We
introduce perturbation and coupled-cluster theories based on
a cluster mean-field reference for describing the ground state of
strongly correlated spin systems. In cluster mean-field, the ground
state wave function is written as a simple tensor product of optimized
cluster states. The cluster language and the mean-field nature of
the ansatz allow for a straightforward improvement which uses perturbation
theory and coupled-cluster to account for intercluster correlations.
We present benchmark calculations on the 1D chain and 2D square J
1–J
2 Heisenberg
model, using cluster mean-field, perturbation theory, and coupled-cluster.
We also present an extrapolation scheme that allows us to compute
thermodynamic limit energies accurately. Our results indicate that,
with sufficiently large clusters, the correlated methods (cPT2, cPT4,
and cCCSD) can provide a relatively accurate description of the Heisenberg
model in the regimes considered, which suggests that the methods presented
can be used for other strongly correlated systems. Some ways to improve
upon the methods presented in this work are discussed.
The de novo computational design of proteins with predefined three-dimensional structure is becoming much more routine due to advancements both in force fields and algorithms. However, creating designs with functions beyond folding is more challenging. In that regard, the recent design of small beta barrel proteins that activate the fluorescence of an exogenous small molecule chromophore (DFHBI) is noteworthy. These proteins, termed mini Fluorescence Activating Proteins (mFAPs), have been shown increase the brightness of the chromophore more than 100-fold upon binding to the designed ligand pocket. The design process created a large library of variants with different brightness levels but gave no rational explanation for why one variant was brighter than another. Here we use quantum mechanics and molecular dynamics simulations to investigate how molecular flexibility in the ground and excited states influences brightness. We show that the ability of the protein to resist dihedral angle rotation of the chromophore is critical for predicting brightness. Our simulations suggest that the mFAP/DFHBI complex has a rough energy landscape, requiring extensive ground-state sampling to achieve converged predictions of excited-state kinetics. While computationally demanding, this roughness suggests that mFAP protein function can be enhanced by reshaping the energy landscape towards states that better resist DFHBI bond rotation.
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