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Catalysis and Catalysts - Infrared Spectroscopy Infrared Spectroscopy Applications:  Catalyst characterisation –direct measurement of catalyst IR spectrum.

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Presentation on theme: "Catalysis and Catalysts - Infrared Spectroscopy Infrared Spectroscopy Applications:  Catalyst characterisation –direct measurement of catalyst IR spectrum."— Presentation transcript:

1 Catalysis and Catalysts - Infrared Spectroscopy Infrared Spectroscopy Applications:  Catalyst characterisation –direct measurement of catalyst IR spectrum –measurement of interaction with “probe” molecules: NH 3, pyridine: acidity CO, NO: nature of active sites (e.g. Pt on alumina)  Mechanistic studies –adsorbed reaction intermediates –deactivation by strongly adsorbing species  Analysis of reactants and products (in situ reaction monitoring

2 Catalysis and Catalysts - Infrared Spectroscopy IRS - General Concepts Frequency ( ) = c/ Wavenumber (  ) = 1/ Energy (E) = h = h c  Electromagnetic Spectrum UVVisibleIR 4000 - 400 cm -1

3 Catalysis and Catalysts - Infrared Spectroscopy Solid/Gas-Phase Applications

4 Catalysis and Catalysts - Infrared Spectroscopy Diffuse Reflectance Infrared Fourier Transform Spectroscopy (DRIFTS)

5 Catalysis and Catalysts - Infrared Spectroscopy Liquid-Phase Applications ATR Crystal Liquid Phase IR SourceDetector Attenuated Total Reflection (ATR)

6 Catalysis and Catalysts - Infrared Spectroscopy Re 2 O 7 /Al 2 O 3 - Preparation NH 4 ReO 4 Dry impregnation on  -Al 2 O 3 Drying Calcination (825 K, 2h) Re 2 O 7 /Al 2 O 3 Structure???

7 Catalysis and Catalysts - Infrared Spectroscopy Absorbance Wavenumber (cm -1 ) 3900 3800 3700 3600 3500 0% 3% 6% 12% 18% Re 2 O 7 loading Re 2 O 7 /  -Al 2 O 3 - IR Spectrum in OH stretching region NH 4 ReO 4 Alumina Dry impregnation Drying 383 K, 16 h Calcination 323 K, 2 h Re 2 O 7 / Alumina Basic Neutral Acidic Al OH Al O Al Al H Intensity decreases Re-loading increases

8 Catalysis and Catalysts - Infrared Spectroscopy Metathesis of Propylene on Re 2 O 7 /Al 2 O 3 2 CH 3 CH=CH 2 CH 2 =CH 2 + CH 3 CH=CHCH 3 Very active catalyst (already at room temperature) N: mol converted/(mol Re-atoms  s)

9 Catalysis and Catalysts - Infrared Spectroscopy Model for Re-sites based on IRS ReO 4 on Lewis site not active Basic -OH substituted by ReO 4 slightly active Acidic -OH substituted by ReO 4 active

10 Catalysis and Catalysts - Infrared Spectroscopy Summary IRS Re/Al  Alumina contains Lewis and Brönsted sites  OH-spectrumdifferent acid sites  Impregnation –OH + HOReO 3 -OReO 3 + H 2 O –Al 3+ + HOReO 3 coordination complex  Low-loading Re/Al not effective  IRS gives detailed picture of surface

11 Catalysis and Catalysts - Infrared Spectroscopy Determination of Nature and Number of Active Sites for F/Al 2 O 3 F/Al 2 O 3 very active in acid-catalysed reactions Al 2 O 3 F/Al 2 O 3 HF F-salt Structure of F/Al 2 O 3 ??? Acid sites? Bronsted, Lewis???, How many??

12 Catalysis and Catalysts - Infrared Spectroscopy IR Spectra “Probe” Molecule N Pyridine adsorbs on acid sites Spectrum changes N Lewis acid N Brönsted acid Different IR Spectra

13 Catalysis and Catalysts - Infrared Spectroscopy IR Absorption Spectra of Fluorinated Alumina Background spectrum F/Al 2 O 3 After addition of H 2 O at 330 K and evacuation at 330 K After adsorption of pyridine at 330 K Lewis siteBrönsted site H2OH2O Wavenumber (cm -1 ) 1300 1500 1700 Transmission L 1452 L 1619 B 1639 B 1490 L 1497 L 1579 B 1542 b c a

14 Catalysis and Catalysts - Infrared Spectroscopy Reference Spectra

15 Catalysis and Catalysts - Infrared Spectroscopy IR results versus Catalytic Activity If Brönsted sites are active sites, DMP is an irreversible poison Conv. Amount DMP added Number of active sites Example: Oligomerisation of Isobutylene

16 Catalysis and Catalysts - Infrared Spectroscopy Number of Brönsted sites vs. F content

17 Catalysis and Catalysts - Infrared Spectroscopy Correlation IR - DMP Poisoning

18 Catalysis and Catalysts - Infrared Spectroscopy Summary IR F/Al 2 O 3  Al 2 O 3 –Lewis sites: weak adsorption of Py and DMP  F/Al 2 O 3 –Lewis sites: weakly adsorbed DMP –Brönsted sites: strongly adsorbed DMP –DMP specific poison number of Brönsted sites –Oligomerisation of isobutylene occurs at Brönsted sites

19 Catalysis and Catalysts - Infrared Spectroscopy NO Adsorption on Fe-ZSM5 Catalyst Fe-based zeolites have high activity for:  deNO x -SCR  N 2 O-mediated selective oxidation of benzene to phenol  Catalytic N 2 O decomposition NO acts as reactant and has been used as probe molecule Preparation of Fe-ZSM5:  liquid ion exchange  solid ion exchange  special route: –incorporation of Fe into zeolite structure during synthesis –extraction of Fe (and Al and Si) to non-framework positions by steaming

20 Catalysis and Catalysts - Infrared Spectroscopy  Ex-[Fe,Al]MFI: –Si/Al: 31.3 –Si/Fe: 121.7 –Fe (wt%): 0.67  Fe species: –(FeO) n ; n < 5: “oligonuclear clusters” –FeAlO x : “nano-particles” Fe extracted from the framework MFI: class of zeolites, e.g. ZSM-5, silicalite

21 Catalysis and Catalysts - Infrared Spectroscopy

22 Assignments of Absorption Bands of NO on Fe-zeolite

23 Catalysis and Catalysts - Infrared Spectroscopy Fe-containing sites in MFI

24 Catalysis and Catalysts - Infrared Spectroscopy IR Absorption Spectra of ex-[Fe,Al]MFI 1600170018001900200021002200 Wavenumber (cm -1 ) Absorbance 2133 1886 1874 1635 0.05 Fe II AlO x -NO FeAlO x -NO 2 NO + Iso Fe II -NO (  ) (Fe II O) n -NO (  )

25 Catalysis and Catalysts - Infrared Spectroscopy Au/TiO 2 Catalysed Oxidation of Propylene to Propylene Oxide

26 Catalysis and Catalysts - Infrared Spectroscopy Desorption of PO as a Function of Time

27 Catalysis and Catalysts - Infrared Spectroscopy IR Spectra of Au/TiO 2 and Au/TiO 2 /SiO 2

28 Catalysis and Catalysts - Infrared Spectroscopy Chemical Interaction of PO with Au Catalysts

29 Catalysis and Catalysts - Infrared Spectroscopy ATR Spectroscopy Nafion Catalysed Esterification

30 Catalysis and Catalysts - Infrared Spectroscopy Equipment - Glass Reactor with Dicomp Probe

31 Catalysis and Catalysts - Infrared Spectroscopy “Waterfall Graph” of Esterification 1800 - 1000 cm -1 n-Decane Ester Hexanoic acid 1-Octanol (shoulder) Abs 0.20 0.16 0.12 0.08 0.04 0.00 1800 1600 1400 1200 1000 Wavenumber (cm -1 ) 5.0 4.0 3.0 2.0 1.0 Time (h)

32 Catalysis and Catalysts - Infrared Spectroscopy Transient Spectra of Hexanoic acid and Ester 1800 - 1700 cm -1 Ester Hexanoic acid Abs 0.08 0.06 0.04 0.02 0.00 5.0 4.0 3.0 2.0 1.0 Time (h) 1780 1760 1740 1720 1700 Wavenumber (cm -1 )

33 Catalysis and Catalysts - Infrared Spectroscopy Concentration Profiles Ester Hexanoic acid

34 Catalysis and Catalysts - Infrared Spectroscopy Esterification in n -decane

35 Catalysis and Catalysts - Infrared Spectroscopy Transient Spectra 1300 - 1000 cm -1 Ester Hexanoic acid 1-Octanol (shoulder) Abs 0.03 0.02 0.01 0.00 5.0 4.0 3.0 2.0 1.0 Time (h) 1250 1200 1150 1100 1050 1000 Wavenumber (cm -1 )

36 Catalysis and Catalysts - Infrared Spectroscopy Subtracted Transient Spectra 1300 - 1000 cm -1 1-Octanol Ester 1250 1200 1150 1100 1050 1000 Wavenumber (cm -1 ) 5.0 4.0 3.0 2.0 1.0 Time (h) Abs 0.05 0.04 0.03 0.02 0.01 0.00

37 Catalysis and Catalysts - Infrared Spectroscopy 1-Octanol Concentration Profile

38 Catalysis and Catalysts - Infrared Spectroscopy Esterification in n-decane 1-Octanol (GC)1-Octanol (IR)

39 Catalysis and Catalysts - Infrared Spectroscopy Concluding Remarks  IR spectroscopy very useful in heterogeneous catalysis –ex-situ –in-situ  Simple technique  Study of catalytic sites on catalyst surface, both qualitatively and quantitatively  Information on reaction mechanism and reaction intermediates  Analysis of liquid-phase catalytic reactions

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