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0905 Dissolution of ionic salts in water

1/28/2019

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The process - a competition
​
"Dissolution" is the noun for the process of dissolving.

Just what is this phenomenon of an ionic salt dissolving in water? Let's chat ....

[In the animations in this video (sodium chloride as crystalline solid, melting, and dissolving in water), the sodium ions are represented by the smaller grey spheres, and chloride ions by the larger green spheres.]
Animations included with permission:  © VisChem (VisChem.com.au)

KEY IDEAS
​

The accepted model of a solid ionic salt is a solid in which there is a lattice network of cations and anions distributed among each other in an orderly way.

A representation of the lattice structure of sodium chloride (NaCl), for example, deduced from x-ray cystallography, has six negatively charged chloride ions as immediate neighbours around each sodium ion, and six positively charged sodium ions around each chloride ion.
​
Picture






​A representation of the structure of part of a sodium chloride crystal. The smaller spheres represent sodium ions, and the larger spheres chloride ions.



​From R.B. Bucat (Ed.) Elements of Chemistry: Earth Air Fire and Water, Australian Academy of Science, 1984.


Because of this interlocking structure over the whole of a crystal, the ions are tightly bound. This is evidenced not only by its state as a solid (the ions are locked in place), but the high melting point of 801 °C.

This then begs the question of why the ions separate when the solid is shaken in water, and the solid quickly dissolves.

This phenomenon is attributed to the evidence that water molecules are dipoles: they behave like a rod with a positive electrostatic charge at one end (on the side of the hydrogen atoms) and a negative charge at the other end (on the oxygen atom).

In conjunction with the ability of water molecules to freely rotate, we can imagine that water molecules are attracted to the ions on the surface of the crystal – with negative ends of the dipole pointing toward the sodium ions, and positive ends toward the chloride ions.
​
These water molecules are also attracted back into the bulk of the water (by dipole-dipole attractions to other water molecules around them).

The result is a competition for the ions on the crystal surface – between inner ions pulling them back into the crystal, and water molecules trying to drag them away from the crystal and into the aqueous phase.

The experimental fact that sodium chloride is soluble in water tells us that the water molecules win the tug-of-war.

The species in the solution are (i) sodium ions surrounded by water molecules, and said to be aquated, or hydrated, and (ii) aquated (or hydrated) chloride ions. – and there is no identifiable species that we call sodium chloride.

Picture
Picture
Schematic representations of an Na+(aq) ion, and a Cl-(aq) ion. Note the different orientations of the water molecules toward the positive ion and the negative ion.
From R.B. Bucat (Ed.) Elements of Chemistry: Earth Air Fire and Water, Australian Academy of Science, 1984

This process is represented by the chemical equation:
Picture

We would draw similar conclusions for other soluble salts such as potassium nitrate and magnesium sulfate.
​
In the case of insoluble ionic salts (like silver chloride, barium sulfate, and calcium carbonate) we can conclude that the inner crystal ions win the competition against the polar water molecules.

Video portrayal
A concise video portrayal, at the molecular level, of the dissolution of sodium chloride in water has been produced by VisChem (VisChem.com.au) and is published here, with kind permission ....
Published with permission:  © VisChem (VisChem.com.au)
External reference
For the best textbook discussion of this subject, you might like to go to …….
​Mahaffy, P.G., Bucat, B., Tasker, R., and others. “CHEMISTRY: Human Activity, Chemical Reactivity” (Nelson Education), pages 178-182 (both International and Canadian editions).


SELF CHECK
Assess whether the following statements are correct or incorrect.
  1. Sodium ions are grey, and chloride ions are green.
  2. Chloride ions are bigger than sodium ions.
  3. In a sodium chloride crystal, each chloride ion has six other chloride ions as immediate neighbours.
  4. In water, the water molecules are free to rotate in any direction, depending upon nearby forces of attraction (or repulsion).
  5. When a crystal of sodium chloride is placed in water, sodium ions at the surface are attracted toward water molecules with their oxygen atoms directed toward the sodium ions.
  6. Potassium nitrate is soluble in water. If solid potassium nitrate is placed in water and shaken up, the attraction from water molecules to potassium ions and nitrate ions on the surface “wins” the competition against attraction from ions within the crystal.
  7. If a crystal of calcium carbonate is placed in water and shaken up, the attraction of water molecules to calcium ions and carbonate ions on the surface “wins” the competition against attraction from ions within the crystal.
  8. The symbolism (aq) means aqueous.
  9. In a solution made by dissolving solid potassium sulfate (K2SO4) in water, potassium sulfate molecules are surrounded by water molecules.
  10. The following three statements are eqauivalent: (i) Water molecules are attracted to sodium ions, (ii) Sodium ions are attracted to water molecules, and (iii) Water molecules and sodium ions are attracted to each other.
  11. If 5 g of solid sodium nitrate is shaken up in 100 mL of water until it all dissolves, there is no species that we call sodium nitrate in the solution.
  12. The term “aquated nitrate ions” (or “hydrated nitrate ions”) refers to nitrate ions surrounded by a “shell” of water molecules with their oxygen atoms directed toward the nitrate ions.
  13. In a solution of magnesium sulfate in water, the only species present (apart from water molecules) are aquated magnesium ions and aquated sulfate ions.
  14. If solid crystalline calcium carbonate is shaken in water, calcium ions and carbonate ions on the surface of the crystal are attracted by both (i) other ions of opposite charge within the crystal, and (ii) water molecules. The ions within the crystal “win” the competition. So calcium carbonate is soluble in water.
     



Answers


  1. Incorrect. Colour is a property of substances, not of individual atoms or ions. The colours of the spheres that represent ions in the animation are chosen randomly so that we can distinguish them.
  2. Correct, as is the case for most anions (negatively charged ions) compared with cations. This is partly due to the fact that anions have more electrons than the parent atoms, while cations have less electrons than their parent atoms.
  3. Incorrect.
  4. Correct.
  5. Correct.
  6. Correct.
  7. Incorrect. Calcium carbonate is essentially insoluble in water.
  8. Incorrect. The symbol (aq) means aquated (or hydrated): that is, to be surrounded by a “shell” of strongly attracted water molecules. The terms aqueous means that the solvent is water. For example, a solution of sodium chloride in water is an aqueous solution. And the species present are aquated sodium ions and aquated chloride ions.
  9. Incorrect.
  10. Correct.
  11. Correct.
  12. Incorrect.
  13. Correct.
  14. Incorrect.
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  • Home
  • Modules
    • 02 The nature of matter >
      • 0201 Atoms: Building blocks
      • 0202 Classification of matter
    • 05 Chemical reaction, chemical equations >
      • 0500 Overview, preview
      • 0501 Amount of substance, mole
      • 0502 Avogadro constant: How many?
      • 0503 Avogadro constant: Why that number?
      • 0504 Chemical formulas: What do they mean?
      • 0505 What can equations tell us?
      • 0506 Limiting reactants
    • 09 Solutions >
      • 0901 What is a solution?
      • 0902 Miscibility of liquids
      • 0903 Like dissolves like?
      • 0905 Dissolution of ionic salts in water
      • 0906 Can we predict solubilities of salts?
      • 0907 Solution concentration
      • 0908 Chemical species, speciation
      • 0909 Solutes: Electrolytes or non-electrolytes?
      • 0910 Electrolytes - strong or weak?
      • 0911 Concentrated, dilute, strong, weak
      • 0912 Species concentration vs. solution concentration
      • 0913 Weak electrolytes: Getting quantitative
    • 11 Dynamic chemical equilibrium >
      • 1100 Equilibrium: An overview
      • 1101 Visualising dynamic equilibrium
      • 1102 The jargon of equilibrium
      • 1103 Equilibrium constants
    • 22 Evidence from spectroscopy >
      • 2200 Overview, preview
      • 2201 Spectroscopy: Quantization of energies
      • 2202 Light: Wave-particle "duality"
      • 2203 UV-Visible spectroscopy
      • 2204 Beer's law
    • 27 Communicating chemistry >
      • 2700 Overview, preview
      • 2703 The jargon we use
  • TOC
  • Index
  • Teachers' area
    • T01 Communicating chemistry
    • T02 Beer's law
    • T03 Professional amnesia of the chemistry teaching professio
    • T04 Law of equilibrium
    • T05 Visusalizing dynamic chemical equilibrium
  • Aha! Whatever
    • Playful dolphins
    • The University of Western Australia
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  • Prof Bob?
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  • In four days for two days