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Electrolysis03:00

Electrolysis

31.8K
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...
31.8K
The Electrical Double Layer01:30

The Electrical Double Layer

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In the region where two bulk phases meet, an intricate electric charge distribution arises due to charge transfer, ion adsorption, molecular orientation, and charge distortion. This complex distribution is commonly referred to as the electrical double layer.When a solid electrode interfaces with ions in an electrolyte solution, the speed of electron transfer dictates the rates of oxidation and reduction. The electrode acquires a charge through the escape of atoms into the solution as cations or...
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Electrochemical Systems01:24

Electrochemical Systems

130
Electrochemical systems provide a fascinating insight into the dynamic interplay of charged species within various phases. One notable example is the interaction between a membrane permeable to K⁺ ions but not to Cl⁻ ions, separating an aqueous KCl solution from pure water. As K⁺ ions diffuse through the membrane, they generate net charges on each phase, leading to a potential difference between them.Similarly, when a piece of Zn is immersed in an aqueous ZnSO₄ solution,...
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Electrochemical Cells01:28

Electrochemical Cells

267
Electrochemical cells are systems that convert chemical energy into electrical energy or use electrical energy to drive chemical reactions. They consist of two electrodes in contact with an electrolyte, where redox reactions enable electron transfer. Most electrochemical cells include two half-cells connected by an external wire for electron flow and a salt bridge for ion flow. The salt bridge contains an electrolyte solution and maintains charge neutrality by allowing ions—not...
267
Processes at Electrodes01:30

Processes at Electrodes

80
The electrode interacts with ions in the electrolyte solution at its interface. The rate of oxidation and reduction depends on the speed at which electrons can transfer through this interface. As ions attach to or leave the electrode surface, the electrode acquires a charge, and an electrical potential forms across the interface, making the process more difficult to reach equilibrium. The charge on the electrode affects the local ion concentrations in the solution, though thermal motion...
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Related Experiment Video

Updated: Apr 6, 2026

Development and Validation of Chromium Getters for Solid Oxide Fuel Cell Power Systems
12:30

Development and Validation of Chromium Getters for Solid Oxide Fuel Cell Power Systems

Published on: May 26, 2019

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A techno-economic model of a solid oxide electrolysis system.

Daniel G Milobar1, Joseph J Hartvigsen2, S Elangovan3

  • 1Tucson, AZ, USA. dmilobar@lasertel.com.

Faraday Discussions
|July 30, 2015
PubMed
Summary

Solid oxide electrolysis cells (SOECs) offer efficient hydrogen production. This study presents a model to generate performance maps, enabling optimized selection of operating conditions for commercial applications.

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Probing and Mapping Electrode Surfaces in Solid Oxide Fuel Cells
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Probing and Mapping Electrode Surfaces in Solid Oxide Fuel Cells

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Area of Science:

  • Electrochemistry
  • Energy Conversion and Storage

Background:

  • Solid oxide cells (SOECs) are crucial for energy and environmental solutions.
  • SOECs can produce electricity from hydrocarbons (fuel cell mode) or hydrogen/synthesis gas from steam/CO2 (electrolysis mode).
  • Selecting optimal operating conditions is vital for the commercial success of SOECs.

Purpose of the Study:

  • To develop a model for generating performance maps of solid oxide electrolysis cell stacks.
  • To provide a method for selecting SOEC operating conditions based on power, efficiency, or cost.

Main Methods:

  • Applied fundamental electrochemical principles to a SOEC system.
  • Utilized closed-form isothermal parametric models, previously demonstrated for SOFCs, to a SOEC stack.
  • Generated performance maps for SOEC stacks operated in electrolysis mode.

Main Results:

  • The model successfully generated performance maps for SOEC stacks.
  • The functional form of the model and operating envelope boundaries offer insights into SOEC characteristics.
  • Operating conditions can be selected prioritizing power output, efficiency, or electricity cost.

Conclusions:

  • The developed model provides a straightforward approach to selecting optimal operating conditions for SOEC operation.
  • Performance maps are essential tools for understanding and optimizing SOEC performance.
  • This work facilitates the commercial application of SOECs for efficient energy conversion.