Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS2 and Alkyldiamine Molecules

Standard

Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS₂ and Alkyldiamine Molecules. / Ushakov, Ivan E.; Goloveshkin, Alexander S.; Lenenko, Natalia D. и др.

в: Crystal Growth and Design, Том 18, № 9, 05.09.2018, стр. 5116-5123.

Результаты исследований: Научные публикации в периодических изданиях › статья › Рецензирование

Harvard

Ushakov, IE, Goloveshkin, AS, Lenenko, ND, Ezernitskaya, MG, Korlyukov, AA, Zaikovskii, VI & Golub, AS 2018, 'Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS₂ and Alkyldiamine Molecules', Crystal Growth and Design, Том. 18, № 9, стр. 5116-5123. https://doi.org/10.1021/acs.cgd.8b00551

APA

Ushakov, I. E., Goloveshkin, A. S., Lenenko, N. D., Ezernitskaya, M. G., Korlyukov, A. A., Zaikovskii, V. I., & Golub, A. S. (2018). Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS₂ and Alkyldiamine Molecules. Crystal Growth and Design, 18(9), 5116-5123. https://doi.org/10.1021/acs.cgd.8b00551

Vancouver

Ushakov IE, Goloveshkin AS, Lenenko ND, Ezernitskaya MG, Korlyukov AA, Zaikovskii VI и др. Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS₂ and Alkyldiamine Molecules. Crystal Growth and Design. 2018 сент. 5;18(9):5116-5123. doi: 10.1021/acs.cgd.8b00551

Author

Ushakov, Ivan E. ; Goloveshkin, Alexander S. ; Lenenko, Natalia D. и др. / Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS₂ and Alkyldiamine Molecules. в: Crystal Growth and Design. 2018 ; Том 18, № 9. стр. 5116-5123.

BibTeX

@article{f243c163ebcc4e5ba5cbc577ce8ee1ce,

title = "Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS2 and Alkyldiamine Molecules",

abstract = "We report the synthesis, structure determination, and quantum-chemical analysis of a new family of layered nanocrystals (NCs) obtained by a liquid-phase assembly reaction of exfoliated, negatively charged MoS2 sheets with alkyldiammonium ions. A combined PXRD, TEM, FTIR and DFT study allowed us to determine the atomic structure of these turbostratically disordered NCs and to reveal the topology of cation-MoS2 binding interactions. The diamine molecules sandwiched between the sulfur layers of the adjacent 1T-MoS2 sheets were found to interlink these sheets through the hydrogen bonding interaction network. Quantification of these interactions on the basis of the analysis of calculated electron density distribution showed that the strong NH···S bonds contribute 40-80% of the total cation-MoS2 hydrogen bonding interaction energy (33-38 kcal/mol), being accompanied by the contribution of the weaker, but more numerous CH···S bonds. The short-range ordering in the positions of neighboring MoS2 layers was identified and its relationship with organic-inorganic hydrogen bonding was established. DFT based comparison of energetic characteristics for the assembled NCs and their delaminated and deprotonated models was performed in order to evaluate stability of NCs against delamination and deprotonation. The data obtained in this study show the prospect for crystal engineering of hydrogen-bonding-based new MoS2-organic nanomaterials.",

keywords = "TOTAL-ENERGY CALCULATIONS, MOLYBDENUM-DISULFIDE, PHASE-TRANSITION, EVOLUTION REACTION, 1T-MOS2 SHEETS, STABILIZATION, INTERCALATION, NANOCOMPOSITE, HYBRIDIZATION, MORPHOLOGY",

author = "Ushakov, {Ivan E.} and Goloveshkin, {Alexander S.} and Lenenko, {Natalia D.} and Ezernitskaya, {Mariam G.} and Korlyukov, {Alexander A.} and Zaikovskii, {Vladimir I.} and Golub, {Alexandre S.}",

note = "Publisher Copyright: {\textcopyright} 2018 American Chemical Society.",

year = "2018",

month = sep,

day = "5",

doi = "10.1021/acs.cgd.8b00551",

language = "English",

volume = "18",

pages = "5116--5123",

journal = "Crystal Growth and Design",

issn = "1528-7483",

publisher = "American Chemical Society",

number = "9",

}

RIS

TY - JOUR

T1 - Hydrogen Bond-Driven Self-Assembly between Single-Layer MoS2 and Alkyldiamine Molecules

AU - Ushakov, Ivan E.

AU - Goloveshkin, Alexander S.

AU - Lenenko, Natalia D.

AU - Ezernitskaya, Mariam G.

AU - Korlyukov, Alexander A.

AU - Zaikovskii, Vladimir I.

AU - Golub, Alexandre S.

PY - 2018/9/5

Y1 - 2018/9/5

N2 - We report the synthesis, structure determination, and quantum-chemical analysis of a new family of layered nanocrystals (NCs) obtained by a liquid-phase assembly reaction of exfoliated, negatively charged MoS2 sheets with alkyldiammonium ions. A combined PXRD, TEM, FTIR and DFT study allowed us to determine the atomic structure of these turbostratically disordered NCs and to reveal the topology of cation-MoS2 binding interactions. The diamine molecules sandwiched between the sulfur layers of the adjacent 1T-MoS2 sheets were found to interlink these sheets through the hydrogen bonding interaction network. Quantification of these interactions on the basis of the analysis of calculated electron density distribution showed that the strong NH···S bonds contribute 40-80% of the total cation-MoS2 hydrogen bonding interaction energy (33-38 kcal/mol), being accompanied by the contribution of the weaker, but more numerous CH···S bonds. The short-range ordering in the positions of neighboring MoS2 layers was identified and its relationship with organic-inorganic hydrogen bonding was established. DFT based comparison of energetic characteristics for the assembled NCs and their delaminated and deprotonated models was performed in order to evaluate stability of NCs against delamination and deprotonation. The data obtained in this study show the prospect for crystal engineering of hydrogen-bonding-based new MoS2-organic nanomaterials.

AB - We report the synthesis, structure determination, and quantum-chemical analysis of a new family of layered nanocrystals (NCs) obtained by a liquid-phase assembly reaction of exfoliated, negatively charged MoS2 sheets with alkyldiammonium ions. A combined PXRD, TEM, FTIR and DFT study allowed us to determine the atomic structure of these turbostratically disordered NCs and to reveal the topology of cation-MoS2 binding interactions. The diamine molecules sandwiched between the sulfur layers of the adjacent 1T-MoS2 sheets were found to interlink these sheets through the hydrogen bonding interaction network. Quantification of these interactions on the basis of the analysis of calculated electron density distribution showed that the strong NH···S bonds contribute 40-80% of the total cation-MoS2 hydrogen bonding interaction energy (33-38 kcal/mol), being accompanied by the contribution of the weaker, but more numerous CH···S bonds. The short-range ordering in the positions of neighboring MoS2 layers was identified and its relationship with organic-inorganic hydrogen bonding was established. DFT based comparison of energetic characteristics for the assembled NCs and their delaminated and deprotonated models was performed in order to evaluate stability of NCs against delamination and deprotonation. The data obtained in this study show the prospect for crystal engineering of hydrogen-bonding-based new MoS2-organic nanomaterials.

KW - TOTAL-ENERGY CALCULATIONS

KW - MOLYBDENUM-DISULFIDE

KW - PHASE-TRANSITION

KW - EVOLUTION REACTION

KW - 1T-MOS2 SHEETS

KW - STABILIZATION

KW - INTERCALATION

KW - NANOCOMPOSITE

KW - HYBRIDIZATION

KW - MORPHOLOGY

UR - http://www.scopus.com/inward/record.url?scp=85052297997&partnerID=8YFLogxK

U2 - 10.1021/acs.cgd.8b00551

DO - 10.1021/acs.cgd.8b00551

M3 - Article

AN - SCOPUS:85052297997

VL - 18

SP - 5116

EP - 5123

JO - Crystal Growth and Design

JF - Crystal Growth and Design

SN - 1528-7483

IS - 9

ER -

ID: 16484060