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Electrolysis03:00

Electrolysis

28.9K
In a galvanic cell, the electrical work is done by a redox system on its surroundings as electrons produced by the spontaneous redox reactions are transferred through an external circuit. Alternatively, an external circuit does work on a redox system by imposing a voltage sufficient to drive an otherwise nonspontaneous reaction in a process known as electrolysis. For instance, recharging a battery involves the use of an external power source to drive the spontaneous (discharge) cell reaction in...
28.9K
Potentiometry: Types of Electrodes01:19

Potentiometry: Types of Electrodes

1.4K
Reference electrodes serve as a stable reference point for potentiometric measurements, while indicator and working electrodes react to variations in the composition of a solution.
The Standard Hydrogen Electrode (SHE) is a widely used reference electrode that maintains zero potential across all temperatures. However, its need for a continuous hydrogen gas supply renders it impractical for everyday use.
An alternative to SHE is the Saturated Calomel Electrode (SCE). This electrode features an...
1.4K
Voltammetry: Factors Affecting Measurements01:21

Voltammetry: Factors Affecting Measurements

390
A current produced due to the redox reactions of the analyte at the working and auxiliary electrodes is called a faradaic current. The reaction can be divided into two types. The current generated due to the reduction of the analyte is called cathodic current, and it carries a positive charge. In contrast, the current produced by analyte oxidation is known as an anodic current, and it has a negative charge. The applied potential at the working electrode determines the faradaic current flow, and...
390
Potentiometry: Membrane Electrodes01:15

Potentiometry: Membrane Electrodes

1.2K
Membrane electrodes, also known as p-ion electrodes, use membranes that selectively interact with free analyte ions, generating a potential difference across the membrane. The resulting membrane potential, known as the asymmetry potential, is not zero even when analyte concentrations on both sides of the membrane are equal. The membrane's response is typically not selective to a single analyte but proportional to the concentration of all ions in the sample solution capable of interacting at...
1.2K
Standard Electrode Potentials03:02

Standard Electrode Potentials

47.6K
On comparing the reactivity of silver and lead, it is observed that the two ionic species, Ag+ (aq) and Pb2+ (aq), show a difference in their redox reactivity towards copper: the silver ion undergoes spontaneous reduction, while the lead ion does not. This relative redox activity can be easily quantified in electrochemical cells by a property called cell potential. This property is commonly known as cell voltage in electrochemistry, and it is a measure of the energy which accompanies the charge...
47.6K
Electrogravimetric Analysis: Overview01:30

Electrogravimetric Analysis: Overview

533
Electrogravimetric analysis measures the weight of an analyte deposited electrolytically onto a suitable working electrode. This method involves applying a potential to a pre-weighed electrode submerged in a solution, which results in the desired substance being deposited through reduction at the cathode or oxidation at the anode. The electrode's weight is recorded after deposition, and the difference in weight gives the analyte's weight in the solution.
To test the completeness of the...
533

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Updated: Nov 16, 2025

Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions
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Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions

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Effect of electrolyte flow on a gas evolution electrode.

Soufiane Abdelghani-Idrissi1, Nicolas Dubouis2,3,4, Alexis Grimaud2,3,4

  • 1ESPCI Paris, PSL Research University, MIE-CBI, CNRS UMR 8231, 10, Rue Vauquelin, 75231, Paris Cedex 05, France.

Scientific Reports
|February 26, 2021
PubMed
Summary

Flowing electrolytes in zinc-air batteries can improve energy gain. Proper hydrodynamic design is crucial for profitability, balancing energy gains against viscous losses for efficient operation.

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Area of Science:

  • Electrochemistry
  • Fluid Dynamics
  • Energy Systems

Background:

  • Electrolysis and zinc-air batteries are key energy conversion technologies.
  • Electrolyte flow dynamics significantly impact cell performance and energy efficiency.
  • Understanding energy gains versus viscous losses is critical for optimizing these systems.

Purpose of the Study:

  • To investigate the impact of electrolyte flow on electrolysis and zinc-air cells.
  • To analyze the energy gains achieved through flow and compare them with viscous losses.
  • To evaluate the economic viability and optimal design parameters for flowing electrolyte systems.

Main Methods:

  • Investigated the effects of electrolyte flow on cell energy balance.
  • Compared electrical power gains with viscous power losses.
  • Developed an analytical model to simulate process dynamics and identify optimal conditions.

Main Results:

  • Positive energy balance is achievable with optimized hydrodynamic resistance.
  • The study identified optimal flowing conditions for energetic profitability.
  • Economical viability is contingent upon correct circuit design and flow parameters.

Conclusions:

  • Flowing electrolytes in zinc-air batteries can be energetically profitable.
  • Appropriate flowing conditions and hydrodynamic design are essential for maximizing energy efficiency.
  • The developed analytical model provides a framework for understanding and optimizing these systems.