posted on 2014-06-11, 00:00authored byTao Yang, Dorian
S. N. Parker, Beni B. Dangi, Ralf I. Kaiser, Domenico Stranges, Yuan-Hsiang Su, Si-Ying Chen, Agnes
H. H. Chang, Alexander M. Mebel
As
a member of the organo sulfidoboron (RBS) family, the hitherto
elusive ethynylsulfidoboron molecule (HCCBS) has been formed via the
bimolecular reaction of the boron monosulfide radical (BS) with acetylene
(C2H2) under single collision conditions in
the gas phase, exploiting the crossed molecular beams technique. The
reaction mechanism follows indirect dynamics via a barrierless addition
of the boron monosulfide radical with its boron atom to the carbon
atom of the acetylene molecule, leading to the trans-HCCHBS intermediate. As predicted by ab initio electronic structure
calculations, the initial collision complex either isomerizes to its cis-form or undergoes a hydrogen atom migration to form
H2CCBS. The cis-HCCHBS intermediate either
isomerizes via hydrogen atom shift from the carbon to the boron atom,
leading to the HCCBHS isomer, or decomposes to ethynylsulfidoboron
(HCCBS). Both H2CCBS and HCCBHS intermediates were predicted
to fragment to ethynylsulfidoboron via atomic hydrogen losses. Statistical
(RRKM) calculations report yields to form the ethynylsulfidoboron
molecule from cis-HCCHBS, H2CCBS, and
HCCBHS to be 21%, 7%, and 72%, respectively, under current experimental
conditions. Our findings open up an unconventional path to access
the previously obscure class of organo sulfidoboron molecules, which
are difficult to access through “classical” formation.