fbpx
Wikipedia

Ligand cone angle

December 14, 2023

In coordination chemistry, the ligand cone angle (θ) is a measure of the steric bulk of a ligand in a transition metal coordination complex. It is defined as the solid angle formed with the metal at the vertex of a cone and the outermost edge of the van der Waals spheres of the ligand atoms at the perimeter of the base of the cone. Tertiary phosphine ligands are commonly classified using this parameter, but the method can be applied to any ligand. The term cone angle was first introduced by Chadwick A. Tolman, a research chemist at DuPont. Tolman originally developed the method for phosphine ligands in nickel complexes, determining them from measurements of accurate physical models.[1][2][3]

Asymmetric cases edit

The concept of cone angle is most easily visualized with symmetrical ligands, e.g. PR3. But the approach has been refined to include less symmetrical ligands of the type PRR′R″ as well as diphosphines. In such asymmetric cases, the substituent angles' half angles, θi/2, are averaged and then doubled to find the total cone angle, θ. In the case of diphosphines, the θi/2 of the backbone is approximated as half the chelate bite angle, assuming a bite angle of 74°, 85°, and 90° for diphosphines with methylene, ethylene, and propylene backbones, respectively. The Manz cone angle is often easier to compute than the Tolman cone angle:[4][clarification needed]

Cone angles of common phosphine ligands
Ligand Angle (°)
PH3 87[1]
PF3 104[1]
P(OCH3)3 107[1]
dmpe 107
depe 115
P(CH3)3 118[1]
dppm 121
dppe 125
dppp 127
P(CH2CH3)3 132[1]
dcpe 142
P(C6H5)3 145[1]
P(cyclo-C6H11)3 179[1]
P(t-Bu)3 182[1]
P(C6F5)3 184[1]
P(C6H4-2-CH3)3 194[1]
P(2,4,6-Me3C6H2)3 212
 

Variations edit

The Tolman cone angle method assumes empirical bond data and defines the perimeter as the maximum possible circumscription of an idealized free-spinning substituent. The metal-ligand bond length in the Tolman model was determined empirically from crystal structures of tetrahedral nickel complexes. In contrast, the solid-angle concept derives both bond length and the perimeter from empirical solid state crystal structures.[5][6] There are advantages to each system.

If the geometry of a ligand is known, either through crystallography or computations, an exact cone angle (θ) can be calculated.[7][8][9] No assumptions about the geometry are made, unlike the Tolman method.

Application edit

The concept of cone angle is of practical importance in homogeneous catalysis because the size of the ligand affects the reactivity of the attached metal center. In an[10] example, the selectivity of hydroformylation catalysts is strongly influenced by the size of the coligands. Despite being monovalent, some phosphines are large enough to occupy more than half of the coordination sphere of a metal center. Recent research has found that other descriptors—such as percent buried volume—are more accurate than cone angle at capturing the relevant steric effects of the phosphine ligand(s) when bound to the metal center.[11]

See also edit

References edit

  1. ^ a b c d e f g h i j k Tolman, Chadwick A. (1970-05-01). "Phosphorus ligand exchange equilibriums on zerovalent nickel. Dominant role for steric effects". J. Am. Chem. Soc. 92 (10): 2956–2965. doi:10.1021/ja00713a007.
  2. ^ Tolman, C. A.; Seidel, W. C.; Gosser, L. W. (1974-01-01). "Formation of three-coordinate nickel(0) complexes by phosphorus ligand dissociation from NiL4". J. Am. Chem. Soc. 96 (1): 53–60. doi:10.1021/ja00808a009.
  3. ^ Tolman, C. A. (1977). "Steric Effects of Phosphorus Ligands in Organometallic Chemistry and Homogeneous Catalysis". Chem. Rev. 77 (3): 313–48. doi:10.1021/cr60307a002.
  4. ^ Manz, T. A.; Phomphrai, K.; Medvedev, G.; Krishnamurthy, B. B.; Sharma, S.; Haq, J.; Novstrup, K. A.; Thomson, K. T.; Delgass, W. N.; Caruthers, J. M.; Abu-Omar, M. M. (2007). "Structure−Activity Correlation in Titanium Single-Site Olefin Polymerization Catalysts Containing Mixed Cyclopentadienyl/Aryloxide Ligation". J. Am. Chem. Soc. 129 (13): 3776–3777. doi:10.1021/ja0640849. PMID 17348648.
  5. ^ Immirzi, A.; Musco, A. (1977). "A method to measure the size of phosphorus ligands in coordination complexes". Inorg. Chim. Acta. 25: L41–L42. doi:10.1016/S0020-1693(00)95635-4.[dead link]
  6. ^ Niksch, Tobias; Görls, Helmar; Weigand, Wolfgang (2009). "The Extension of the Solid-Angle Concept to Bidentate Ligands". Eur. J. Inorg. Chem. 2010 (1): 95–105. doi:10.1002/ejic.200900825.
  7. ^ Bilbrey, Jenna A.; Kazez, Arianna H.; Locklin, J.; Allen, Wesley D. (2013). "Exact ligand cone angles". Journal of Computational Chemistry. 34 (14): 1189–1197. doi:10.1002/jcc.23217. PMID 23408559. S2CID 23864226.
  8. ^ "AaronTools". aarontools.readthedocs.io. Retrieved 2023-05-30.
  9. ^ Petitjean, Michel (2015). "Analytical Algorithms for Ligand Cone Angles Calculations. Application to Triphenylphosphine Palladium Complexes". Comptes Rendus Chimie. 18 (6): 678–684. doi:10.1016/j.crci.2015.04.004.
  10. ^ Evans, D.; Osborn, J. A.; Wilkinson, G. (1968). "Hydroformylation of Alkenes by Use of Rhodium Complex Catalyst". Journal of the Chemical Society. 33 (21): 3133–3142. doi:10.1039/J19680003133.
  11. ^ Newman-Stonebraker, Samuel H.; Smith, Sleight R.; Borowski, Julia E.; Peters, Ellyn; Gensch, Tobias; Johnson, Heather C.; Sigman, Matthew S.; Doyle, Abigail G. (2021). "Univariate classification of phosphine ligation state and reactivity in cross-coupling catalysis". Science. 374 (6565): 301–308. Bibcode:2021Sci...374..301N. doi:10.1126/science.abj4213. PMID 34648340. S2CID 238991361.

December 14, 2023
ligand, cone, angle, coordination, chemistry, ligand, cone, angle, measure, steric, bulk, ligand, transition, metal, coordination, complex, defined, solid, angle, formed, with, metal, vertex, cone, outermost, edge, waals, spheres, ligand, atoms, perimeter, bas. In coordination chemistry the ligand cone angle 8 is a measure of the steric bulk of a ligand in a transition metal coordination complex It is defined as the solid angle formed with the metal at the vertex of a cone and the outermost edge of the van der Waals spheres of the ligand atoms at the perimeter of the base of the cone Tertiary phosphine ligands are commonly classified using this parameter but the method can be applied to any ligand The term cone angle was first introduced by Chadwick A Tolman a research chemist at DuPont Tolman originally developed the method for phosphine ligands in nickel complexes determining them from measurements of accurate physical models 1 2 3 Contents 1 Asymmetric cases 2 Variations 3 Application 4 See also 5 ReferencesAsymmetric cases editThe concept of cone angle is most easily visualized with symmetrical ligands e g PR3 But the approach has been refined to include less symmetrical ligands of the type PRR R as well as diphosphines In such asymmetric cases the substituent angles half angles 8i 2 are averaged and then doubled to find the total cone angle 8 In the case of diphosphines the 8i 2 of the backbone is approximated as half the chelate bite angle assuming a bite angle of 74 85 and 90 for diphosphines with methylene ethylene and propylene backbones respectively The Manz cone angle is often easier to compute than the Tolman cone angle 4 clarification needed Cone angles of common phosphine ligands Ligand Angle PH3 87 1 PF3 104 1 P OCH3 3 107 1 dmpe 107depe 115P CH3 3 118 1 dppm 121dppe 125dppp 127P CH2CH3 3 132 1 dcpe 142P C6H5 3 145 1 P cyclo C6H11 3 179 1 P t Bu 3 182 1 P C6F5 3 184 1 P C6H4 2 CH3 3 194 1 P 2 4 6 Me3C6H2 3 2128 2 3 i 8 i 2 displaystyle theta frac 2 3 sum i frac theta i 2 nbsp Variations editThe Tolman cone angle method assumes empirical bond data and defines the perimeter as the maximum possible circumscription of an idealized free spinning substituent The metal ligand bond length in the Tolman model was determined empirically from crystal structures of tetrahedral nickel complexes In contrast the solid angle concept derives both bond length and the perimeter from empirical solid state crystal structures 5 6 There are advantages to each system If the geometry of a ligand is known either through crystallography or computations an exact cone angle 8 can be calculated 7 8 9 No assumptions about the geometry are made unlike the Tolman method Application editThe concept of cone angle is of practical importance in homogeneous catalysis because the size of the ligand affects the reactivity of the attached metal center In an 10 example the selectivity of hydroformylation catalysts is strongly influenced by the size of the coligands Despite being monovalent some phosphines are large enough to occupy more than half of the coordination sphere of a metal center Recent research has found that other descriptors such as percent buried volume are more accurate than cone angle at capturing the relevant steric effects of the phosphine ligand s when bound to the metal center 11 See also editSteric effects versus electronic effects Tolman electronic parameterReferences edit a b c d e f g h i j k Tolman Chadwick A 1970 05 01 Phosphorus ligand exchange equilibriums on zerovalent nickel Dominant role for steric effects J Am Chem Soc 92 10 2956 2965 doi 10 1021 ja00713a007 Tolman C A Seidel W C Gosser L W 1974 01 01 Formation of three coordinate nickel 0 complexes by phosphorus ligand dissociation from NiL4 J Am Chem Soc 96 1 53 60 doi 10 1021 ja00808a009 Tolman C A 1977 Steric Effects of Phosphorus Ligands in Organometallic Chemistry and Homogeneous Catalysis Chem Rev 77 3 313 48 doi 10 1021 cr60307a002 Manz T A Phomphrai K Medvedev G Krishnamurthy B B Sharma S Haq J Novstrup K A Thomson K T Delgass W N Caruthers J M Abu Omar M M 2007 Structure Activity Correlation in Titanium Single Site Olefin Polymerization Catalysts Containing Mixed Cyclopentadienyl Aryloxide Ligation J Am Chem Soc 129 13 3776 3777 doi 10 1021 ja0640849 PMID 17348648 Immirzi A Musco A 1977 A method to measure the size of phosphorus ligands in coordination complexes Inorg Chim Acta 25 L41 L42 doi 10 1016 S0020 1693 00 95635 4 dead link Niksch Tobias Gorls Helmar Weigand Wolfgang 2009 The Extension of the Solid Angle Concept to Bidentate Ligands Eur J Inorg Chem 2010 1 95 105 doi 10 1002 ejic 200900825 Bilbrey Jenna A Kazez Arianna H Locklin J Allen Wesley D 2013 Exact ligand cone angles Journal of Computational Chemistry 34 14 1189 1197 doi 10 1002 jcc 23217 PMID 23408559 S2CID 23864226 AaronTools aarontools readthedocs io Retrieved 2023 05 30 Petitjean Michel 2015 Analytical Algorithms for Ligand Cone Angles Calculations Application to Triphenylphosphine Palladium Complexes Comptes Rendus Chimie 18 6 678 684 doi 10 1016 j crci 2015 04 004 Evans D Osborn J A Wilkinson G 1968 Hydroformylation of Alkenes by Use of Rhodium Complex Catalyst Journal of the Chemical Society 33 21 3133 3142 doi 10 1039 J19680003133 Newman Stonebraker Samuel H Smith Sleight R Borowski Julia E Peters Ellyn Gensch Tobias Johnson Heather C Sigman Matthew S Doyle Abigail G 2021 Univariate classification of phosphine ligation state and reactivity in cross coupling catalysis Science 374 6565 301 308 Bibcode 2021Sci 374 301N doi 10 1126 science abj4213 PMID 34648340 S2CID 238991361 Retrieved from https en wikipedia org w index php title Ligand cone angle amp oldid 1163499573, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.