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Beginning with the seminal paper of Born and Oppenheimer (BO) [

Due to the recent advances in ^{−1} or better [^{−1}) with experiment for rovibrational transitions [

In many cases the BO approximation is valid to a high degree, and a single PES is sufficient to describe the motion of nuclei. However, when several electronic states get close in energy, the coupling between different potential energy surfaces becomes significant. The crossings of several PESs (e.g., conical intersections) or avoided crossings require a more refined treatment of nuclear dynamics which extends nuclear motion to more than one BO surface [

The current special issue (ten papers: six reviews and four research articles) represents an excellent collection of papers focusing on the various aspects of potential energy surfaces.

The paper “Constructing potential energy surfaces for polyatomic systems: recent progress and new problems” by J. Espinosa-Garcia, M. Monge-Palacios, and J. C. Corchado provides a comprehensive description of different methods for constructing PESs based on electronic structure calculations, and their performance is evaluated by calculating properties associated with chemical reaction dynamics. The authors conclude that at the present stage the field of small systems has become mature; however the realm of larger polyatomic systems requires considerable improvement, especially when dealing with relativistic (e.g., spin-orbit) effects.

M. Ayouz and D. Babikov in their research paper “Improved potential energy surface of ozone constructed using the fitting by permutationally invariant polynomial function” illustrate the advantages of their method by studying the formation of ozone at thermal energies and its spectroscopy near the dissociation limit. The authors demonstrate that the approach of fitting the

The research paper “

The surface diffusion of adsorbed atoms and molecules plays a significant role in various surface dynamical processes, e.g., in heterogeneous chemical reactions and formation of self-assembled structures. N. Tsukahara and J. Yoshinobu in the paper “Potential energy surface of NO on Pt(997): adsorbed states and surface diffusion” elucidate the PES by investigating the adsorption states and diffusion processes of NO on Pt(997) using infrared absorption spectroscopy (IRAS) and scanning tunneling microscopy (STM).

The classical transition state theory (TST) has been very popular over the years for calculating the reaction rate constants, and it has been quite successful in the high-temperature regime. However, at low temperatures, especially involving light nuclei, the quantum effects become significant. Quantum instanton (QI) approximation has been introduced as one way to quantize the TST by naturally incorporating the quantum effects, like, for example, tunneling. For this reason, the quantum instanton approximation has received much attention for estimating the chemical reaction rate constants using full-dimensional potential energy surfaces. The QI can be applied to quite complex molecular systems via well-established imaginary time path integral techniques as described by Y. Zhao and W. Wang in their paper “Quantum instanton evaluations of the thermal rate constants for complex systems.” The authors demonstrate the utility of the QI method by applying it to such complex processes like H diffusion on Ni(100) surface, and surface-subsurface transport and interior migration for H/Ni.

The hydrogen bonding plays a significant role in living organisms, for example, between DNA or RNA bases. The cooperativity of hydrogen bonding and the substituent effects are very important in stabilizing biomolecules. In this issue, A. Ebrahimi, S. M. Habibi-Khorassani, F. B. Akher, and A. Farrokhzadeh in the research article “The N_{2} complexes: substituent effects and energy components” investigate the strength of the hydrogen bonding between X-pyridazine (N-sites) and HF molecules depending on the substituent. The authors find that in all complexes the binding energies (N

In order to understand the entire photochemical reaction process of a given system, it is necessary to explore several PESs that represent ground and excited states. Within the Franck-Condon (FC) approximation, a reaction starts from the FC point on an excited-state surface. Then, depending on the topography and the available excess energy, the system may select either adiabatic or nonadiabatic pathway. In the adiabatic case, the reacting system moves on the excited PES surpassing transition state to yield products. In the nonadiabatic case, the system undergoes a nonadiabatic transition (or several transitions cascading through a number of PESs) and then moves on the PES of the lower state. In the later case, the seams of intersection between two PESs play an important role. S. Maeda, K. Ohno, and K. Morokuma in the review paper “Exploring multiple potential energy surfaces: photochemistry of small carbonyl compounds” describe the global reaction route mapping (GRRM) method to explore the critical regions such as transition states, conical intersections, intersection seams, and minima associated with multiple PESs. The authors illustrate the efficiency of the method by documenting new nonadiabatic pathways in the photochemistry of formaldehyde and acetone.

Enzymatic reactions exploring catalytic properties of enzymes represent a very intense area of chemical research. Many species encountered in enzymatic reactions, especially metalloenzymes, may have more than one electronic state lying close in energy. It is possible that as reaction progresses, the relative energy separation between states may vary, and in particular the energetic ordering of these states may change during the reaction. Such mechanisms may include cases where the “switching” involves PESs of different spin multiplicities. The likelihood of such multistate reactivity may have important consequences in enzymatic reactions. E. A. C. Bushnell, W. Huang, and J. Gauld in the paper “Applications of potential energy surfaces in the study of enzymatic reactions” explore several states of different spin multiplicities in the catalytic activation of O_{2} by alpha-ketoglutarate-dependent dioxygenase (AlkB).

The photochemical studies where the metal atom is photoexcited into an upper state and then reacts with a given molecule (e.g., methane) are quite informative since the reaction pathway and probability strongly depend on the initial electronic state of an atom. Furthermore, the reaction pathway frequently encounters several potential energy surfaces (with various multiplicities) before the final products are formed. In this issue, O. Novaro, M. del Alba Pacheco-Blas, and J. H. Pacheco-Sánchez in the paper “Potential energy surfaces for reactions of X metal atoms (X = Cu, Zn, Cd, Ga, Al, Au, or Hg) with YH_{4} molecules (Y = C, Si, or Ge) and transition probabilities at avoided crossings in some cases” discuss the possible mechanisms for the reaction of the metal atom with the gas molecules. In the cases above, the authors show that reaction pathways encounter many surfaces, and the transition probabilities for going from one surface to another are calculated using time-dependent Landau-Zener theory. The results indicate a good agreement with the experimental data whenever they are available.

An example of the BO approximation breakdown is the Renner-Teller effect which is due to the fact that at linear geometries many of the electronic states in molecules are twofold degenerate. This results in the coupling of the electronic motion with the nuclear motion giving rise to the so-called rovibronic coupling. H. Ma, C. Zhang, Z. Zhang, X. Liu, and W. Bian in their research article “New _{2}” generate the analytical representations of the PESs using a dual-level (the lower level and the higher level which also include core and core-valence correlation effects) strategy with the inclusion of the Renner-Teller terms. The authors use these PESs for the quantum dynamical calculations and demonstrate that the calculated vibronic energy levels for the two singlet electronic states are in excellent agreement with experiment.

Finally, we would like to thank all the authors for providing the high-quality papers and also all the reviewers who donated their valuable time to this special issue.

_{2}. IV. Transition from the covalent to the van der Waals region: competition between multipolar and correlation forces

_{2}II. Core-valence correlations, relativistic contributions, and vibration-rotation spectrum