5 Must Know Facts For Your Next Test

1. Dissociation occurs when an ionic compound is placed in water, causing the positive and negative ions to separate due to the attraction of water molecules to each ion.
2. The extent of dissociation is influenced by factors like temperature and the concentration of the ionic solution.
3. Strong electrolytes fully dissociate into ions in solution, while weak electrolytes only partially dissociate.
4. The ability of a solution to conduct electricity is directly related to the degree of dissociation of its ionic components.
5. In contrast to ionic compounds, covalent compounds typically do not dissociate into ions when dissolved; they remain as neutral molecules.

Review Questions

• How does the process of dissociation differ between ionic and covalent compounds when dissolved in a solvent?
  • Dissociation primarily occurs in ionic compounds, where they separate into their constituent ions upon dissolving in a solvent like water. The strong electrostatic forces holding the ionic lattice together are disrupted by interactions with solvent molecules, resulting in free-moving ions. In contrast, covalent compounds usually do not dissociate; they remain intact as neutral molecules rather than forming ions.
• Evaluate how the degree of dissociation affects the electrical conductivity of a solution.
  • The degree of dissociation significantly impacts a solution's electrical conductivity. Strong electrolytes completely dissociate into ions, allowing for high conductivity as there are many charged particles available to carry electric current. Conversely, weak electrolytes only partially dissociate, resulting in fewer free ions and thus lower conductivity. This relationship highlights the importance of understanding dissociation when studying solutions.
• Assess the implications of dissociation on biological systems and processes within living organisms.
  • Dissociation plays a critical role in biological systems as many essential processes depend on ion concentrations and movements. For instance, the dissociation of electrolytes like sodium chloride (NaCl) in body fluids is vital for nerve impulse transmission and muscle contraction. Furthermore, pH regulation in biological systems relies on the dissociation of acids and bases. Understanding how dissociation influences these processes helps explain how organisms maintain homeostasis and respond to changes in their environment.

© 2024 Fiveable Inc. All rights reserved.

AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.