Search: onr:"swepub:oai:DiVA.org:kth-316346" >
Computational Chemi...
-
Fransson, ThomasKTH,Teoretisk kemi och biologi
(author)
Computational Chemistry from Laptop to HPC : A notebook exploration of quantum chemistry
Publisher, publication year, extent ...
-
2022-08-19
-
Stockholm :KTH Royal Institute of Technology,2022
-
printrdacarrier
Numbers
-
LIBRIS-ID:oai:DiVA.org:kth-316346
-
ISBN:9789198811407
-
https://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-316346URI
-
https://doi.org/10.30746/978-91-988114-0-7DOI
Supplementary language notes
-
Language:English
-
Summary in:English
Part of subdatabase
Classification
-
Subject category:vet swepub-contenttype
-
Subject category:bok swepub-publicationtype
Notes
-
QC 20220819
-
Quantum chemistry is a powerful tool. It is now possible to model complex chemical processes even on a laptop getting insights into matter at its fundamental scale.But quantum chemistry is also very complex. Answering a chemical question requires selecting parameters among a wide variety of choices. Choosing a model system, an electronic structure method, a basis set, a set of properties, and a wide array of parameters which can affect the results in small but sometimes meaningful way… It can be a very daunting task, even for veterans of the field.Similarly, for those who wish to get a deeper understanding of a method, going through the pages of equation often riddled with inconsistent notations and formulations is very challenging. And at the end, the link between the equation and the computer implementation found in existing softwares can be vague at best.We believe that a core issue is that humans are not good at learning in abstract terms. We can get very far with a lecture or a textbook, but we will never build as much intuition about how a clock work as by simply breaking one apart and rebuilding it from scratch.This is exactly the aim of this page, allowing a hands-on approach to computational chemistry. Together we will dismantle the black box that a computational chemistry code often seems to be, go through all the cogs and gears, and build back together some of the main computational methods of modern computational chemistry. We will do this by presenting the underlying equations, all expressed with consistent notations, as well as by suggesting a simple python implementation, to really display in action how the theory is implemented into a practical tool. Additionally, we will put these methods in context by showing how they can be used to address concrete chemical questions, discussing the strengths and weaknesses of each method and how to best use them to solve practical problems.
Subject headings and genre
Added entries (persons, corporate bodies, meetings, titles ...)
-
Delcey, Mickael G.KTH,Teoretisk kemi och biologi(Swepub:kth)u1pisgaq
(author)
-
Brumboiu, Iulia E.,1987-Nicolaus Copernicus University, Torun(Swepub:kth)u14jpwa1
(author)
-
Hodecker, ManuelKTH,Teoretisk kemi och biologi(Swepub:kth)u1ja9xkd
(author)
-
Li, XinKTH,Teoretisk kemi och biologi(Swepub:kth)u1omz1ee
(author)
-
Rinkevicius, ZilvinasKTH,Teoretisk kemi och biologi(Swepub:kth)u1ad7nfi
(author)
-
Dreuw, AndreasHeidelberg University(Swepub:kth)u16brd1v
(author)
-
Rhee, Young Minorea Advanced Institute of Science and Technology (KAIST)
(author)
-
Norman, PatrickKTH,Teoretisk kemi och biologi(Swepub:kth)u1c4e2k0
(author)
-
KTHTeoretisk kemi och biologi
(creator_code:org_t)
Internet link
Find in a library
To the university's database