eprintid: 20538
rev_number: 23
userid: 3144
dir: disk0/00/02/05/38
datestamp: 2014-09-23 13:28:17
lastmod: 2016-11-15 14:17:27
status_changed: 2014-09-23 13:28:17
type: thesis_degree
metadata_visibility: show
contact_email: ozk2@pitt.edu
item_issues_count: 0
eprint_status: archive
creators_name: Karalti, Ozan
creators_email: ozk2@pitt.edu
creators_id: OZK2
title: Correcting Density Functional Methods For Dispersion Interactions Using Pseudopotentials
ispublished: unpub
divisions: sch_as_chemistry
full_text_status: public
keywords: DFT, Dispersion, DCACP, Pseudopotential
abstract: The development of practical density functional theory (DFT) methods has provided the science community with a very important tool for modeling variety of systems such as materials, molecular and bio–molecular systems. Nonetheless, most practitioners of the method did not give enough attention to the deficiencies in modeling the dispersion interactions with the commonly used density functionals until a few years ago. Since then there have been many methods proposed to solve this problem and it is still a very active research area. I have tested a number of these dispersion–corrected DFT schemes for various systems that are of interest to our research group such as a water molecule interacting with a series of acenes and isomers of the water hexamer to see which of these methods give accurate results. Based on the tests, DFT–D3 of Grimme et al. and dispersion–corrected atom–centered pseudopotentials (DCACPs) attracted on our attention. DCACP procedure provided accurate interaction energies for the test cases, but the interaction energies fall too quickly as the distance between the molecules increases. I further investigated the effects of DCACPs on the employed density functionals with a detailed study of the interaction energies of isomers of the water hexamers and determined that with the original implementation it corrects for limitations of the BLYP functional in describing exchange-repulsion interaction as well as for dispersion interactions. We propose two different methods, namely DCACP+D and DCACP2, for improving the problems associated with the DCACP approach. These methods both provide improvements in the accuracy of the original DCACPs and also correct the quick fall-off problem of the interaction energies at long–range.
date: 2014-09-23
date_type: published
pages: 148
institution: University of Pittsburgh
refereed: TRUE
etdcommittee_type: committee_chair
etdcommittee_type: committee_member
etdcommittee_type: committee_member
etdcommittee_type: committee_member
etdcommittee_name: Jordan, Kenneth D.
etdcommittee_name: Johnson, J. Karl
etdcommittee_name: Hutchison, Geoffrey
etdcommittee_name: Garrett-Roe, Sean
etdcommittee_email: jordan@pitt.edu
etdcommittee_email: karlj@pitt.edu 
etdcommittee_email: geoffh@pitt.edu
etdcommittee_email: sgr@pitt.edu
etdcommittee_id: JORDAN
etdcommittee_id: KARLJ
etdcommittee_id: GEOFFH
etdcommittee_id: SGR
etd_defense_date: 2014-07-30
etd_approval_date: 2014-09-23
etd_submission_date: 2014-02-11
etd_release_date: 2014-09-23
etd_access_restriction: immediate
etd_patent_pending: FALSE
thesis_type: dissertation
degree: PhD
citation:   Karalti, Ozan  (2014) Correcting Density Functional Methods For Dispersion Interactions Using Pseudopotentials.  Doctoral Dissertation, University of Pittsburgh.    (Unpublished)  
document_url: http://d-scholarship-dev.library.pitt.edu/20538/1/dissertation_OK.pdf