TY  - CONF
AU  - Milovanović, Milan R.
AU  - Živković, Jelena M.
AU  - Ninković, Dragan B.
AU  - Blagojević Filipović, Jelena P.
AU  - Vojislavljević-Vasilev, Dubravka Z.
AU  - Veljković, Ivana S.
AU  - Stanković, Ivana M.
AU  - Malenov, Dušan P.
AU  - Medaković, Vesna
AU  - Veljković, Dušan Ž.
AU  - Zarić, Snežana D.
PY  - 2021
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/5347
AB  - In the recent review it was point out that the crystal structures in the Cambridge Structural Database (CSD), collected, have contributeto various fields of chemical research such as geometries of molecules, noncovalent interactions of molecules, and large assemblies ofmolecules. The CSD also contributed to the study and the design of biologically active molecules and the study of gas storage anddelivery [1].In our group we use analysis of the crystal structures in the CSD to recognize and characterize new types of noncovalent interactionsand to study already known noncovalent interactions. Based on the data from the CSD we can determine existence of the interactions,frequency of the interactions, and preferred geometries of the interactions in the crystal structures. In addition, we perform quantumchemical calculations to evaluate the energies of the interactions. Based on the calculated potential energy surfaces for theinteractions, we can determine the most stable geometries, as well as stability of various geometries. We also can determine theinteraction energies for the preferred geometries in the crystal structures. In the cases where the most preferred geometries in thecrystal structures are not the most stable geometries at the potential energy surface, one can find significant influence of thesupramolecular structures in the crystals.Using this methodology our group recognized stacking interactions of planar metal-chelate rings; stacking interactions with organicaromatic rings and stacking interactions between two chelate rings. The calculated energies indicate strong stacking interactions ofmetal-chelate rings; the stacking of metal-chelate rings is stronger than stacking between two benzene molecules [2]. The data indicateinfluence of the metal and ligand type in the metal chelate ring on the strength of the interactions. Our results also indicate strongstacking interactions of coordinated aromatic rings [3]. Studies of interactions of coordinated water indicate stronger hydrogen bondsand stronger OH/π interactions of coordinated in comparison to noncoordianted water molecule [4,5]. The calculations on OH/Minteractions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongesthydrogen bonds in any molecular system [6].The studies on stacking interactions of benzene molecules in the crystal structures in the CSD show preference for interactions at largehorizontal displacements, while high level quantum chemical calculations indicate significantly strong interactions at large offsets; theenergy is 70% of the strongest stacking geometry [7].
PB  - The International Union of Crystallography (IUCr)
C3  - Acta Crystallographica, section A
T1  - Study of noncovalent interactions using crystal structure data in the Cambridge Structural Database
VL  - A77
SP  - C192
DO  - 10.1107/S0108767321094903
ER  - 

@conference{
author = "Milovanović, Milan R. and Živković, Jelena M. and Ninković, Dragan B. and Blagojević Filipović, Jelena P. and Vojislavljević-Vasilev, Dubravka Z. and Veljković, Ivana S. and Stanković, Ivana M. and Malenov, Dušan P. and Medaković, Vesna and Veljković, Dušan Ž. and Zarić, Snežana D.",
year = "2021",
abstract = "In the recent review it was point out that the crystal structures in the Cambridge Structural Database (CSD), collected, have contributeto various fields of chemical research such as geometries of molecules, noncovalent interactions of molecules, and large assemblies ofmolecules. The CSD also contributed to the study and the design of biologically active molecules and the study of gas storage anddelivery [1].In our group we use analysis of the crystal structures in the CSD to recognize and characterize new types of noncovalent interactionsand to study already known noncovalent interactions. Based on the data from the CSD we can determine existence of the interactions,frequency of the interactions, and preferred geometries of the interactions in the crystal structures. In addition, we perform quantumchemical calculations to evaluate the energies of the interactions. Based on the calculated potential energy surfaces for theinteractions, we can determine the most stable geometries, as well as stability of various geometries. We also can determine theinteraction energies for the preferred geometries in the crystal structures. In the cases where the most preferred geometries in thecrystal structures are not the most stable geometries at the potential energy surface, one can find significant influence of thesupramolecular structures in the crystals.Using this methodology our group recognized stacking interactions of planar metal-chelate rings; stacking interactions with organicaromatic rings and stacking interactions between two chelate rings. The calculated energies indicate strong stacking interactions ofmetal-chelate rings; the stacking of metal-chelate rings is stronger than stacking between two benzene molecules [2]. The data indicateinfluence of the metal and ligand type in the metal chelate ring on the strength of the interactions. Our results also indicate strongstacking interactions of coordinated aromatic rings [3]. Studies of interactions of coordinated water indicate stronger hydrogen bondsand stronger OH/π interactions of coordinated in comparison to noncoordianted water molecule [4,5]. The calculations on OH/Minteractions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongesthydrogen bonds in any molecular system [6].The studies on stacking interactions of benzene molecules in the crystal structures in the CSD show preference for interactions at largehorizontal displacements, while high level quantum chemical calculations indicate significantly strong interactions at large offsets; theenergy is 70% of the strongest stacking geometry [7].",
publisher = "The International Union of Crystallography (IUCr)",
journal = "Acta Crystallographica, section A",
title = "Study of noncovalent interactions using crystal structure data in the Cambridge Structural Database",
volume = "A77",
pages = "C192",
doi = "10.1107/S0108767321094903"
}

Milovanović, M. R., Živković, J. M., Ninković, D. B., Blagojević Filipović, J. P., Vojislavljević-Vasilev, D. Z., Veljković, I. S., Stanković, I. M., Malenov, D. P., Medaković, V., Veljković, D. Ž.,& Zarić, S. D.. (2021). Study of noncovalent interactions using crystal structure data in the Cambridge Structural Database. in Acta Crystallographica, section A
The International Union of Crystallography (IUCr)., A77, C192.
https://doi.org/10.1107/S0108767321094903

Milovanović MR, Živković JM, Ninković DB, Blagojević Filipović JP, Vojislavljević-Vasilev DZ, Veljković IS, Stanković IM, Malenov DP, Medaković V, Veljković DŽ, Zarić SD. Study of noncovalent interactions using crystal structure data in the Cambridge Structural Database. in Acta Crystallographica, section A. 2021;A77:C192.
doi:10.1107/S0108767321094903 .

Milovanović, Milan R., Živković, Jelena M., Ninković, Dragan B., Blagojević Filipović, Jelena P., Vojislavljević-Vasilev, Dubravka Z., Veljković, Ivana S., Stanković, Ivana M., Malenov, Dušan P., Medaković, Vesna, Veljković, Dušan Ž., Zarić, Snežana D., "Study of noncovalent interactions using crystal structure data in the Cambridge Structural Database" in Acta Crystallographica, section A, A77 (2021):C192,
https://doi.org/10.1107/S0108767321094903 . .

TY  - CONF
AU  - Ninković, Dragan
AU  - Malenov, Dušan
AU  - Veljković, Dušan
AU  - Andrić, Jelena M.
AU  - Vojislavljević-Vasilev, Dubravka
AU  - Veljković, Ivana
AU  - Zarić, Snežana
PY  - 2019
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/7502
AB  - We studied noncovalent interactions of metal complexes and described several new types of these interactions. Our studies are based on analyzing data in crystal structures from the Cambridge Structural Database (CSD) and on quantum chemical calculations. The analysis of the data from the CSD enable to recognize interactions in crystal structures and to describe the geometries of these interactions, while by quantum chemical calculations we can evaluate interaction energies and find the most stable interaction geometries.Our study of planar metal-chelate rings interactions, based on data in the CSD, showed possibility of chelate ring stacking interactions with organic aromatic rings, and stacking interactions between two chelate rings in crystal structures. The quantum chemical calculations indicate strong stacking interactions of metal-chelate rings; the stacking of metal- chelate rings is stronger than stacking between two benzene molecules.Studies of interactions of coordinated water and ammonia indicate stronger hydrogen bonds and stronger OH/π and NH/π interactions of coordinated in comparison to noncoordianted water and ammonia. Namely in the crystal structures the interaction distances are shorter, while the calculations show larger interactions energies.The calculations on OH/M interactions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongest hydrogen bonds in any molecular system.
C3  - XVII International Conference on Coordination and Bioinorganic Chemistry, Progressive Trends in Coordination, Bioinorganic, and Applied Inorganic Chemistry, Smolenice, Slovakia, June 2-7, 2019
T1  - Noncovalent interactions of metal complexes
SP  - 122
EP  - 122
UR  - https://hdl.handle.net/21.15107/rcub_cer_7502
ER  - 

@conference{
author = "Ninković, Dragan and Malenov, Dušan and Veljković, Dušan and Andrić, Jelena M. and Vojislavljević-Vasilev, Dubravka and Veljković, Ivana and Zarić, Snežana",
year = "2019",
abstract = "We studied noncovalent interactions of metal complexes and described several new types of these interactions. Our studies are based on analyzing data in crystal structures from the Cambridge Structural Database (CSD) and on quantum chemical calculations. The analysis of the data from the CSD enable to recognize interactions in crystal structures and to describe the geometries of these interactions, while by quantum chemical calculations we can evaluate interaction energies and find the most stable interaction geometries.Our study of planar metal-chelate rings interactions, based on data in the CSD, showed possibility of chelate ring stacking interactions with organic aromatic rings, and stacking interactions between two chelate rings in crystal structures. The quantum chemical calculations indicate strong stacking interactions of metal-chelate rings; the stacking of metal- chelate rings is stronger than stacking between two benzene molecules.Studies of interactions of coordinated water and ammonia indicate stronger hydrogen bonds and stronger OH/π and NH/π interactions of coordinated in comparison to noncoordianted water and ammonia. Namely in the crystal structures the interaction distances are shorter, while the calculations show larger interactions energies.The calculations on OH/M interactions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongest hydrogen bonds in any molecular system.",
journal = "XVII International Conference on Coordination and Bioinorganic Chemistry, Progressive Trends in Coordination, Bioinorganic, and Applied Inorganic Chemistry, Smolenice, Slovakia, June 2-7, 2019",
title = "Noncovalent interactions of metal complexes",
pages = "122-122",
url = "https://hdl.handle.net/21.15107/rcub_cer_7502"
}

Ninković, D., Malenov, D., Veljković, D., Andrić, J. M., Vojislavljević-Vasilev, D., Veljković, I.,& Zarić, S.. (2019). Noncovalent interactions of metal complexes. in XVII International Conference on Coordination and Bioinorganic Chemistry, Progressive Trends in Coordination, Bioinorganic, and Applied Inorganic Chemistry, Smolenice, Slovakia, June 2-7, 2019, 122-122.
https://hdl.handle.net/21.15107/rcub_cer_7502

Ninković D, Malenov D, Veljković D, Andrić JM, Vojislavljević-Vasilev D, Veljković I, Zarić S. Noncovalent interactions of metal complexes. in XVII International Conference on Coordination and Bioinorganic Chemistry, Progressive Trends in Coordination, Bioinorganic, and Applied Inorganic Chemistry, Smolenice, Slovakia, June 2-7, 2019. 2019;:122-122.
https://hdl.handle.net/21.15107/rcub_cer_7502 .

Ninković, Dragan, Malenov, Dušan, Veljković, Dušan, Andrić, Jelena M., Vojislavljević-Vasilev, Dubravka, Veljković, Ivana, Zarić, Snežana, "Noncovalent interactions of metal complexes" in XVII International Conference on Coordination and Bioinorganic Chemistry, Progressive Trends in Coordination, Bioinorganic, and Applied Inorganic Chemistry, Smolenice, Slovakia, June 2-7, 2019 (2019):122-122,
https://hdl.handle.net/21.15107/rcub_cer_7502 .

TY  - CONF
AU  - Ninković, Dragan B.
AU  - Veljković, Dušan
AU  - Malenov, Dusan P.
AU  - Milovanović, Milan R.
AU  - Stanković, Ivana
AU  - Veljković, Ivana S.
AU  - Medaković, Vesna B.
AU  - Blagojević Filipović, Jelena
AU  - Vojislavljević-Vasilev, Dubravka Z.
AU  - Zarić, Snežana
PY  - 2019
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/6620
AB  - Our research is based on analyzing data in crystal structures from the Cambridge Structural Database (CSD) and on quantum chemical calculations. The analysis of the data from the CSD enable to recognize interactions in crystal structures and to describe the geometries of these interactions, while by quantum chemical calculations we can evaluate interaction energies and find the most stable interaction geometries. Using this methodology we were able to recognize and describe several new types of noncovalent interactions. Our study of planar metal-chelate rings interactions showed possibility of chelate ring stacking interactions with organic aromatic rings, and stacking interactions between two chelate rings. The calculated energies indicate strong stacking interactions of metal-chelate rings; the stacking of metal-chelate rings is stronger than stacking between two benzene molecules. Studies of interactions of coordinated water and ammonia indicate stronger hydrogen bonds and stronger OH/pi and NH/pi interactions of coordinated in comparison to noncoordianted water and ammonia. The calculations on OH/M interac-tions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongest hydrogen bonds in any molecular system. The studies on aromatic molecules indicate stacking interactions at large horizontal dispacements between two aromatic molecules with significantly strong interacitons, the energy is 70% of the strongest stacking geometry. Our data also indicate that stacking interactions of an aliphatic rings with an aromatic ring are stonger than interactions between two aromatic molecules, while aliphatic/aromatic interactions are very frequent in protein structures.
PB  - Serbian Crystallographic Society
C3  - 26th Conference of the Serbian Crystallographic Society, Abstracts, Silver Lake, Serbia / XXVI Konferencija Srpskog kristalografskog društva, Izvodi radova, Srebrno jezero, Srbija
T1  - Noncovalent Interactions оf Metal Complexes аnd Aromatic Molecules
SP  - 9
EP  - 9
UR  - https://hdl.handle.net/21.15107/rcub_cer_6620
ER  - 

@conference{
author = "Ninković, Dragan B. and Veljković, Dušan and Malenov, Dusan P. and Milovanović, Milan R. and Stanković, Ivana and Veljković, Ivana S. and Medaković, Vesna B. and Blagojević Filipović, Jelena and Vojislavljević-Vasilev, Dubravka Z. and Zarić, Snežana",
year = "2019",
abstract = "Our research is based on analyzing data in crystal structures from the Cambridge Structural Database (CSD) and on quantum chemical calculations. The analysis of the data from the CSD enable to recognize interactions in crystal structures and to describe the geometries of these interactions, while by quantum chemical calculations we can evaluate interaction energies and find the most stable interaction geometries. Using this methodology we were able to recognize and describe several new types of noncovalent interactions. Our study of planar metal-chelate rings interactions showed possibility of chelate ring stacking interactions with organic aromatic rings, and stacking interactions between two chelate rings. The calculated energies indicate strong stacking interactions of metal-chelate rings; the stacking of metal-chelate rings is stronger than stacking between two benzene molecules. Studies of interactions of coordinated water and ammonia indicate stronger hydrogen bonds and stronger OH/pi and NH/pi interactions of coordinated in comparison to noncoordianted water and ammonia. The calculations on OH/M interac-tions between metal ion in square-planar complexes and water molecule indicate that these interactions are among the strongest hydrogen bonds in any molecular system. The studies on aromatic molecules indicate stacking interactions at large horizontal dispacements between two aromatic molecules with significantly strong interacitons, the energy is 70% of the strongest stacking geometry. Our data also indicate that stacking interactions of an aliphatic rings with an aromatic ring are stonger than interactions between two aromatic molecules, while aliphatic/aromatic interactions are very frequent in protein structures.",
publisher = "Serbian Crystallographic Society",
journal = "26th Conference of the Serbian Crystallographic Society, Abstracts, Silver Lake, Serbia / XXVI Konferencija Srpskog kristalografskog društva, Izvodi radova, Srebrno jezero, Srbija",
title = "Noncovalent Interactions оf Metal Complexes аnd Aromatic Molecules",
pages = "9-9",
url = "https://hdl.handle.net/21.15107/rcub_cer_6620"
}

Ninković, D. B., Veljković, D., Malenov, D. P., Milovanović, M. R., Stanković, I., Veljković, I. S., Medaković, V. B., Blagojević Filipović, J., Vojislavljević-Vasilev, D. Z.,& Zarić, S.. (2019). Noncovalent Interactions оf Metal Complexes аnd Aromatic Molecules. in 26th Conference of the Serbian Crystallographic Society, Abstracts, Silver Lake, Serbia / XXVI Konferencija Srpskog kristalografskog društva, Izvodi radova, Srebrno jezero, Srbija
Serbian Crystallographic Society., 9-9.
https://hdl.handle.net/21.15107/rcub_cer_6620

Ninković DB, Veljković D, Malenov DP, Milovanović MR, Stanković I, Veljković IS, Medaković VB, Blagojević Filipović J, Vojislavljević-Vasilev DZ, Zarić S. Noncovalent Interactions оf Metal Complexes аnd Aromatic Molecules. in 26th Conference of the Serbian Crystallographic Society, Abstracts, Silver Lake, Serbia / XXVI Konferencija Srpskog kristalografskog društva, Izvodi radova, Srebrno jezero, Srbija. 2019;:9-9.
https://hdl.handle.net/21.15107/rcub_cer_6620 .

Ninković, Dragan B., Veljković, Dušan, Malenov, Dusan P., Milovanović, Milan R., Stanković, Ivana, Veljković, Ivana S., Medaković, Vesna B., Blagojević Filipović, Jelena, Vojislavljević-Vasilev, Dubravka Z., Zarić, Snežana, "Noncovalent Interactions оf Metal Complexes аnd Aromatic Molecules" in 26th Conference of the Serbian Crystallographic Society, Abstracts, Silver Lake, Serbia / XXVI Konferencija Srpskog kristalografskog društva, Izvodi radova, Srebrno jezero, Srbija (2019):9-9,
https://hdl.handle.net/21.15107/rcub_cer_6620 .

TY  - JOUR
AU  - Vojislavljevic-Vasilev, Dubravka Z
AU  - Janjić, Goran
AU  - Medaković, Vesna
AU  - Blagojevic, Jelena P
AU  - Zarić, Snežana D.
PY  - 2014
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/1570
AB  - The parallel interactions of non-coordinated and coordinated water molecules with an aromatic ring were studied by analyzing data in the Cambridge structural database (CSD) and by using quantum chemical calculations. The CSD data show that water/aromatic contacts prefer parallel to OH/pi interactions, which indicates the importance of parallel interactions. The results reveal the influence of water coordination to a metal ion; the interactions of aqua complexes are stronger. Coordinated water molecules prefer a parallel-down orientation in which one O-H bond is parallel to the aromatic ring, whereas the other O-H bond points to the plane of the ring. The interactions of aqua complexes with parallel-down water/benzene orientation are as strong as the much better known OH/pi orientations. The strongest calculated interaction energy is -14.89 kcal mol(-1). The large number of parallel contacts in crystal structures and the quite strong interactions indicate the importance of parallel orientation in water/benzene interactions.
PB  - Wiley-V C H Verlag Gmbh, Weinheim
T2  - Chemphyschem
T1  - Parallel Water/Aromatic Interactions of Non-Coordinated and Coordinated Water
VL  - 15
IS  - 11
SP  - 2386
EP  - 2396
DO  - 10.1002/cphc.201402004
ER  - 

@article{
author = "Vojislavljevic-Vasilev, Dubravka Z and Janjić, Goran and Medaković, Vesna and Blagojevic, Jelena P and Zarić, Snežana D.",
year = "2014",
abstract = "The parallel interactions of non-coordinated and coordinated water molecules with an aromatic ring were studied by analyzing data in the Cambridge structural database (CSD) and by using quantum chemical calculations. The CSD data show that water/aromatic contacts prefer parallel to OH/pi interactions, which indicates the importance of parallel interactions. The results reveal the influence of water coordination to a metal ion; the interactions of aqua complexes are stronger. Coordinated water molecules prefer a parallel-down orientation in which one O-H bond is parallel to the aromatic ring, whereas the other O-H bond points to the plane of the ring. The interactions of aqua complexes with parallel-down water/benzene orientation are as strong as the much better known OH/pi orientations. The strongest calculated interaction energy is -14.89 kcal mol(-1). The large number of parallel contacts in crystal structures and the quite strong interactions indicate the importance of parallel orientation in water/benzene interactions.",
publisher = "Wiley-V C H Verlag Gmbh, Weinheim",
journal = "Chemphyschem",
title = "Parallel Water/Aromatic Interactions of Non-Coordinated and Coordinated Water",
volume = "15",
number = "11",
pages = "2386-2396",
doi = "10.1002/cphc.201402004"
}

Vojislavljevic-Vasilev, D. Z., Janjić, G., Medaković, V., Blagojevic, J. P.,& Zarić, S. D.. (2014). Parallel Water/Aromatic Interactions of Non-Coordinated and Coordinated Water. in Chemphyschem
Wiley-V C H Verlag Gmbh, Weinheim., 15(11), 2386-2396.
https://doi.org/10.1002/cphc.201402004

Vojislavljevic-Vasilev DZ, Janjić G, Medaković V, Blagojevic JP, Zarić SD. Parallel Water/Aromatic Interactions of Non-Coordinated and Coordinated Water. in Chemphyschem. 2014;15(11):2386-2396.
doi:10.1002/cphc.201402004 .

Vojislavljevic-Vasilev, Dubravka Z, Janjić, Goran, Medaković, Vesna, Blagojevic, Jelena P, Zarić, Snežana D., "Parallel Water/Aromatic Interactions of Non-Coordinated and Coordinated Water" in Chemphyschem, 15, no. 11 (2014):2386-2396,
https://doi.org/10.1002/cphc.201402004 . .

TY  - JOUR
AU  - Vojislavljevic, Dubravka Z.
AU  - Janjić, Goran
AU  - Ninković, Dragan B.
AU  - Kapor, Agnes
AU  - Zarić, Snežana D.
PY  - 2013
UR  - https://cer.ihtm.bg.ac.rs/handle/123456789/1282
AB  - The interactions between water molecules (non-coordinating and coordinating) and aromatic rings were studied by analyzing data in the Cambridge Structural Database and by quantum chemical calculations. The results show the influence of water coordination to a metal ion; interactions of coordinating water are stronger. The MP2/def2-QZVP interaction energies of non-coordinating water and neutral aqua complexes [ScCl3(H2O)(3)], [ZnCl2(H2O)(4)], [CdCl2(H2O)(4)], and [ZnCl2(H2O)(2)] with benzene molecule are -3.36, -5.10, -5.43, -6.86, and -5.14 kcal mol(-1), respectively. Interactions of charged aqua complexes [ZnCl(H2O)(5)](+) and [Zn(H2O)(6)](2+) are stronger, -9.69 and -13.96 kcal mol(-1), respectively. The calculations also reveal strong long-range interactions: at the distance of 3.0 angstrom the interaction energies of neutral complexes are in the range of -4.11 to -4.91 kcal mol(-1), while interaction energies of charged complexes are -6.37 and -10.76 kcal mol(-1).
PB  - Royal Soc Chemistry, Cambridge
T2  - Crystengcomm
T1  - The influence of water molecule coordination onto the water-aromatic interaction. Strong interactions of water coordinating to a metal ion
VL  - 15
IS  - 11
SP  - 2099
EP  - 2105
DO  - 10.1039/c2ce25621e
ER  - 

@article{
author = "Vojislavljevic, Dubravka Z. and Janjić, Goran and Ninković, Dragan B. and Kapor, Agnes and Zarić, Snežana D.",
year = "2013",
abstract = "The interactions between water molecules (non-coordinating and coordinating) and aromatic rings were studied by analyzing data in the Cambridge Structural Database and by quantum chemical calculations. The results show the influence of water coordination to a metal ion; interactions of coordinating water are stronger. The MP2/def2-QZVP interaction energies of non-coordinating water and neutral aqua complexes [ScCl3(H2O)(3)], [ZnCl2(H2O)(4)], [CdCl2(H2O)(4)], and [ZnCl2(H2O)(2)] with benzene molecule are -3.36, -5.10, -5.43, -6.86, and -5.14 kcal mol(-1), respectively. Interactions of charged aqua complexes [ZnCl(H2O)(5)](+) and [Zn(H2O)(6)](2+) are stronger, -9.69 and -13.96 kcal mol(-1), respectively. The calculations also reveal strong long-range interactions: at the distance of 3.0 angstrom the interaction energies of neutral complexes are in the range of -4.11 to -4.91 kcal mol(-1), while interaction energies of charged complexes are -6.37 and -10.76 kcal mol(-1).",
publisher = "Royal Soc Chemistry, Cambridge",
journal = "Crystengcomm",
title = "The influence of water molecule coordination onto the water-aromatic interaction. Strong interactions of water coordinating to a metal ion",
volume = "15",
number = "11",
pages = "2099-2105",
doi = "10.1039/c2ce25621e"
}

Vojislavljevic, D. Z., Janjić, G., Ninković, D. B., Kapor, A.,& Zarić, S. D.. (2013). The influence of water molecule coordination onto the water-aromatic interaction. Strong interactions of water coordinating to a metal ion. in Crystengcomm
Royal Soc Chemistry, Cambridge., 15(11), 2099-2105.
https://doi.org/10.1039/c2ce25621e

Vojislavljevic DZ, Janjić G, Ninković DB, Kapor A, Zarić SD. The influence of water molecule coordination onto the water-aromatic interaction. Strong interactions of water coordinating to a metal ion. in Crystengcomm. 2013;15(11):2099-2105.
doi:10.1039/c2ce25621e .

Vojislavljevic, Dubravka Z., Janjić, Goran, Ninković, Dragan B., Kapor, Agnes, Zarić, Snežana D., "The influence of water molecule coordination onto the water-aromatic interaction. Strong interactions of water coordinating to a metal ion" in Crystengcomm, 15, no. 11 (2013):2099-2105,
https://doi.org/10.1039/c2ce25621e . .