Fourier Transform Microwave and Millimeter-Wave Spectroscopy of Bromoiodomethane, CH₂BrI

Abstract: Bromoiodomethane, CH2BrI, is a molecule of natural origin emitted in significant amount into the marine boundary layer. It can easily be decomposed by solar radiation, releasing Br and I atoms in the troposphere, which in turn impacts the atmospheric chemistry. Spectroscopy is an invaluable tool to monitor species present in the atmosphere. Since no high-resolution spectroscopic studies are available for this dihalomethane, we have investigated the rotational spectra of the two bromine isotopologues of CH2BrI … Show more

“…These features match their expected electrostatic kinetic energies of 1.76 eV and 2.41 eV when the two charges are separated by the equilibrium I-Br distance of CH 2 BrI, 345 pm [47][48][49], and exhibit a decrease in ion yield at positive delays that corresponds to the depletion of CH 2 BrI by the UV pulse. By contrast, if the charges were located on iodine and carbon, the I + and CH 2 Br + kinetic energies would be 2.82 eV and 3.85 eV, respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…Figure 3 presents the kinetic energy distributions of I + and CH 2 Br + after pBasex Abel inversion of the respective ion images at each delay step [46]. Normalized data from 1.85 ps, the delay step with the most statistics respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…The IR background and the negative delay regions, where the IR light arrives first, both indicate that the I + and CH 2 Br + channels centered at 1.73 ± 0.17 eV and 2.31 ± 0.21 eV are caused by the double ionization and Coulomb explosion of CH 2 BrI. These features match their expected electrostatic kinetic energies of 1.76 eV and 2.41 eV when the two charges are separated by the equilibrium I-Br distance of CH 2 BrI, 345 pm [47][48][49], and exhibit a decrease in ion yield at positive delays that corresponds to the depletion of CH 2 BrI by the UV pulse. By contrast, if the charges were located on iodine and carbon, the I + and CH 2 Br + kinetic energies would be 2.82 eV and 3.85 eV, respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…The expected three-body kinetic energy release of I + , Br + , and CH 2 + is 18.2 eV when using equilibrium internuclear distances of 345 pm, 195 pm, and 216 pm for I-Br, C-Br, and C-I, respectively [47][48][49]. Summing the highest kinetic energy channels of Br + and CH 2 + (5.4 ± 0.8 eV and 8.9 ± 0.9 eV) with the diffuse I + feature centered at 3.3 eV results in 17.6 eV.…”

Coulomb-explosion imaging of concurrent CH2BrI photodissociation dynamics

“…These features match their expected electrostatic kinetic energies of 1.76 eV and 2.41 eV when the two charges are separated by the equilibrium I-Br distance of CH 2 BrI, 345 pm [47][48][49], and exhibit a decrease in ion yield at positive delays that corresponds to the depletion of CH 2 BrI by the UV pulse. By contrast, if the charges were located on iodine and carbon, the I + and CH 2 Br + kinetic energies would be 2.82 eV and 3.85 eV, respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…Figure 3 presents the kinetic energy distributions of I + and CH 2 Br + after pBasex Abel inversion of the respective ion images at each delay step [46]. Normalized data from 1.85 ps, the delay step with the most statistics respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…The IR background and the negative delay regions, where the IR light arrives first, both indicate that the I + and CH 2 Br + channels centered at 1.73 ± 0.17 eV and 2.31 ± 0.21 eV are caused by the double ionization and Coulomb explosion of CH 2 BrI. These features match their expected electrostatic kinetic energies of 1.76 eV and 2.41 eV when the two charges are separated by the equilibrium I-Br distance of CH 2 BrI, 345 pm [47][48][49], and exhibit a decrease in ion yield at positive delays that corresponds to the depletion of CH 2 BrI by the UV pulse. By contrast, if the charges were located on iodine and carbon, the I + and CH 2 Br + kinetic energies would be 2.82 eV and 3.85 eV, respectively, supporting the view that the CH 2 Br + charge is located on bromine [47][48][49].…”

“…The expected three-body kinetic energy release of I + , Br + , and CH 2 + is 18.2 eV when using equilibrium internuclear distances of 345 pm, 195 pm, and 216 pm for I-Br, C-Br, and C-I, respectively [47][48][49]. Summing the highest kinetic energy channels of Br + and CH 2 + (5.4 ± 0.8 eV and 8.9 ± 0.9 eV) with the diffuse I + feature centered at 3.3 eV results in 17.6 eV.…”

Coulomb-explosion imaging of concurrent CH2BrI photodissociation dynamics

“…The I and I* images in Figure 7 appear to be anisotropic, indicating that the dissociation process at all wavelengths occurs on a faster timescale than the rotational period ( τ ≤ 10 ps) of CH 2 BrI, determined from microwave spectroscopy rotational constants. 17 Table 2 for I photofragments, the G1 components have an average β = 1.65, 1.56, and 1.48 at 279.71, 298.23, and 308.15 nm wavelengths, respectively. Taken together, the G1 components on average have an observed β ~ 1.56, while the G2 components generally have β ~ 0.94 using the same procedure.…”

Imaging the Dynamics of CH₂BrI Photodissociation in the Near Ultraviolet Region

Molecules Containing One Carbon Atom