posted on 2018-06-28, 00:00authored byHsuan-Hao Hsu, Chen-Hsuan Huang, Shiang-Tai Lin
The value of fine and specialty chemicals
is often determined by
the specific requirements in their physical and chemical properties.
Therefore, it is most desirable to design the structure of chemicals
to meet some targeted material properties. In the past, the design
of specialty chemicals has been based largely on experience and trial-and-error.
However, recent advances in computational chemistry and machine learning
can offer a new path to this problem. In this presentation, we demonstrate
a successful example where the structure of a chemical of specified
value of octanol–water partition coefficient (Kow) can be predicted by computers. This method consists
of two parts, the first being a robust method, the COSMO-SAC activity
coefficient model, that predicts the activity coefficient with input
of only the molecular structure. The second component of this method
is a derivative-free optimization algorithm that searches in the multidimensional
structure space for the desired value of Kow. In particular, the genetic algorithm (GA), based on the Darwinian
theory of evolution and natural selection, combined with simulated
annealing (SA) is adopted for this purpose. Compared to other optimization
algorithms, GA can overcome the problem of being trapped in local
minima and SA can help improve the convergence. Therefore, the GA–SA
combination has been found to be very suitable for molecular design.
We show that the value of Kow can be achieved
within 1% of the target in 30 generations with a proper set of evolution
parameters (including the size of the population, the probability
of selection, the rate of temperature annealing, etc.). The same method
can be applied to the search for chemicals with other desired properties,
such as vapor pressure and solubility.