Introduction to Weak Electrolytes
A substance produces an electrically conducting solution when it is dissolved in polar solvents such as water. These types of substances are called electrolytes. The dissolved substance can be separated in the form of cations and anions that are dispersed in the solvent uniformly. This solution is in the neutral condition, electrically.
When we apply electric potential to such types of solutions, the cations present in the solution get attracted to or drawn towards the electrode that has an abundance of electrons, and in the case of anions, these are directed or attracted towards the electrode that lacks or is deficient in electrons. This opposite movement of the cations and anions results in the production of electric current. Some examples of electrolytes are soluble salts, bases, and acids. In some conditions, gases such as HCl or hydrogen chloride can also act as electrolytes; such conditions include low pressure or high temperature.
Types of Electrolytes
Polyelectrolytes are formed with the help of the dissolution of some of the synthetic polymers and biological polymers that contain charged functional groups. A substance has the capability to conduct electricity when it is dissociated into ions in the solution. The classification of strong and weak electrolytes is given below.
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There are two types of electrolytes:
Strong Electrolytes: If an electrolyte is completely dissociated into the solution, then such types of electrolytes are known as Strong electrolytes.
Weak Electrolytes: If an electrolyte is not completely dissociated into the solution, then such types of electrolytes are known as weak electrolytes.
In the case of weak electrolytes, only a small fraction of the ions are present in a dissolved solute. Let us learn more about them.
What Are Strong Electrolytes and Weak Electrolytes?
The solid crystalline salts start dissociating into the paired charged particles when dissolved in a solvent. This was observed by a scientist named Svante Arrhenius in the year 1884. For this invention, he received the Nobel Prize in the year 1903. The salts that dissociate in the solvent as charged particles were named by Micheal Faraday as “ions”. According to Faraday, ions are produced by the process of electrolysis. But Arrhenius found that even in the absence of an electric current, salts contain ions and hence chemical reactions occur as a result of reactions in between the ions.
Weak electrolytes do not completely dissociate into the solvent, whereas strong electrolytes can dissolve in the aqueous solution. The solution contains both molecules and the ions that are present in the electrolyte. Weak electrolytes ionise partially in water but strong electrolytes ionise completely. Weak bases and weak acids are considered weak electrolytes. Strong bases, strong acids, and salts are considered strong electrolytes. Salt is considered a strong electrolyte even though it has low solubility in the water because whatever the amount it dissolves in the water is completely ionised.
Weak electrolyte examples: Acetic acid (CH3COOH): Acetic acid is the acid that is found in vinegar. It is an electrolyte that is extremely soluble in the water. But when it is dissolved in the water, most of its original molecule remains as it is, instead of being in the ion form. This original form is known as ethanoate. The acetic acid is dissolved in the water and ionises as ethanoate and the hydronium ion. Thus, this makes acetic acid a weak electrolyte.
CH3COOH + H2O ⇔ CH3COO -+ H3O +
Carbonic acid (CH2O3), Ammonia (NH3), and Phosphoric acid (H3PO4) act as weak electrolytes.
Strong electrolytes examples: Hydrochloric acid (HCl), Sulfuric acid (H2SO4), sodium hydroxide (NaOH), and potassium hydroxide (KOH).
Difference Between Strong Electrolyte and Weak Electrolyte
Importance
The physiological importance and rehydration of weak electrolytes are as follows:
Physiological Importance:
The primary ions that are present in the electrolyte are sodium (Na+), chloride (Cl-), magnesium(Mg 2+), hydrogen carbonate (HCO3- ), hydrogen phosphate (HPO42- ), calcium(Ca2+), and potassium (K+). These electric charge symbols represent that the substance is of ionic nature and has an imbalanced distribution of electrons. Sodium and potassium are required to maintain fluid balance and blood pressure control.
The complex and subtle electrolyte balance between the intracellular and extracellular environment is required for all multicellular organisms. That is in particular maintaining the precise osmotic gradient of the electrolyte is important. These types of gradients regulate the hydration of the body and maintain the pH of the blood, nerve and muscle functions.
The electrolyte activity between the intracellular fluid and extracellular fluid or interstitial fluid is required to maintain the activity of the muscles and neurons. The specialised protein structures that are present in the plasma membrane of the cell are known as ion channels. Through these channels, the electrolytes enter and leave the cell.
Rehydration:
The electrolyte drinks that contain potassium and sodium salts are used in oral rehydration therapy. These salts help to replenish the concentration of electrolytes in the body that are dehydrated due to excessive consumption of alcohol, exercise, vomiting, starvation, or heavy sweating. Athletes who are found exercising in extreme conditions for more than two hours continuously have the risk of dehydration. Thus the oral consumption of electrolytes is required. The electrolyte drink can be prepared at home by using sugar, salt, and water in definite proportions.
Conclusion
Electrolytes are found commonly in fruit juices, milk, nuts, vegetables and many fruits. It is found in two forms: strong and weak electrolytes. These can be strong bases and acids or weak bases and acids. Electrolytes can be measured by performing diagnostic procedures, where blood is tested with the ion-selective electrodes. The most often measured electrolytes are potassium and sodium.
FAQs on Weak Electrolytes
1. What is the fundamental difference between a weak electrolyte and a strong electrolyte?
The fundamental difference lies in their degree of dissociation in a solvent. A strong electrolyte, like hydrochloric acid (HCl), dissociates almost completely into its constituent ions. In contrast, a weak electrolyte, such as acetic acid (CH₃COOH), only partially dissociates, meaning the solution contains a mixture of ions and undissociated molecules in a state of equilibrium.
2. What are the key characteristics of a solution containing a weak electrolyte?
A solution of a weak electrolyte has several distinct characteristics:
- Poor Electrical Conductivity: Due to the low concentration of free-moving ions, the solution is a poor conductor of electricity compared to a solution of a strong electrolyte.
- Chemical Equilibrium: The ions and the undissociated molecules exist in a dynamic equilibrium, which is represented by a reversible reaction arrow (⇔).
- Presence of Molecules and Ions: The majority of the solute remains in its original molecular form, with only a small fraction existing as ions.
3. Could you provide some common examples of weak electrolytes?
Weak electrolytes are typically weak acids and weak bases. Common examples include:
- Acetic Acid (CH₃COOH): The main component of vinegar.
- Carbonic Acid (H₂CO₃): Found in carbonated drinks and essential for blood pH regulation.
- Ammonia (NH₃): A common weak base used in cleaning products.
- Phosphoric Acid (H₃PO₄): Used in some soft drinks and fertilisers.
- Hydrofluoric Acid (HF): A weak acid despite the high electronegativity of fluorine.
4. How is the partial dissociation of a weak electrolyte represented in a chemical equation?
The partial dissociation of a weak electrolyte is represented using a reversible arrow (⇔) to show that the reaction reaches a state of equilibrium. For a generic weak acid (HA), the equation is:
HA (aq) + H₂O (l) ⇔ H₃O⁺ (aq) + A⁻ (aq)
This indicates that the forward reaction (dissociation) and the reverse reaction (association) occur simultaneously, with the undissociated form (HA) being predominant.
5. Why do weak electrolytes only dissociate partially in water?
Weak electrolytes only dissociate partially because the covalent bonds within their molecules are strong relative to the energy released during solvation (hydration). The energy provided by the interaction with water molecules is insufficient to break all the bonds. As a result, an equilibrium is established where the rate of dissociation into ions is equal to the rate of ions recombining to form molecules, leaving most of the substance undissociated.
6. How does the concept of chemical equilibrium apply to weak electrolytes?
Chemical equilibrium is central to understanding weak electrolytes. The partial dissociation establishes a dynamic equilibrium where the concentrations of the reactants (undissociated molecules) and products (ions) remain constant. This equilibrium is quantified by an equilibrium constant—either the acid dissociation constant (Ka) for weak acids or the base dissociation constant (Kb) for weak bases. A smaller Ka or Kb value signifies a weaker electrolyte.
7. What is the physiological importance of weak electrolytes in the human body?
Weak electrolytes are vital for maintaining homeostasis. The most critical example is the carbonic acid-bicarbonate buffer system (H₂CO₃ / HCO₃⁻) in the blood. This weak acid and its conjugate base work together to resist drastic changes in blood pH, absorbing excess acid or base to keep the pH within a narrow, life-sustaining range (around 7.4).
8. Why is phosphoric acid (H₃PO₄) considered a weak electrolyte despite having three hydrogen atoms?
Phosphoric acid (H₃PO₄) is a polyprotic acid, meaning it donates its protons in successive steps. While the first dissociation is significant, the subsequent dissociations are progressively weaker. Because it does not dissociate completely into 3H⁺ and PO₄³⁻ ions in a single step, and the overall concentration of ions remains relatively low, it is classified as a weak electrolyte.
