Chemometric modeling of core-electron binding energies

被引:8
作者
Kiralj, R. [1 ]
Takahata, Y. [1 ]
机构
[1] Univ Estadual Campinas, Inst Quim, BR-13083970 Campinas, SP, Brazil
来源
STRUCTURAL CHEMISTRY | 2006年 / 17卷 / 05期
基金
巴西圣保罗研究基金会;
关键词
chemometrics; regression models; ESCA; core-electron binding energy (CEBE); atom-type descriptors;
D O I
10.1007/s11224-006-9104-3
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
Structures of 31 small molecules were modeled at HF6- 31* level and 325 atom-type descriptors of different nature, such as electronegativity, polarizability, energy, charge, density, and steric descriptors, were calculated from molecular formula, optimized geometries, and literature data. The descriptors were employed in PLS ( partial least squares) regression modeling of 59 X1s ( 59 X1s = 1 B1s, 27 C1s, 9 N1s, 14 O1s, and 8 F1s) core-electron binding energies (CEBEs) as unique set and also as elemental sets ( C1s, N1s, O1s, and F1s). Parsimonius PLS models were obtained for all data sets (Q(2) > 0.79, R-2 > 0.84, SEV < 1.10 eV). Exploratory analyses of the PLS data sets have shown that CEBEs possess three-dimensional character which is determined by the element type of the ionized atom, electronegativity character of its chemical environment, and intramolecular stereolectronic effects.
引用
收藏
页码:525 / 538
页数:14
相关论文
共 50 条
[21]   Cluster resolution: A metric for automated, objective and optimized feature selection in chemometric modeling [J].
Sinkov, Nikolai A. ;
Harynuk, James J. .
TALANTA, 2011, 83 (04) :1079-1087
[22]   Vibrational spectroscopy and chemometric modeling: An economical and robust quality control method for lavender oil [J].
Tankeu, Sidonie Y. ;
Vermaak, Ilze ;
Kamatou, Guy P. P. ;
Viljoen, Alvaro M. .
INDUSTRIAL CROPS AND PRODUCTS, 2014, 59 :234-240
[23]   Prospective inference of bioprocess cell viability through chemometric modeling of fluorescence multiway data [J].
Chiappini, Fabricio A. ;
Azcarate, Silvana ;
Alcaraz, Mirta R. ;
Forno, Angela G. ;
Goicoechea, Hector C. .
BIOTECHNOLOGY PROGRESS, 2021, 37 (04)
[24]   Hyperspectral Imaging and Chemometric Modeling of Echinacea - A Novel Approach in the Quality Control of Herbal Medicines [J].
Sandasi, Maxleene ;
Vermaak, Iize ;
Chen, Weiyang ;
Viljoen, Alvaro M. .
MOLECULES, 2014, 19 (09) :13104-13121
[25]   Use of chemometric methodology in optimizing conditions for competitive binding partial filling affinity capillary electrophoresis [J].
Montes, Ruth E. ;
Hanrahan, Grady ;
Gomez, Frank A. .
ELECTROPHORESIS, 2008, 29 (16) :3325-3332
[26]   Reference binding energies of transition metal carbides by core-level x-ray photoelectron spectroscopy free from Ar+ etching artefacts [J].
Greczynski, G. ;
Primetzhofer, D. ;
Hultman, L. .
APPLIED SURFACE SCIENCE, 2018, 436 :102-110
[27]   Infrared spectroscopic and chemometric approach for identifying binding medium in Sukias mansion's wall paintings [J].
Haghighi, Zahra ;
Karimy, Amir-Hossein ;
Karami, Farshad ;
Garmarudi, Amir Bagheri ;
Khanmohammadi, Mohammadreza .
NATURAL PRODUCT RESEARCH, 2019, 33 (07) :1052-1060
[28]   Predictive QSAR modeling of CCR5 antagonist piperidine derivatives using chemometric tools [J].
Roy, Kunal ;
Mandal, Asim Sattwa .
JOURNAL OF ENZYME INHIBITION AND MEDICINAL CHEMISTRY, 2009, 24 (01) :205-223
[29]   Chemometric modeling of neurotransmitter amino acid separation in normal and reversed migration micellar electrokinetic chromatography [J].
Wan, H ;
Öhman, M ;
Blomberg, LG .
JOURNAL OF CHROMATOGRAPHY A, 2001, 916 (1-2) :255-263
[30]   Chemometric modeling of the electrochemical data to investigate proline cis/trans isomeration effect on aggregation of Tau protein [J].
Khodarahmi, Reza ;
Akbari, Vali ;
Mohammadi, Soheila ;
Farshadnia, Tooraj ;
Rahimabadi, Mehdi Moradi ;
Goicoechea, Hector C. ;
Jalalvand, Ali R. .
PROTEIN EXPRESSION AND PURIFICATION, 2021, 182
12345