio, Microwave, Infrared (IR), Ultraviolet rays (UV), Visible region, Gamma rays and Cosmic rays. SUN Purpose of each Electromagnetic Radiation Regions of IR Radiation Spectroscopy Spectroscopy is the study of the interaction between matter and radiated energy or radiation. Infrared Spectroscopy Infrared Spectroscopy (IR spectroscopy) is the spectroscopy that deals with the interaction of only infrared region of the electromagnetic spectrum with the matter. Types of Molecular Vibrations Stretching Vibrations: in which bond length changes that require more energy. Symmetrical stretching Asymmetrical stretching Bending Vibrations: in which bond angle changes that require less energy. Rocking Twisting Scissoring Wagging  IR Spectroscopy is a qualitative analytical technique that helps to indicate mainly the functional group of a molecule.  When the IR radiation irradiated to the molecule the part of molecule which is functional absorbs it, as a result of this absorbance the molecular vibration increases.  After the excitation of molecular vibration, these molecules comes back to their original state by releasing that energy of certain wave number which is recorded as transmittance on the spectrophotometer. Parameters  The spectrophotometer give the spectra of certain wave by indicating the quality of wave (i.e. its wavenumber) and the quantity of wave that how much wave is absorbed by the molecule (Transmittance). Transmittance is the fraction of incident light electromagnetic radiation at a specified wavelength that passes through a sample.(Lambert-Beer Law) It is a ratio so it has no unit.  IR light or electromagnetic radiation is actually thermal radiation. Its means that all of the heat which feel to us or coming into the earth from sun is nothing but IR radiation.  IR is low energy, low frequency and long wavelength radiation with low wave number that can only cause an increase in molecular vibrations (i.e. stretching & bending).  So by triggering molecular vibrations through irradiation with infrared light provides mostly information about the presence or absence of certain functional groups. Requirement of molecule In order to absorb the electromagnetic radiation for a molecule the frequency of the incident radiation matches the natural frequency of the vibration, the IR photon is absorbed and the amplitude of the vibration increases. The dipole moment of the molecule must change as a result of a molecular vibration. The change in the dipole moment allows interaction with the alternating electrical component of the IR radiation wave. Symmetric molecules (or bonds) do not absorb IR radiation since there is no dipole moment.  If the dipole moment of a molecule would not change i.e. as in Symmetric stretching the absorption spectra of radiation cannot be obtained. Such spectra is called as Forbidden or Inactive IR Spectra.  If the molecule vibrate asymmetrically, the change in its dipole moment takes place so absorption spectra of this molecule can be obtained. This is called Active IR spectra. The IR Spectrum  There are two type of IR Spectra from which we can obtained the information about the quality of molecule. 1. The Functional Group region: Identifies the functional group with the consequence of changing stretching vibrations. Ranges from 4000 to 1600 cm-1. 2. The Fingerprint region: Identifies the exact molecule with the consequence of changing bending vibrations. Ranges from 1600 to 625cm-1. Focus your analysis on this region. This is where most stretching Fingerprint region: complex and difficult to Interpretation of IR Spectra  Structural information about a compound is mainly derived from the presence or absence of characteristics absorption bands of various functional groups in the IR Spectrum of the compound.  A knowledge of the band of all the major functional groups will be valuable. The band position of all the major structural bonding types have been determined in a tabular form. Characteristic absorption position of some of the more important common functional groups are presented in given table.  This table is particularly useful for correlation when the spectrum of an unknown compound has been obtained.  It is always more useful to make direct comparison with the spectra of closely related compound. s=strong, m=medium, w=weak, v=variable. FUNCTIONAL GROUPS AND IR TABLES The remainder of this presentation will be focused on the IR identification of various functional groups such as alkenes, alcohols, ketones, carboxylic acids, etc. Basic knowledge of the structures and polarities of these groups is assumed. If you need a refresher please turn to your organic chemistry textbook. The inside cover of the Wade textbook has a table of functional groups, and they are discussed in detail in ch. 2, pages 68 – 74 of the 6th edition. A table relating IR frequencies to specific covalent bonds can be found on p. 851 of your laboratory textbook. Pages 852 – 866 contain a more detailed discussion of each type of bond, much like the discussion in this presentation. IR SPECTRUM OF ALKANES Alkanes have no functional groups. Their IR spectrum displays only C-C and C-H bond vibrations. Of these the most useful are the C-H bands, which appear around 3000 cm-1. Since most organic molecules have such bonds, most organic molecules will display those bands in their spectrum. Graphics source: Wade, Jr., L.G. Organic Chemistry, 5th ed. Pearson Education Inc., 2003 IR SPECTRUM OF ALKENES Besides the presence of C-H bonds, alkenes also show sharp, medium bands corresponding to the C=C bond stretching vibration at about 1600-1700 cm-1. Some alkenes might also show a band for the =C-H bond stretch, appearing around 3080 cm-1 as shown below. However, this band could be obscured by the broader bands appearing around 3000 cm -1 (see next slide) Graphics source: Wade, Jr., L.G. Organic Chemistry, 5th ed. Pearson Education Inc., 2003 IR SPECTRUM OF ALKENES This spectrum shows that the band appearing around 3080 cm-1 can be obscured by the broader bands appearing around 3000 cm-1. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF ALKYNES The most prominent band in alkynes corresponds to the carbon-carbon triple bond. It shows as a sharp, weak band at about 2100 cm-1. The reason it’s weak is because the triple bond is not very polar. In some cases, such as in highly symmetrical alkynes, it may not show at all due to the low polarity of the triple bond associated with those alkynes. Terminal alkynes, that is to say those where the triple bond is at the end of a carbon chain, have C-H bonds involving the sp carbon (the carbon that forms part of the triple bond). Therefore they may also show a sharp, weak band at about 3300 cm-1 corresponding to the C-H stretch. Internal alkynes, that is those where the triple bond is in the middle of a carbon chain, do not have C-H bonds to the sp carbon and therefore lack the aforementioned band. The following slide shows a comparison between an unsymmetrical terminal alkyne (1-octyne) and a symmetrical internal alkyne (4-octyne). IR SPECTRUM OF ALKYNES Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF A NITRILE In a manner very similar to alkynes, nitriles show a prominent band around 2250 cm-1 caused by the CN triple bond. This band has a sharp, pointed shape just like the alkyne C-C triple bond, but because the CN triple bond is more polar, this band is stronger than in alkynes. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF AN ALCOHOL The most prominent band in alcohols is due to the O-H bond, and it appears as a strong, broad band covering the range of about 3000 - 3700 cm-1. The sheer size and broad shape of the band dominate the IR spectrum and make it hard to miss. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF ALDEHYDES AND KETONES Carbonyl compounds are those that contain the C=O functional group. In aldehydes, this group is at the end of a carbon chain, whereas in ketones it’s in the middle of the chain. As a result, the carbon in the C=O bond of aldehydes is also bonded to another carbon and a hydrogen, whereas the same carbon in a ketone is bonded to two other carbons. Aldehydes and ketones show a strong, prominent, stake-shaped band around 1710 - 1720 cm-1 (right in the middle of the spectrum). This band is due to the highly polar C=O bond. Because of its position, shape, and size, it is hard to miss. Because aldehydes also contain a C-H bond to the sp2 carbon of the C=O bond, they also show a pair of medium strength bands positioned about 2700 and 2800 cm-1. These bands are missing in the spectrum of a ketone because the sp2 carbon of the ketone lacks the C-H bond. The following slide shows a spectrum of an aldehyde and a ketone. Study the similarities and the differences so that you can distinguish between the two. IR SPECTRUM OF ALDEHYDES AND KETONES Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF A CARBOXYLIC because it has both the O-H bond ACID A carboxylic acid functional group combines the features of alcohols and ketones and the C=O bond. Therefore carboxylic acids show a very strong and broad band covering a wide range between 2800 and 3500 cm-1 for the O-H stretch. At the same time they also show the stake-shaped band in the middle of the spectrum around 1710 cm-1 corresponding to the C=O stretch. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRA OF AMINES The most characteristic band in amines is due to the N-H bond stretch, and it appears as a weak to medium, somewhat broad band (but not as broad as the O-H band of alcohols). This band is positioned at the left end of the spectrum, in the range of about 3200 - 3600 cm-1. Primary amines have two N-H bonds, therefore they typically show two spikes that make this band resemble a molar tooth. Secondary amines have only one N-H bond, which makes them show only one spike, resembling a canine tooth. Finally, tertiary amines have no N-H bonds, and therefore this band is absent from the IR spectrum altogether. The spectrum below shows a secondary amine. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 IR SPECTRUM OF AMIDES The amide functional group combines the features of amines and ketones because it has both the N-H bond and the C=O bond. Therefore amides show a very strong, somewhat broad band at the left end of the spectrum, in the range between 3100 and 3500 cm-1 for the N-H stretch. At the same time they also show the stake-shaped band in the middle of the spectrum around 1710 cm-1 for the C=O stretch. As with amines, primary amides show two spikes, whereas secondary amides show only one spike. Graphics source: Wade, Jr., L.G. Organic Chemistry, 6th ed. Pearson Prentice Hall Inc., 2006 References http://www.utdallas.edu/~biewerm/12IR.pdf http://www.chem.ucla.edu/~webspectra/irtable.html http://en.wikipedia.org/wiki/Infrared_spectroscopy http://orgchem.colorado.edu/Spectroscopy/irtutor/IRtheory. pdf http://chemwiki.ucdavis.edu/Organic_Chemistry/Organic_Ch emistry_With_a_Biological_Emphasis/Chapter__4%3A_Struct ure_Determination_I/Section_4.2%3A__Infrared_spectroscop y

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