Voltaic cell | How does it work?

Sabins

9 Dec 202104:10

Summary

TLDRThis educational video explores the fundamental workings of a galvanic or voltaic cell, demonstrating how zinc atoms and copper ions interact to generate electric current. It explains how zinc atoms lose electrons and copper ions accept them, with the help of a salt bridge to maintain continuous electron flow. As the zinc bar erodes and the copper plate thickens, the process continues, providing a sustainable electrical current. The video also highlights the role of the salt bridge in neutralizing charge build-up, ensuring that the cell operates efficiently until depletion.

Takeaways

😀 The galvanic or voltaic cell is a fundamental and easy-to-understand concept in electricity generation.
😀 Zinc atoms lose two electrons to achieve stability, while copper ions gain electrons to become stable.
😀 The flow of two electrons through a conducting cable between zinc and copper generates electricity.
😀 A sustainable flow of current can be achieved by producing more zinc atoms and copper ions.
😀 Copper sulfate solution contains copper ions, and a zinc metal bar contains zinc atoms for the reaction.
😀 Zinc atoms donate electrons, transforming into zinc ions, which need to be accommodated in another solution.
😀 The flow of electrons through the circuit generates electricity, while copper ions in the solution become copper atoms.
😀 A buildup of positive and negative charges can impede electron flow, blocking the current.
😀 A salt bridge, containing Na+ and Cl- ions, helps neutralize accumulated charges, ensuring continuous electron flow.
😀 The salt bridge neutralizes charges on both sides of the galvanic cell, making the voltage and electricity production sustainable.
😀 Over time, the zinc metal bar erodes as zinc ions are lost, while the copper plate gains mass as copper atoms are deposited.

Q & A

What is the basic principle of a galvanic or voltaic cell?
-A galvanic or voltaic cell generates voltage and current by using two materials, zinc and copper, where zinc loses electrons and copper ions accept them. This flow of electrons creates electricity.
Why does the zinc atom want to lose electrons?
-The zinc atom wants to lose two electrons in order to achieve stability. By losing these electrons, the zinc becomes a positively charged ion, which is a more stable state.
What role do copper ions play in this process?
-Copper ions in the solution are 'starving' for electrons. They accept the electrons from the zinc atoms, transforming into copper metal in the process.
How do electrons flow in the circuit?
-Electrons flow from the zinc metal bar, through the external circuit, and to the copper ions in the solution, where the copper ions receive the electrons and become copper metal.
Why is the salt bridge necessary in the voltaic cell?
-The salt bridge is necessary to neutralize the build-up of charges on both sides of the cell. It allows ions to flow between the two chambers, preventing the charge imbalance that would stop electron flow.
What is the composition of the salt bridge?
-The salt bridge is an aqueous solution containing sodium ions (Na+) and chloride ions (Cl-) and is enclosed in cotton material to facilitate ion flow.
What happens to the zinc metal bar during the process?
-The zinc metal bar erodes over time as it loses zinc ions into the solution. This causes the bar to become thinner.
What happens to the copper plate during the process?
-The copper plate becomes thicker as copper ions in the solution accept electrons and deposit as solid copper on the plate.
What causes the flow of current in the voltaic cell?
-The flow of current is driven by the transfer of electrons from the zinc bar to the copper ions in the solution, facilitated by the conducting wire and the salt bridge.
What eventually causes the voltaic cell to stop operating?
-The voltaic cell will stop functioning when the zinc bar is completely depleted or when the ions in the salt bridge are exhausted, disrupting the ion flow and electron transfer.