Your search keyword '"Martinka, Jakub"' showing total 4 results

1. A simple approach to rotationally invariant machine learning of avector quantity

Author

Martinka, Jakub, Pederzoli, Marek, Barbatti, Mario, Dral, Pavlo O., and Pittner, Jiří

Subjects

Physics - Chemical Physics

Abstract

Unlike with the energy, which is a scalar property, machine learning (ML) predictions of vector or tensor properties poses the additional challenge of achieving proper invariance (covariance) with respect to molecular rotation. If the properties cannot be obtained by differentiation, other appropriate methods should be applied to retain the covariance. There have been several approaches suggested to properly treat this issue. For nonadiabatic couplings and polarizabilities, for example, it was possible to construct virtual quantities from which the above tensorial properties are obtained by differentiation and thus guarantee the covariance. Here we propose a simpler alternative technique, which does not require construction of auxiliary properties or application of special equivariant ML techniques. We suggest a three-step approach, using the molecular tensor of inertia. In the first step, the molecule is rotated using the eigenvectors of this tensor to its principal axes. In the second step, the ML procedure predicts the vector property relative to this orientation, based on a training set where all vector properties were in this same coordinate system. As third step, it remains to transform the ML estimate of the vector property back to the original orientation. This rotate-predict-rotate (RPR) procedure should thus guarantee proper covariance of a vector property and is trivially extensible also to tensors such as polarizability. The PRP procedure has an advantage that the accurate models can be trained very fast for thousands of molecular configurations which might be beneficial where many trainings are required (e.g., in active learning). We have implemented the RPR technique, using the MLatom and Newton-X programs for ML and MD and performed its assessment on the dipole moment along MD trajectories of 1,2-dichloroethane., Comment: typo corrected, reference added

Published

2024

2. A simple approach to rotationally invariant machine learning of a vector quantity.

Author

Martinka, Jakub, Pederzoli, Marek, Barbatti, Mario, Dral, Pavlo O., and Pittner, Jiří

Subjects

*MOLECULAR rotation, *MOLECULAR shapes, *DIPOLE moments, *MACHINE learning, *MOLECULAR dynamics

Abstract

Unlike with the energy, which is a scalar property, machine learning (ML) prediction of vector or tensor properties poses the additional challenge of achieving proper invariance (covariance) with respect to molecular rotation. For the energy gradients needed in molecular dynamics (MD), this symmetry is automatically fulfilled when taking analytic derivative of the energy, which is a scalar invariant (using properly invariant molecular descriptors). However, if the properties cannot be obtained by differentiation, other appropriate methods should be applied to retain the covariance. Several approaches have been suggested to properly treat this issue. For nonadiabatic couplings and polarizabilities, for example, it was possible to construct virtual quantities from which the above tensorial properties are obtained by differentiation and thus guarantee the covariance. Another possible solution is to build the rotational equivariance into the design of a neural network employed in the model. Here, we propose a simpler alternative technique, which does not require construction of auxiliary properties or application of special equivariant ML techniques. We suggest a three-step approach, using the molecular tensor of inertia. In the first step, the molecule is rotated using the eigenvectors of this tensor to its principal axes. In the second step, the ML procedure predicts the vector property relative to this orientation, based on a training set where all vector properties were in this same coordinate system. As the third step, it remains to transform the ML estimate of the vector property back to the original orientation. This rotate–predict–rotate (RPR) procedure should thus guarantee proper covariance of a vector property and is trivially extensible also to tensors such as polarizability. The RPR procedure has an advantage that the accurate models can be trained very fast for thousands of molecular configurations, which might be beneficial where many training sets are required (e.g., in active learning). We have implemented the RPR technique, using the MLatom and Newton-X programs for ML and MD, and performed its assessment on the dipole moment along MD trajectories of 1,2-dichloroethane. [ABSTRACT FROM AUTHOR]

Published

2024

3. Non-adiabatic molecular dynamics of photochemical processes accelerated by machine learning

Author

Martinka, Jakub, Pittner, Jiří, and Sršeň, Štěpán

Subjects

machine learning nonadiabatic molecular dynamics, strojové učení neadiabatická molekulová dynamika

Abstract

Nonadiabatic molecular dynamics is an important approach for the study of photochemical phenomena. Using a stochastic algorithm and a set of trajectories, it is possible to study phenomena where the Born-Oppenheimer approximation breaks down. This approach is limited by the size of the molecule and the length of time intervals that can be studied. Machine learning techniques, which have proven themselves in many different fields, can be a helpful tool. In this thesis, I focus on the applicability of a kernel ridge regression technique as a potential tool for accelerating nonadiabatic molecular dynamics simulations. Vinyl bromide is a small molecule with a heavy bromine atom, which from a computational point of view represents a suitable test system for nonadiabatic molecular dynamics with the inclusion of non-adiabatic and spinorbital couplings.

Published

2022

4. Study of naphthalene access pathways to cytochrome P450 1A2

Author

Martinka, Jakub, Jeřábek, Petr, and Kulhánek, Petr

Abstract

Cytochrome P450 1A2 is a human liver enzyme of a hemoprotein nature that belongs to the evolutionarily ancient group of cytochromes P450. Cytochrome P450 substrates include a wide range of drugs and most procarcinogens, making it a crucial enzyme for the study of carcinogenesis. The main reaction catalyzed by cytochrome P450 1A2 is monooxygenation, in which an oxygen atom is incorporated into a substrate molecule. This reaction takes place at an active site which, in the case of published structure of cytochrome P450 1A2, is buried in the core of the catalytic domain without an accessible tunnels. Molecular modeling techniques allow the study of dynamic phenomena in large systems and are therefore also suitable for simulations of the transport of substrate molecules to the active site. The tunnels are being made accessible due to structural fluctuations. In this work, molecular modeling techniques were used to study the pathways that the naphthalene molecule uses to enter the active site of cytochrome P450 1A2. A system consisting of cytochrome P450 1A2 anchored in a phospholipid membrane, water, ion and naphthalene molecules was simulated. The simulations yielded trajectories with a total length of 8 µs and the analysis identified seven tunnels that can be used to transport substrates....

Published

2020