Open AccessImaging covalent bond formation by H atom scattering from graphene
Author(s) -
Hongyan Jiang,
Marvin Kammler,
Feizhi Ding,
Yvonne Dorenkamp,
Frederick R. Manby,
Alec M. Wodtke,
Thomas F. Miller,
Alexander Kandratsenka,
Oliver Bünermann
Publication year - 2019
Publication title -
science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 12.556
H-Index - 1186
eISSN - 1095-9203
pISSN - 0036-8075
DOI - 10.1126/science.aaw6378
Subject(s) - intramolecular force , molecule , covalent bond , graphene , chemistry , chemical physics , atom (system on chip) , hydrogen bond , scattering , sextuple bond , hydrogen atom , chemical bond , relaxation (psychology) , atomic physics , molecular physics , crystallography , bond length , materials science , bond order , nanotechnology , physics , stereochemistry , group (periodic table) , quantum mechanics , psychology , social psychology , organic chemistry , computer science , embedded system
Viewing the atomic-scale motion and energy dissipation pathways involved in forming a covalent bond is a longstanding challenge for chemistry. We performed scattering experiments of H atoms from graphene and observed a bimodal translational energy loss distribution. Using accurate first-principles dynamics simulations, we show that the quasi-elastic channel involves scattering through the physisorption well where collision sites are near the centers of the six-membered C-rings. The second channel results from transient C-H bond formation, where H atoms lose 1 to 2 electron volts of energy within a 10-femtosecond interaction time. This remarkably rapid form of intramolecular vibrational relaxation results from the C atom's rehybridization during bond formation and is responsible for an unexpectedly high sticking probability of H on graphene.
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