The electrostatic potential profile of a spherical soft particle is derived by solving the PoissonBoltzmann equations on a spherical system both numerically and analytically. The soft particle is assumed to consist of an ion-permeable charged outer layer and a non-permeable charged core with constant charged density. The contribution of the core to the potential profile is calculated for different charges and dielectric constants. Our results show that the charged core heavily influences the local potential within the soft particle. In contrast, the potential distribution outside the particle in the salt solution is found to be weakly dependent on the core features. These findings are consistent with previous experiments showing the minor impact of the core of the MS2 virus on its overall electrical properties. Our studies also indicate that while a change in temperature from 290 K to 310 K only slightly varies the potential, the ionic strength in the range of 1-600 mM has a significant effect on the potential profile. Our studies would provide good understanding for experimental research in the field of biophysics and nanomedicine.
We present a method to link the Nonadiabatic EXcited-state
Molecular
Dynamics (NEXMD) package to the SANDER package supplied by AMBERTOOLS
to provide excited-state adiabatic quantum mechanics/molecular mechanics
(QM/MM) simulations. NEXMD is a computational package particularly
developed to perform simulations of the photoexcitation and subsequent
nonadiabatic electronic and vibrational energy relaxation in large
multichromophoric conjugated molecules involving several coupled electronic
excited states. The NEXMD-SANDER exchange has been optimized in order
to achieve excited-state adiabatic dynamics simulations of large conjugated
materials in a QM/MM environment, such as an explicit solvent. Dynamics
of a substituted polyphenylene vinylene oligomer (PPV3-NO2) in vacuum and different explicit solvents has been used as a test
case by performing comparative analysis of changes in its optical
spectrum, state-dependent conformational changes, and quantum bond
orderings. The method has been tested and compared with respect to
previous implicit solvent implementations. Also, the impact on the
expansion of the QM region by including a variable number of solvent
molecules has been analyzed. Altogether, these results encourage future
implementations of NEXMD simulations using the same combination of
methods.
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