1.1 Introduction Energy of IR photon Near IR 12, cm -1 Mid IR cm -1 Far IR cm -1 Energy of IR photons insufficient to cause electronic excitation but can cause vibrational or rotational excitation Dipole moment changes during vibrations Magnitude of dipole moment determined by a. charge b. separation (vibrational or rotation causes varying separation)

*Molecule must have change in dipole moment due to vibration or rotation to absorb IR radiation (only in this case the alternating E field can interact with the molecule and cause change in amplitude of one of its motions) Molecule with permanent dipole moments are IR active

1.1.3 Types of molecular vibrations basic categories: - stretching: change in bond length, symmetric or asymmetric - bending: change in the angle, scissoring, wagging, rocking, twisting/torsion

H 2 CO vibrations 4 = 1165 cm -1 out-of-plane wagging 2 = 1756 cm -1 CO stretch 3 = 1482 cm -1 CH 2 scissors 5 = 2846 cm -1 aym CH stretch 6 = 1221 cm -1 in-plane CH 2 rock 1 = 2790 cm -1 CH 2 sys stretch

1.1.4 Vibrational modes Translation Rotation Vibration Non-Linear 3 3 3N-6 Linear 3 2 3N-5 Only some vibrational modes are IR active

1.1.5 Classical vibrational motion A system of two masses connected by a spring? Quantum treatment E 0 = ½ h m ground vibrational state ( =0) E 1 = 3/2h m first excited vibrational state ( =1)  E = h m Vibrational selection rule:  =  1 since levels are equally spaced- should see one absorption frequency

2.1 FT-IR Time-domain spectroscopy - changes in radiant power with time Fig (p.207) Unfortunately, no detector can respond on s time scale

2.1.2 Michelson interferometer Use Michelson interferometer to measure signal proportional to time varying signal - If moving mirror moves 1/4 (1/2 round-trip) waves are out of phase at beam-splitting mirror – no signal -If moving mirror moves 1/2 (1 round- trip) waves are out of phase at beam- splitting mirror –signal Difference in path lengths called retardation  Plot  vs. signal – cosine wave with frequency proportional to light frequency but signal varies at much lower frequency Fig (p.208)

One full cycle when movable mirror moves distance /2 (round trip = ) The velocity of moving mirror v MM Bolometer, photoconducting IR detector, etc. can “see” changes on s

Time-domain signal  frequency-domain signal Fig (p.210)

2.1.3 Resolution Two closely spaced lines only separated if one complete “beat” is recorded. As lines get closer together,  must increase Mirror motion is 1/2 , resolution is governed by distance moving mirror travels Advantages of FT-IR (reading assignment, will be in exam)

2.2 IR sources Fig (p.153)

2.3 IR transducer Pyroelectric - TGS (Triglycine sulfate) based on pyroelectric effect (temperature dependent capacitance) fast enough for FT-IR (but less sensitive than thermocouple) most common detector for FT-IR Photoconducting semiconductors (e.g., PbS, MCT, etc) resistance decreases with increase photon flux (promotion of electrons to conduction band) MCT (mercury telluride-cadmium telluride) about x100 sensitive than TGS, cooled to N2(liquid) temp to reduce thermal noise. Thermal couple– based on temperature detection (heating effect of radiation) poor sensitivity slow (ms response time) – not suitable for FT-IR

*Anharmonic oscillator: a. Electron repulsion (steeper at small distance) b. Dissociation (bond breaks at large distance) Consequences: -Harmonic at low -  E becomes smaller at high -Selection rules fails  =  1,  2,  3,..

3.1 Sample handling IR (especially FT-IR) is very widely used for qualitative quantitative Analysis of gases liquids solids Most time-consuming part is sample handling

3.1.1 Gases fill gas cell (1) transparent windows (NaCl / KBr) (2) long path length (10cm-10m) – few molecules

3.1.2 Liquids fill liquid cell (1) dissolved in transparent solvent – not water (attacks the window) (2) short path length ( mm) – solvent absorbs In the following figure, horizontal lines indicate useful regions Fig (p.456)

Fig (p.457)

Determining cell pathlength Get interference pattern due to interference of waves that are reflected between the cell windows (empty cell) Determination of the distance between the salt plates Fig (p.458)

3.1.3 Solids (1) make semi-transparent pellet with KBr (2) grind and mix with mineral oil to form mull. One drop (film) between NaCl plates.

3.2 Qualitative Analysis (1) Identify functional groups (group frequency region, cm -1 ) (2) Compare with standard spectra containing these functional groups (fingerprint region, 1200 – 600 cm -1 ) - use computerized spectral search engines - use IR assignments in conjunction with other info (e.g., chemical, physical, spectroscopic)

Group frequencies Approximately calculated from masses and spring constants Variation due to coupling Compared to correlation charts/database (Table 17-6, p )

Fig (p.460)

Fig (continued, p.461)

3.3Quantitative Analysis IR more difficult than UV-Vis because (1) narrow bands (variation in  ) (2) complex spectra (3) weak incident beam (4) low transducer sensitivity (5) solvent absorption IR mostly used for rapid qualitative but not quantitative analysis

Diffuse-reflection spectrometry Advantages (powdered samples) Instrumentation (an adapter fitting into the cell component of FT-IR) Fig (p.471)

Comparison of the absorbance spectrum (a) for carbazole with its diffuse-reflectance spectrum (b) Fig (p.471)

Fig (p.477)  Orbiting Mars Global Surveyor-Thermal Emission Spectra, providing measurement of the Martian Surface and atmosphere  mini thermal-emission spectrometer measured by the Mars rover Spirit, indicating composition of nearly soils and rocks