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Vibronic Emission Spectroscopy of Benzyl-type Radicals Generated from Chloro-Substituted o-Xylenes in Corona Dischargea Young Wook Yoon and Sang Kuk Lee Department of Chemistry Pusan National University Busan 46241, Korea aSupported by the National Research Foundation(NRF) of Korea.
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Chemistry in corona discharge
What is the reaction intermediate? A + B → [A-B]☨ → C + D How to detect and identify the intermediate?
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Seven delocalized π electrons on the ring plane
What is benzyl radical? A prototype of aromatic molecular radicals Reaction intermediate in aromatic reactions Seven delocalized π electronic system Fairly strong visible emission of the D1 → D0 transition H Seven delocalized π electrons on the ring plane 2nd Excited state: (1b2)2 (2b2)1 (1a2)2 (3b2)2 22B2 1st Excited state: (1b2)2 (2b2)2 (1a2)1 (3b2)2 12A2 Ground state: (1b2)2 (2b2)2 (1a2)2 (3b2)1 12B2
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Motivation We have identified many benzyl-type radicals of
Up to the present, the hetero disubstituted benzyl radicals of CH3 and Cl have been much less studied due to the difficulty associated with weak emission intensity and dissociation of C-Cl bond. X=F, Cl, CH3, CN X, Y=F, Cl, CH3 Home-type Hetero-type
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Pinhole-type glass nozzle for generation of transient molecules
Rev. Sci. Instrum 57, 2274 (1986). Large soot deposits near hole, destabilizing the discharge system Schematics of glass nozzle for corona discharge and supersonic jet expansion Useful for OH radical, but not suitable for hydrocarbons
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Modification of glass nozzle for use of heavy aromatic compounds
Original glass nozzle Rev. Sci. Instrum. 57, 2274 (1986) Made by grinding one end of glass tube Flat bottom surface : Large soot deposit Short path length : Deflecting beam Useful for carbon-free precursors Modified glass nozzle Chem. Phys. Lett. 358, 110 (2002) Made a hole through one end of glass tube Round bottom surface : Reducing soot deposit Long path length : Straight beam Useful for hydrocarbon precursors
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Glass nozzle Nozzle holder Nozzle holder Anode Anode holder
1.27 cm < 0.3 mm Soot deposition
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Visible emission in CESE system Demonstration with He Discharge
Discharge in CESE Glass nozzle The bright visible He emission disappears with injection of precursor because of energy transfer from He* to precursor.
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Characteristics of CESE system Corona Excitation and Supersonic Jet Expansion
Carrier gas(He) + Sample Vacuum Chamber Pv Po = 3 atm Pv = 5 Torr HV = ~2.0 kV Current = ~3 mA Supersonic Expansion (+) (-) e- Corona Discharge P0 High Press. (P0) anode cathode Emission Laser-free technique for transient species Simple scheme and easy to operate Very small electric current Reduce sample temperature up to 30K Strong emission intensity CESE Spectra
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Spectrum from corona discharge of 3-chloro-o-xylene
* Precursor 2M3Cl 2M6Cl o-Xylyl Already reported
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Spectrum from corona discharge of 4-chloro-o-xylene
Precursor 2M5Cl 2M4Cl
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Assignment of the origin band of isomeric chloro-substiututed-o-xylyl radical
We estimated the electronic transition energy of the di- substituted benzyl-type radicals by using the additivity rule, summing up the contribution from each substituent which has a limitation up to di-substitution. With the confirmation of the origin band, other vibronic bands were assigned by comparing with the ab initio calculation. We identified the radical species generated by assigning the vibronic bands and the molecular structure of precursor.
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Red-shift of electronic transition energy with substitution
Substituent Position Origin banda Red-shifta,b X=None 22002 X=CH3 2- 21345 657 3- 21485 517 4- 21700 302 X=Cl 21040 962 21194 808 21645 357 aIn unit of cm-1 bRed-shift from benzyl radical of 22002cm-1 The size of red-shift depends on the position and type of the substituents on benzene ring.
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2-Methyl-3-Chlorobenzyl Radical
657 808 Additivity rule : =1465 cm-1 Prediction : =20537 cm-1 Observation : cm-1 2-Methyl-6-Chlorobenzyl Radical 657 Additivity rule : =1619 cm-1 Prediction : =20383 cm-1 Observation : cm-1 962 The 2M3Cl and 2M6Cl benzyl radicals show excellent agreements with the observation.
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Assignment of origin bands of benzyl-type radicals observed from 3-chloro-o-xylene
* Already reported
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2-Methyl-4-Chlorobenzyl Radical
Additivity rule : =1014 cm-1 Prediction : =20988 cm-1 Observation : cm-1 657 ● ● Nodes at D1 state X 357 2-Methyl-5-Chlorobenzyl Radical 657 Additivity rule : =1465 cm-1 Prediction : =20537 cm-1 Observation : cm-1 Anti-parallel orientation of two substituents ● ● 808 The 2M4Cl and 2M5Cl benzyl radicals show a large discrepancy from the observations.
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Assignment of origin bands of benzyl-type radicals observed from 4-chloro-o-xylene
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Shows excellent agreement with the ab initio calculation.
Determination of vibrational structures of 2M3Cl and 2M6Cl benzyl radicals Shows excellent agreement with the ab initio calculation.
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Shows excellent agreement with the ab initio calculation.
Determination of vibrational structures of 2M4Cl and 2M5Cl benzyl radicals Shows excellent agreement with the ab initio calculation.
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Assignments of Isomeric Radicals
Question: How to explain the distribution of the electronic transition energies of isomeric chloro-substituted methylbenzyl radicals?
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Electronic energy of substituted benzyl radicals
We assume that the rotational period of electron determines the electronic transition energy. for elliptic orbit a : major axis b : minor axis Elliptic orbit has a longer circumference than circular orbit, showing lower electronic transition energy.
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Shape of molecular orbitals at the D1 state Nodes are located at 1- and 4-positions
● (Benzyl) (2M4Cl) (2M3Cl) (2M6Cl) (2M5Cl) ● ● MO shape ● ● ● ● ● ● ● ● ● X Medium size Elliptic Large size Circular Near Elliptic Small size 21376 20270 20418 20680 22002 Obs. (cm -1) Red-shift (cm-1) 626 1322 1584 1732
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Tetrafluorobenzyl Pentafluorobenzyl
● X 21910(92) 21857(145) Although they have different numbers of substituents, they show a similar LUMO shape due to the modal position, confirming that LUMO determines the electronic transition energy.
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Orbit shape of disubstituted benzyl radicals
for elliptic Molecules Energy (cm-1) Red-shift (cm-1) Circular/Elliptic a/b Benzyl 22002 1.000 2M3Cl 20680 1322 1.124 2M6Cl 20418 1584 1.150 2M5Cl 20270 1732 1.165 It is possible to determine the shape of the elliptic orbit from the red-shift of the electronic transition energies.
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Summary We have observed the vibronic emission spectra from corona discharge of chloro-substituted o-xylenes. We have identified the benzyl-type radicals from the assignments of the origin and vibronic bands. More interestingly, we discovered the red-shift of electronic transition energy with substitution is related to the shape and size of LUMO for the first time. We confirmed the CESE system is useful for emission spectroscopy of benzyl-type radicals.
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* Scheme of CESE system D2 D1 Sn D0 S0 -1
X * He* Sn − ·H D0 D1 CESE Spectrum -1 Origin band Emission Radical Production Precursor D2 Vibronic relaxation S0 The CESE spectrum provides directly Origin band : Electronic energy of the D1 → D0 transition. Vibronic structure : Vibrational mode in the D0 state.
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Characteristics of CESE spectrum
LIF- DF spectrum J. Chem. Phys. 1990, 93, 8488 No bands exist to blue region of the origin band Origin band p-fluorobenzyl radical * He atomic line * CESE spectrum Chem. Phys. Lett. 1999, Origin band Vibrational structures in the D0 state
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Displacement reaction of Cl by H
2M6Cl 2Mbenzyl The production of o-xylyl radical can be explained in terms of bond dissociation energy.
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