Ion association

In chemistry, ion association is a chemical reaction whereby ions of opposite electrical charge come together in solution to form a distinct chemical entity.[1][2] Ion associates are classified, according to the number of ions that associate with each other, as ion pairs, ion triplets, etc. Ion pairs are also classified according to the nature of the interaction as contact, solvent-shared or solvent-separated. The most important factor to determine the extent of ion association is the dielectric constant of the solvent. Ion associates have been characterized by means of vibrational spectroscopy. The concept was introduced by Niels Bjerrum.[3]

Classification of ion pairs

Ion pairs are formed when a cation and anion, which are present in a solution of an ionizable substance, come together to form a discrete chemical species. There are three distinct types of ion pairs, depending on the extent of solvation of the two ions. For example, magnesium sulphate exists as both contact and solvent-shared ion-pairs in seawater.[4]

Mg2+(aq) + SO42-(aq) Mg(SO4)(aq)

In the schematic representation above, the circles represent spheres. The sizes are arbitrary and not necessarily similar as illustrated. The cation is coloured red and the anion is coloured blue. The green area represents solvent molecules in a primary solvation shell; secondary solvation is ignored. When both ions have a complete primary solvation sphere, the ion pair may be termed fully solvated. When there is about one solvent molecule between cation and anion, the ion pair may be termed solvent-shared. Lastly, when the ions are in contact with each other, the ion pair is termed a contact ion pair. Even in a contact ion pair, however, the ions retain most of their solvation shell. The nature of this solvation shell is generally not known with any certainty. In aqueous solution and in other donor solvents, metal cations are surrounded by between 4 and 9 solvent molecules in the primary solvation shell,[5]

An alternative name for a solvent-shared ion pair is an outer-sphere complex. This usage is common in co-ordination chemistry and denotes a complex between a solvated metal cation and an anion. Similarly, a contact ion pair may be termed an inner-sphere complex. The essential difference between the three types is the closeness with which the ions approach each other: fully solvated > solvent-shared > contact. With fully solvated and solvent-shared ion pairs the interaction is primarily electrostatic, but in a contact ion pair some covalent character in the bond between cation and anion is also present.

An ion triplet may be formed from one cation and two anions or from one anion and two cations.[6] Higher aggregates, such as a tetramer (AB)4, may be formed.

Ternary ion associates involve the association of three species.[7] Another type, named intrusion ion pair, has also been characterized.[8]

Theory

Ions of opposite charge are naturally attracted to each other by the electrostatic force.[9][10] This is described by Coulomb's law:

where F is the force of attraction, q1 and q2 are the magnitudes of the electrical charges, ε is the dielectric constant of the medium and r is the distance between the ions. For ions in solution this is an approximation because the ions exert a polarizing effect on the solvent molecules that surround them, which attenuates the electric field somewhat. Nevertheless, some general conclusions can be inferred.

Ion association will increase as:
  • the magnitude(s) of the electrical charge(s) q1 and q2 increase,
  • the magnitude of the dielectric constant ε decreases,
  • the size of the ions decreases so that the distance r between cation and anion decreases.

The equilibrium constant K for ion-pair formation, like all equilibrium constants, is related to the standard free-energy change:[11]

where R is the gas constant and T is the temperature in kelvins. Free energy is made up of an enthalpy term and an entropy term:

The coulombic energy released when ions associate contributes to the enthalpy term, . In the case of contact ion pairs, the covalent interaction energy also contributes to the enthalpy, as does the energy of displacing a solvent molecule from the solvation shell of the cation or anion. The tendency to associate is opposed by the entropy term, which results from the fact that the solution containing unassociated ions is more disordered than a solution containing associates. The entropy term is similar for electrolytes of the same type, with minor differences due to solvation effects. Therefore, it is the magnitude of the enthalpy term that mostly determines the extent of ion association for a given electrolyte type. This explains the general rules given above.

Occurrence

Dielectric constant is the most important factor in determining the occurrence of ion association. A table of some typical values can be found under Dielectric constant. Water has a relatively high dielectric constant value of 78.7 at 298K (25 °C), so in aqueous solutions at ambient temperatures 1:1 electrolytes such as NaCl do not form ion pairs to an appreciable extent except when the solution is very concentrated.[12] 2:2 electrolytes (q1 = 2, q2 = 2) form ion pairs more readily. Indeed, the solvent-shared ion pair [Mg(H2O)6]2+SO42− was famously discovered to be present in seawater, in equilibrium with the contact ion pair [Mg(H2O)5(SO4)][13] Trivalent ions such as Al3+, Fe3+ and lanthanide ions form weak complexes with monovalent anions.

The dielectric constant of water decreases with increasing temperature to about 55 at 100 °C and about 5 at the critical temperature (217.7 °C).[14] Thus ion pairing will become more significant in superheated water.

Solvents with a dielectric constant in the range, roughly, 20–40, show extensive ion-pair formation. For example, in acetonitrile both contact and solvent-shared ion pairs of Li(NCS) have been observed.[15] In methanol the 2:1 electrolyte Mg(NCS)2 is partially dissociated into a contact ion pair, [Mg(NCS)]+ and the thiocyanate ion.[16]

The dielectric constant of liquid ammonia decreases from 26 at its freezing point (80 °C) to 17 at 20 °C (under pressure). Many simple 1:1 electrolytes form contact ion pairs at ambient temperatures. The extent of ion pairing decreases as temperature decreases. With lithium salts there is evidence to show that both inner-sphere and outer-sphere complexes exist in liquid-ammonia solutions.[17]

Of the solvents with dielectric constant of 10 or less, tetrahydrofuran (THF) is particularly relevant in this context, as it solvates cations strongly with the result that simple electrolytes have sufficient solubility to make the study of ion association possible. In this solvent ion association is the rule rather than the exception. Indeed, higher associates such as tetramers are often formed.[18] Triple cations and triple anions have also been characterized in THF solutions.[19]

Ion association is an important factor in phase-transfer catalysis, since a species such as R4P+Cl is formally neutral and so can dissolve easily in a non-polar solvent of low dielectric constant. In this case it also helps that the surface of the cation is hydrophobic.

In SN1 reactions the carbocation intermediate may form an ion pair with an anion, particularly in solvents of low dielectric constant, such as diethylether.[20] This can affect both the kinetic parameters of the reaction and the stereochemistry of the reaction products.

Experimental characterization

Vibrational spectroscopy provides the most widely used means for characterizing ion associates. Both infrared spectroscopy and Raman spectroscopy have been used. Anions containing a CN group, such as cyanide, cyanate and thiocyanide have a vibration frequency a little above 2000 cm−1, which can be easily observed, as the spectra of most solvents (other than nitriles) are weak in this region. The anion vibration frequency is "shifted" on formation of ion pairs and other associates, and the extent of the shift gives information about the nature of the species. Other monovalent anions that have been studied include nitrate, nitrite and azide. Ion pairs of monatomic anions, such as halide ions, cannot be studied by this technique. NMR spectroscopy is not very useful, as association/dissociation reactions tend to be fast on the NMR time scale, giving time-averaged signals of the cation and/or anion.

Nearly the same shift of vibration frequency is observed for solvent-shared ion pairs of LiCN, Be(CN)2 and Al(CN)3 in liquid ammonia. The extent of this type of ion pairing decreases as the size of the cation increases. Thus, solvent-shared ion pairs are characterized by a rather small shift of vibration frequency with respect to the "free" solvated anion, and the value of the shift is not strongly dependent on the nature of the cation. The shift for contact ion pairs is, by contrast, strongly dependent on the nature of the cation and decreases linearly with the ratio of the cations charge to the squared radius:[17]

Cs+ > Rb+ > K+ > Na+ > Li+;
Ba2+ > Sr2+ > Ca2+.

The extent of contact ion pairing can be estimated from the relative intensities of the bands due to the ion pair and free ion. It is greater with the larger cations.[17] This is counter to the trend expected if coulombic energy were the determining factor. Instead, the formation of a contact ion pair is seen to depend more on the energy needed to displace a solvent molecule from the primary solvation sphere of the cation. This energy decreases with the size of the cation, making ion pairing occur to a greater extent with the larger cations. The trend may be different in other solvents.[17]

Higher ion aggregates, sometimes triples M+XM+, sometimes dimers of ion pairs (M+X)2, or even larger species can be identified in the Raman spectra of some liquid-ammonia solutions of Na+ salts by the presence of bands that cannot be attributed to either contact- or solvent-shared ion pairs.[17]

Evidence for the existence of fully solvated ion pairs in solution is mostly indirect, as the spectroscopic properties of such ion pairs are indistinguishable from those of the individual ions. Much of the evidence is based on the interpretation of conductivity measurements.[21][22]

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See also

References

  1. Davies, C. W. (1962). Ion Association. London: Butterworths.
  2. Wright, Margaret Robson (2007). "Chapter 10: concepts and theory of non-ideality". An introduction to aqueous electrolyte solutions. Wiley. ISBN 978-0-470-84293-5.
  3. "Untersuchungen über Ionenassoziation. I. Der Einfluss der Ionenassoziation auf die Aktivität der Ionen bei Mittleren Assoziationsgraden". Cite journal requires |journal= (help)
  4. Burgess, John (1978). Metal Ions in Solution. Chichester: Ellis Horwood. ISBN 978-0-85312-027-8.Chapter 12, Kinetics and Mechanism: Complex formation"
  5. Burgess, Chapter 5, "Solvation numbers"
  6. Fuoss, R. M.; Kraus, C. A. (1935). "Properties of Electrolytic Solutions. XV. Thermodynamic Properties of Very Weak Electrolytes". J. Am. Chem. Soc. 57: 1–4. doi:10.1021/ja01304a001.
  7. Alexandrov, A.; Kostova, S. (1984). "Extraction-spectrophotometric and radiometric investigation of the ternary ion-association complex of niobium(V) with pyrocatechol and triphenyl-tetrazolium chloride". Journal of Radioanalytical and Nuclear Chemistry. 83 (2): 247–255. doi:10.1007/BF02037138.
  8. Fletcher, R. J.; Gans, P.; Gill, J. B.; Geyer, C. (1997). "Spectrochemistry of solutions. part 29. Intrusion ion pairing: identification of a new form of ion pair in transition metal salt solutions in pyridine through their visible spectra". J. Mol. Liquids. 73–74: 99–106. doi:10.1016/S0167-7322(97)00060-3.
  9. Hans Falkenhagen, Theorie der Elektrolyte, S. Hirzel Verlag, Leipzig, 1971.
  10. S. Petrucci, ed. (2012). "III. Foundations of Modern Statistical Theories". Ionic Interactions: From Dilute Solution to Fused Salts. Physical Chemistry: A Series of Monographs. 22. Elsevier. p. 424. ISBN 9780323150927.
  11. Klotz, I. M. (1964). Chemical Thermodynamics. W. A. Benjamin. Chapter 10.
  12. Assuming that both Na+ and Cl have 6 water molecules in the primary solvation shell at ambient temperatures, a 5 M solution (5 mol/L) will consist almost entirely of fully solvated ion pairs.
  13. Manfred Eigen, Nobel lecture.
  14. Clifford, A. A. "Changes of water properties with temperature". Archived from the original on 2008-02-13. Retrieved 2009-05-02.
  15. Gans, P.; Gill, J. B.; Longdon, P. J. (1989). "Spectrochemistry of solutions. Part 21. Inner- and outer-sphere complexes of lithium with thiocyanate in acetonitrile solutions". J. Chem. Soc. Faraday Trans. I. 85 (7): 1835–1839. doi:10.1039/F19898501835.
  16. Gans, P; Gill, J. B.; Holden, K. M. L. (1994). "Spectrochemistry of solutions. Part 27. Formation of [Mg(NCS)]+ in solutions of Mg(NCS)2 in methanol". J. Chem. Soc., Faraday Trans. 90 (16): 2351–2352. doi:10.1039/FT9949002351.
  17. Gill, J. B. (1981). "Solute-solute interactions in liquid ammonia solutions: a vibrational spectroscopic view". Pure Appl. Chem. 53 (7): 1365–1381. doi:10.1351/pac198153071365.
  18. Goralski, P.; Chabanel, M. (1987). "Vibrational study of ionic association in aprotic solvents. 11. Formation and structure of mixed aggregates between lithium halides and lithium thiocyanate". Inorg. Chem. 26 (13): 2169–2171. doi:10.1021/ic00260a032.
  19. Bacelon, P.; Corset, J.; de Loze , C. (2004). "Triple ion formation in solutions of alkaline sulfocyanides". J. Solution Chem. 9 (2): 129–139. doi:10.1007/BF00644484. (sulfocyanides = thiocyanates).
  20. Winstein, S.; Clippinger, E.; Fainberg, A. H.; Heck, R.; Robinson G. C. (1956). "Salt Effects and Ion Pairs in Solvolysis and Related Reactions. III.1 Common Ion Rate Depression and Exchange of Anions during Acetolysis". Journal of the American Chemical Society. 78 (2): 328–335. doi:10.1021/ja01583a022.
  21. Raymond M. Fuoss (1957). "Ionic Association. I. Derivation of Constants from Conductance Data". J. Am. Chem. Soc. 79 (13): 3301–3303. doi:10.1021/ja01570a001.CS1 maint: uses authors parameter (link)
  22. Miyoshi, K. (1973). "Comparison of the Conductance Equations of Fuoss–Onsager, Fuoss–Hsia and Pitts with the Data of Bis(2,9-dimethyl-1,10-phenanthroline)Cu(I) Perchlorate". Bull. Chem. Soc. Jpn. 46 (2): 426–430. doi:10.1246/bcsj.46.426.
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