Aspects of an introduction to photochemistry Ground state reactants Excited state reactants Reaction Intermediates Ground state products Orbital occupancy Carbonyl photochemistry Vibrational structure Frank Condon Anthracene ST gaps Intersystem crossing Some kinetics Delayed fluorescence Excimers and exciplexes Energy gap law Fluorescence yields Correlation diagrams Energy transfer Sensitization and quenching 3.1
Kinetic terms Decay of reaction intermediates with lifetimes of 25 ns (A) and 100 ns (B). 100 80 [Conc] τ = [Conc] 0 2.718 concentration 60 40 20 0 0 A τ 20 40 60 80 100 120 Time, ns B τ τ = k -1 ; t 1 2 = ln 2 k = 0.69 k 3.2
Two mechanisms for delayed fluorescence (A) Thermal population of the singlet state O Endothermic but accessible at room T S 1 ISC T 1 S 0 3.3
Two mechanisms for delayed fluorescence Triplet-triplet annihilation in naphthalene Triplet + Triplet Excited Singlet + Ground State 61 61 91 0 Energies in kcal/mol refer to the case of naphthalene Triplet-triplet encounters Spin considerations: 1/9 singlets 3/9 triplets 5/9 quintets 3.4
Two mechanisms for delayed fluorescence E and P mechanisms Ground state reactants Excited state reactants Reaction Intermediates Ground state products Singlet States the triplet feeds back into the singlet Triplet States Fluorescence emission The triplet state behaves as a parking lot for the singlet state, which emits with a lifetime directly related to the triplet lifetime in the system. 3.5
E and P mechanisms Triplet State P type delayed fluorescence E type delayed fluorescence no thermal activation energy of TWO triplet exceeds requirements for one singlet spin allowed mobility required usual observation in solution under laser excitation or very high sensitivity thermally activated requires only one triplet mobility not essential usual observation in room temperature inert medium 3.6
Stabilization by association Excited stae molecules are stabilized by association in a manner that cannot be achieved by geornd state molecules. This simple ideas mean that association will occur more readily in the excited than in the ground state. Given the scheme that follows, why is it that not all excited molecules associate. Shouldn t they ALL associate? 3.7
Stabilization by association Ground state Excited state no stabilization electron stabilization 3.8
The pyrene excimer Fig. 5.31: Experimental example of the emission from pyrene and surface interpretation from N.J. Turro, Modern Molecular Photochemistry, 1978 3.9
Time evolution of excimer emission Excited state concentration λ λ time >> τfluo. 3.10
Excited state complexes Two identical molecules: EXCI ted dimer EXCIMER Two different molecules: EXCIted complex EXCIPLEX 3.11
Exciplexes and emission Exciplex formation normally involves charge-transfer interactions. Emission can be detected in non-polar media but usually not in polar solvents. 3.12
Energy gap law k ic = 10 13 e - α E (sec -1 ) Singlet States ISC Triplet States Frank Condon factor: Proportional to the overlap of the wavefunctions for the initial and final states f v exp(-α E) Ground Singlet State 3.13
Quantum yields Φ = Rate at which a process occurs of rate of formation of a product, or of disappearence of a reactant Intensity of light, i.e. rate of light absorption 3.14
Fluorescence quantum yields Φ F 0.2 π,π*, rigid 0.7 π,π*, rigid 0.05 π,π*, flexible CH 3 CH 3 O O 0.001 < 0.0001 n,π*, flexible, small ST gap n,π*, flexible,very small ST gap 3.15
Hydrogen abstraction by a carbonyl triplet CH 3 CH 3 O* + H X CH 3 OH + X CH 3 3.16
Some hydrogen abstraction rate constants (in units of 10 6 M -1 s -1 ) Benzophenone triplet (CH 3 ) 3 CO Cyclohexane Methanol Benzhydrol Triethylsilane 0.45 0.21 7.5 9.6 1.6 0.29 7.2 5.7 CH 3 CH 3 O* + H X CH 3 OH + X CH 3 3.17
Energy transfer M* + Q M + Q* 3.18
Trivial mechanism for energy transfer D* D + hν hν + A A* High quantum yield for emission from D* High concentration of A High extinction coefficient for A Overlap of emission from D* and absorption from A 3.19
Coulombic energy transfer e 2 R donor acceptor 3.20
Exchange energy transfer donor acceptor Only mechanism of importance for triplet energy transfer 3.21
Exothermic energy transfer The rate constants for energy transfer processes which are exothermic by more than 3-4 kcal/mol and are spin allowed, frequently approach the diffusion controlled limit. k diff = 8RT 2000η 2 x 105 T η Representative diffusion controlled rate constants in units of: 10 10 M -1 s -1 isopentane benzene water 4.6 1.6 1.1 3.22
Sensitization and quenching Two viewpoints for the same phenomena hn D D* D* + A D + A* D is a sensitizer for A A is a quencher for D* 3.23
Energy transfer in the ketone naphthalene system S 1 91 N hν 1 N* S 1 85 1 N* + K N + 1 K* 1 K* 3 K* T 1 78 3 K* + N K + 3 N* T 1 CH 3 60 O H 3 C CH 3 The consequence of this exchange is assisted intersystem crossing in naphthalene. Approximate energies given in kcal/mol It also provides a way of 'isolating' the singlet chemistry of carbonyl compounds 3.24