Abstract
Libraries of extremely localized molecular orbitals (ELMOs) have been recently assembled to reconstruct approximate wavefunctions of very large biological systems, such as polypeptides and proteins. In this paper, we investigate for the first time the possibility of using ELMO transferability to also quickly obtain wavefunctions, electron densities, and electrostatic potentials of three-dimensional coordination polymers such as metal organic frameworks (MOFs). To accomplish this task, we propose a protocol that, in addition to exploiting the usual exportability of extremely localized molecular orbitals, also takes advantage of the novel QM/ELMO (quantum mechanics/extremely localized molecular orbital) approach to properly describe the secondary building units of MOFs. As a benchmark test, our technique has been applied to the well-known metal organic framework HKUST-1 ({Cu3(BTC)2}n, with BTC=1,3,5-benzenetricarboxylate) to quickly calculate electrostatic potential maps in the small and large cavities inside the network. On the basis of the obtained results, we envisage further improvements and applications of this strategy, which can be also seen as a starting point to perform less computationally expensive quantum mechanical calculations on metal organic frameworks with the goal of investigating transformation phenomena such as chemisorption.
Highlights
The investigation of large systems by means of reliable and computationally affordable techniques has been one of the main topics in theoretical chemistry for a long time
Since the primary goal of the present study is to evaluate the reliability of the extremely localized molecular orbitals (ELMOs) and QM/ELMO approximations in providing electron densities and electrostatic potentials, we compared the non-covalent interaction (NCI) plots
We have investigated for the first time the possibility of exploiting the transferability of extremely localized molecular orbitals to quickly and reliably reconstruct wavefunctions, electron densities, and electrostatic potentials of large portions of metal organic frameworks
Summary
The investigation of large systems by means of reliable and computationally affordable techniques has been one of the main topics in theoretical chemistry for a long time. Several strategies have been introduced over the years, most of them consisting of subdividing the (macro)molecule/(macro)system under exam into different subunits that are treated separately, sometimes even at different levels of theory [1,2] In this area of research, prominent examples are the so-called embedding methods, according to which the chemically crucial region of the system is treated at a higher quantum chemical level, while the remaining part is described through a more approximate strategy. Approach jointly devised by the Manby and Miller research groups [15,16,17,18,19,20,21,22,23,24]
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