Application of Fragment Molecular Orbital (FMO) Method to Nano-Bio Field

被引：1

作者：

Nakano, Tatsuya ^{[1
,2
]}

Mochizuki, Yuji ^{[2
,3
]}

Amari, Shinji ^{[4
]}

Kobayashi, Masato ^{[5
]}

Fukuzawa, Kaori ^{[2
,6
]}

Tanaka, Shigenori ^{[2
,7
]}

机构：

[1] Natl Inst Hlth Sci, Div Med Safety Sci, Setagaya Ku, 1-18-1 Kamiyoga, Tokyo 1588501, Japan

[2] Japan Sci & Technol Agcy, CREST Project, Kawaguchi, Saitama 3320012, Japan

[3] Rikkyo Univ, Fac Sci, Dept Chem, Toshima Ku, Tokyo 1718501, Japan

[4] Univ Tokyo, Inst Ind Sci, Meguro Ku, Tokyo 1538505, Japan

[5] Univ Tokyo, Ctr Collaborat Res, AdvanceSoft, Meguro Ku, Tokyo 1538904, Japan

[6] Mizuho Informat & Res Inst Inc, Chiyoda Ku, Tokyo 1018443, Japan

[7] Kobe Univ, Grad Sch Sci & Technol, Nada Ku, Kobe, Hyogo 6578501, Japan

来源：

JOURNAL OF COMPUTER CHEMISTRY-JAPAN | 2007年 / 6卷 / 03期

关键词：

Fragment molecular orbital method; MP2; CIS(D); CAFI; VISCANA; ABINIT-MP;

D O I：

10.2477/jccj.6.173

中图分类号：

O6 [化学];

学科分类号：

0703 ;

摘要：

Kitaura et al. (Chem. Phys. Lett. 312, 319-324 (1999)) have proposed an ab initio fragment molecular orbital (FMO) method by which large molecules such as proteins can be easily treated with chemical accuracy. In the ab initio FMO method, a molecule or a molecular cluster is divided into fragments, and the MO calculations on the fragments (monomers) and the fragment pairs (dimers) are performed to obtain the total energy that is expressed as a summation of the fragment energies and inter-fragment interaction energies (IFIEs). In this paper, we provide a brief description of the ab initio FMO method and demonstrate recent applications in the nano-bio field.

引用

页码：173 / 184

页数：12

共 50 条

[31] Multilevel fragmentation: Combining fragment molecular orbital (FMO) and cluster-in-molecule (CIM) methods
Findlater, Alexander D.
Hull, Emily
Zahariev, Federico
Gordon, Mark S.
ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 2013, 246
[32] Polarization energies in the fragment molecular orbital method
Fedorov, Dmitri G.
JOURNAL OF COMPUTATIONAL CHEMISTRY, 2022, 43 (16) : 1094 - 1103
[33] Exploring chemistry with the fragment molecular orbital method
Fedorov, Dmitri G.
Nagata, Takeshi
Kitaura, Kazuo
PHYSICAL CHEMISTRY CHEMICAL PHYSICS, 2012, 14 (21) : 7562 - 7577
[34] Acceleration of fragment molecular orbital method with GPUs
Koga, Ryota
Furukawa, Yuki
Yasuda, Koji
ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 2011, 241
[35] Recent development of the fragment molecular orbital method
Kitaura, Kazuo
ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 2011, 241
[36] An automated framework to evaluate effective interaction parameters for dissipative particle dynamics simulations based on the fragment molecular orbital (FMO) method
Okuwaki, Koji
Doi, Hideo
Mochizuki, Yuji
JOURNAL OF COMPUTER CHEMISTRY-JAPAN, 2018, 17 (02) : 102 - 109
[37] Biological evaluation, molecular modeling and dynamic simulation of IDQ bulk and IDQNPs: Organo nano-bio interface in the medical field
Salunkhe, Shilpa Y.
Gurav, Rutikesh P.
Rathod, Sanket S.
Choudhari, Prafulla B.
Yadav, Tejaswini P.
Wakshe, Saubai B.
Anbhule, Prashant, V
Kolekar, Govind B.
JOURNAL OF MOLECULAR STRUCTURE, 2024, 1301
[38] Electrospun nano-bio membrane for bone tissue engineering application-a new approach
Rethinam, Senthil
Basaran, Bahri
Vijayan, Sumathi
Mert, Ali
Bayraktar, Oguz
Aruni, A. Wilson
MATERIALS CHEMISTRY AND PHYSICS, 2020, 249
[39] Dynamic molecular exchange and conformational transitions of alpha-synuclein at the nano-bio interface
Tira, Roberto
De Cecco, Elena
Rigamonti, Valentina
Santambrogio, Carlo
Barracchia, Carlo Giorgio
Munari, Francesca
Romeo, Alessandro
Legname, Giuseppe
Prosperi, Davide
Grandori, Rita
Assfalg, Michael
INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES, 2020, 154 : 206 - 216
[40] Fragment molecular orbital-based molecular dynamics (FMO-MD), a quantum simulation tool for large molecular systems
Komeiji, Yuto
Mochizuki, Yuji
Nakano, Tatsuya
Fedorov, Dmitri G.
JOURNAL OF MOLECULAR STRUCTURE-THEOCHEM, 2009, 898 (1-3): : 2 - 7

← 1 2 3 4 5 →