Chemistry Reference
In-Depth Information
Chapter 10
Bondonic Chemistry: Physical Origins
and Entanglement Prospects
Mihai V. Putz and Ottorino Ori
Abstract
The predicted quantum particles of the chemical bonding, the
bondons
,
are searched for their ontological bosonic existence and frontier inter-disciplinary
applications. To this end, special theoretical methodology and measuring setups are
needed in order to find the bondons through entangled experiments on cold nanosys-
tems as graphenic layers with optically-induced topological (Stone-Wales) defects,
such that the emergence of the associated bondons is caused by teleportation of
defective chemical bonds corresponding to the long-range topological propagation
of defective information on the nano-carbon sheet(s). The entangled control of the
chemical bonding by bondons, once established, is further implemented provid-
ing quantum eigen-energy by quantum phase iterative computations for aromatic
chemicals designed
in situ
on graphene by optical lattice with controlling gates ac-
counting for specific molecular Hamiltonians. Moreover, the bondons' existence is
also employed to develop the green quantum effector—biological activity determina-
tions (q-EC50) on graphenic optical lattices, highly considered (e.g. by Organisation
for Economic Co-operation and Development, along European Commission—Joint
Research Center) for global welfare, health and consumer protection due to their
toxicological prediction of chemical-biological interactions in organisms and en-
vironment; while recognizing the Stone-Wales topological-like walls' propagation
mechanism (as on graphene) in cellular homeostasis and morphogenesis, the specific
q-EC50 for chemicals acting on a biological system is resolved against recording and
fitting the entanglement purity degree curve of teleportation of SMILE (simplified
molecular-input line-entry system) molecules to the Hypermolecule form superim-
posed in a series of congeners (anti-HIV and aromatic compounds are targeted)
by counting the “emitted” bondons detected with appropriate optical lattice SWAP
protocol(s).
