0000000001305367

AUTHOR

Matti Tuikka

showing 15 related works from this author

A Novel Halogen Bond Acceptor : 1-(4-Pyridyl)-4-Thiopyridine (PTP) Zwitterion

2020

Sulfur is a widely used halogen bond (XB) acceptor, but only a limited number of neutral XB acceptors with bifurcated sp3-S sites have been reported. In this work a new bidentate XB acceptor, 1-(4-pyridyl)-4-thiopyridine (PTP), which combines sp3-S and sp2-N acceptor sites, is introduced. Three halogen bonded cocrystals were obtained by using 1,4-diiodobenzene (DIB), 1,4-diiodotetrafluorobenzene (DIFB), and iodopentafluorobenzene (IPFB) as XB donors and PTP as acceptor. The structures of the cocrystals showed some XB selectivity between the S and N donors in PTP. However, the limited contribution of XB to the overall molecular packing in these three cocrystals and the results from DSC measu…

kemialliset sidoksethalogen bonds (xb)rikkiyhdisteetlcsh:QD901-999selectivitylcsh:CrystallographyacceptorcocrystalskiteetHalogen bonds (XB)orgaaniset yhdisteet
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Halogen bond preferences of thiocyanate ligand coordinated to Ru(II) via sulphur atom

2017

Halogen bonding between [Ru(bpy)(CO)2(S-SCN)2] (bpy = 2,2’-bipyridine), I2 was studied by co-crystallising the metal compound and diiodine from dichloromethane. The only observed crystalline product was found to be [Ru(bpy)(CO)2(S-SCN)2]⋅I2 with only one NCS⋅⋅⋅I2 halogen bond between I2 and the metal coordinated S atom of one of the thiocyanate ligand. The dangling nitrogen atoms were not involved in halogen bonding. However, computational analysis suggests that there are no major energetic differences between the NCS⋅⋅⋅I2 and SCN⋅⋅⋅I2 bonding modes. The reason for the observed NCS⋅⋅⋅I2 mode lies most probably in the more favourable packing effects rather than energetic preferences between …

chemistry.chemical_element010402 general chemistryPhotochemistry01 natural sciencesjodiMetalchemistry.chemical_compoundAtomhalogensGeneral Materials Scienceta116DichloromethanethiocyanateHalogen bondhalogeenitThiocyanateiodine010405 organic chemistryLigandRuGeneral ChemistryCondensed Matter PhysicsSulfurNitrogen3. Good health0104 chemical sciencesCrystallographychemistryvisual_arthalogeenisidoksetvisual_art.visual_art_mediumhalogen bondIodineSolid State Sciences
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Fine-tuning halogen bonding properties of diiodine through halogen–halogen charge transfer – extended [Ru(2,2′-bipyridine)(CO)2X2]·I2 systems (X = Cl…

2016

The current paper introduces the use of carbonyl containing ruthenium complexes, [Ru(bpy)(CO)2X2] (X = Cl, Br, I), as halogen bond acceptors for a I2 halogen bond donor. In all structures, the metal coordinated halogenido ligand acts as the actual halogen bond acceptor. Diiodine, I2, molecules are connected to the metal complexes through both ends of the molecule forming bridges between the complexes. Due to the charge transfer from Ru–X to I2, formation of the first Ru–X⋯I2 contact tends to generate a negative charge on I2 and redistribute the electron density anisotropically. If the initial Ru–X⋯IA–IB interaction causes a notable change in the electron density of I2, the increased negativ…

Halogen bond010405 organic chemistryChemistryLigandchemistry.chemical_elementCharge densityGeneral Chemistry010402 general chemistryCondensed Matter PhysicsPhotochemistry01 natural sciencesAcceptor22'-Bipyridine0104 chemical sciencesRutheniumCrystallographychemistry.chemical_compoundhalogen bondingHalogenruthenium complexesMoleculeGeneral Materials Scienceta116CrystEngComm
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Concerted halogen and hydrogen bonding in [RuI2(H2dcbpy)(CO)2]···I2···(CH3OH)···I2···[RuI2(H2dcbpy)(CO)2].

2011

A new type of concerted halogen bond-hydrogen bond interaction was found in the solid state structure of [RuI(2)(H(2)dcbpy)(CO)(2)]···I(2)···(MeOH)···I(2)···[RuI(2)(H(2)dcbpy)(CO)(2)]. The iodine atoms of the two I(2) molecules interact simultaneously with each other and with the OH group of methanol of crystallization. The interaction was characterized by single crystal X-ray measurements and by computational charge density analysis based on DFT calculations.

Hydrogen bondMetals and AlloysCharge densityGeneral ChemistrySolid state structureCatalysisSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialslaw.inventionchemistry.chemical_compoundCrystallographychemistryComputational chemistrylawHalogenMaterials ChemistryCeramics and CompositesMoleculeMethanolCrystallizationSingle crystalta116Chemical communications (Cambridge, England)
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A new copper chloride chain by supported hydrogen bonding

2013

In the current paper we introduce a new type of Cu–Cl polymer ([H2bipip]2+[CuCl3]2−)n. In this polymer the trigonal CuCl3 units are covalently linked via chloride bridges. The structure is supported by the bipiperidinium cation ([H2bipip]2+) via hydrogen bonds. The cation plays an essential role in formation of the polymeric structure. The closely related piperazinium (H2pip)2+ cation also leads to a hydrogen bonded assembly of CuCl3 ([H2pip]2+[CuCl3]2−), but a covalently bound polymer was not obtained.

chemistry.chemical_classificationHydrogenHydrogen bondchemistry.chemical_elementGeneral ChemistryPolymerTrigonal crystal systemCondensed Matter PhysicsChloridechemistryChain (algebraic topology)Covalent bondPolymer chemistrymedicineGeneral Materials ScienceCopper chlorideta116medicine.drugCrystEngComm
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Halogen bonding—a key step in charge recombination of the dye-sensitized solar cell

2011

The halogen bonding between [Ru(dcbpy)(2)(SCN)(2)] dye and I(2) molecule has been studied. The ruthenium complex forms a stable [Ru(dcbpy)(2)(SCN)(2)]···I(2)·4(CH(3)OH) adduct via S···I interaction between the thiocyanate ligand and the I(2) molecule. The adduct can be seen as a model for one of the key intermediates in the regeneration cycle of the oxidized dye by the I(-)/I(3)(-) electrolyte in dye sensitized solar cells.

Halogen bondThiocyanateLigandMetals and Alloyschemistry.chemical_elementGeneral ChemistryElectrolytePhotochemistryCatalysisSurfaces Coatings and FilmsElectronic Optical and Magnetic MaterialsAdductRutheniumchemistry.chemical_compoundDye-sensitized solar cellchemistryMaterials ChemistryCeramics and CompositesMoleculeta116Chemical Communications
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Hydroformylation of 1-Hexene over Rh/Nano-Oxide Catalysts

2013

The effect of nanostructured supports on the activity of Rh catalysts was studied by comparing the catalytic performance of nano- and bulk-oxide supported Rh/ZnO, Rh/SiO₂ and Rh/TiO₂ systems in 1-hexene hydroformylation. The highest activity with 100% total conversion and 96% yield of aldehydes was obtained with the Rh/nano-ZnO catalyst. The Rh/nano-ZnO catalyst was found to be more stable and active than the corresponding rhodium catalyst supported on bulk ZnO. The favorable morphology of Rh/nano-ZnO particles led to an increased metal content and an increased number of weak acid sites compared to the bulk ZnO supported catalysts. Both these factors favored the improved catalytic performan…

Materials scienceScanning electron microscopeInorganic chemistryOxiderodiumchemistry.chemical_elementsupported catalyst02 engineering and technologylcsh:Chemical technology010402 general chemistry7. Clean energy01 natural sciencesCatalysisCatalysisRhodiumlcsh:Chemistrychemistry.chemical_compoundDesorptionlcsh:TP1-1185Physical and Theoretical Chemistryta116hydroformylation of 1-hexenehydroformylointinano-zinc oxide021001 nanoscience & nanotechnology0104 chemical sciences1-Hexenehydroformylation nano-oxidelcsh:QD1-999chemistrykatalyysirhodiumnano-oxidit0210 nano-technologyPowder diffractionHydroformylationCatalysts
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Crystal structure of the pyridine–diiodine (1/1) adduct

2015

In the title adduct, C5H5N·I2, the N—I distance [2.424 (8) Å] is remarkably shorter than the sum of the van der Waals radii. The line through the I atoms forms an angle of 78.39 (16)° with the normal to the pyridine ring.

pyridinecrystal structureNanotechnology02 engineering and technologyCrystal structure010402 general chemistryRing (chemistry)01 natural sciencesAdductlcsh:Chemistrysymbols.namesakechemistry.chemical_compoundPyridineGeneral Materials ScienceVan der Waals radiusta116Halogen bondChemistryGeneral Chemistry021001 nanoscience & nanotechnologyCondensed Matter PhysicsData Reports3. Good health0104 chemical sciencesCrystallographylcsh:QD1-999halogen bondingsymbols0210 nano-technologydiiodine
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A novel bisphosphonate-based solid phase method for effective removal of chromium(iii) from aqueous solutions and tannery effluents

2013

Effective removal of chromium(III) from waste waters e.g. in the leather industry is required due to continuously tightening environmental regulations, and several methods such as precipitation and adsorption are currently in use. Nevertheless, more efficient, straightforward and inexpensive methods are constantly being sought. The current study describes a novel method to separate chromium(III) from aqueous solutions based on the use of solid bisphosphonates with a P–C–P backbone. Five classes of bisphosphonates with different functional groups and alkyl chain lengths at the center carbon, in all 16 compounds, were prepared and their suitability for metal ion complexing as chelating agents…

chemistry.chemical_classificationAqueous solutionPrecipitation (chemistry)General Chemical EngineeringInorganic chemistrychemistry.chemical_elementGeneral ChemistryChromiumAdsorptionchemistryWastewaterChelationCarbonta116AlkylRsc advances
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Extended Assemblies of Ru(bpy)(CO)2X2 (X = Cl, Br, I) Molecules Linked by 1,4-Diiodotetrafluoro-Benzene (DITFB) Halogen Bond Donors

2019

The ruthenium carbonyl compounds, Ru(bpy)(CO)2X2 (X = Cl, Br or I) act as neutral halogen bond (XB) acceptors when co-crystallized with 1,4-diiodotetrafluoro-benzene (DITFB). The halogen bonding strength of the Ru-X&sdot

kemialliset sidoksetcrystal structurebipyridinelcsh:QD901-999halogen bondcarbonyllcsh:CrystallographyorganometalliyhdisteetkiteetrutheniumCrystals
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CCDC 935269: Experimental Crystal Structure Determination

2013

Related Article: Matti Tuikka,Ulo Kersen,Matti Haukka|2013|CrystEngComm|15|6177|doi:10.1039/C3CE40692J

Space GroupCrystallography44'-Bipiperidinium tetrachloro-copper(ii) monohydrateCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinates
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CCDC 935268: Experimental Crystal Structure Determination

2013

Related Article: Matti Tuikka,Ulo Kersen,Matti Haukka|2013|CrystEngComm|15|6177|doi:10.1039/C3CE40692J

Space GroupCrystallographyCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinatescatena-[44'-Bipiperidinium bis((mu~2~-chloro)-chloro-copper)]
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CCDC 1524888: Experimental Crystal Structure Determination

2017

Related Article: Xin Ding, Matti Tuikka, Pipsa Hirva, Matti Haukka|2017|Solid State Sciences|71|8|doi:10.1016/j.solidstatesciences.2017.06.016

Space GroupCrystallographyCrystal SystemCrystal StructureCell Parameters(22'-bipyridine)-(dicarbonyl)-bis(thiocyanato)-ruthenium iodineExperimental 3D Coordinates
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CCDC 935271: Experimental Crystal Structure Determination

2013

Related Article: Matti Tuikka,Ulo Kersen,Matti Haukka|2013|CrystEngComm|15|6177|doi:10.1039/C3CE40692J

Space GroupCrystallographyCrystal SystemCrystal StructureCell ParametersPiperazinediium trichloro-copper(i)Experimental 3D Coordinates
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CCDC 935270: Experimental Crystal Structure Determination

2013

Related Article: Matti Tuikka,Ulo Kersen,Matti Haukka|2013|CrystEngComm|15|6177|doi:10.1039/C3CE40692J

Space GroupCrystallographyCrystal SystemCrystal StructureCell ParametersPiperazinediium tetrachloro-copper(ii)Experimental 3D Coordinates
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