Experimental Study of Electrical Energy Generation Using a Simple Aluminum-Carbon Electrochemical Cell in Saline Solution
Authors
Laboratoire de Procédés et d’innovations Technologiques (LaPIT) /Université Nationale des Sciences, Technologies, Ingénierie et Mathématiques d’Abomey (UNSTIM) (Benin)
Laboratoire de Procédés et d’innovations Technologiques (LaPIT) /Université Nationale des Sciences, Technologies, Ingénierie et Mathématiques d’Abomey (UNSTIM) (Benin)
Laboratoire de Procédés et d’innovations Technologiques (LaPIT) /Université Nationale des Sciences, Technologies, Ingénierie et Mathématiques d’Abomey (UNSTIM) (Benin)
Laboratoire de Procédés et d’innovations Technologiques (LaPIT) /Université Nationale des Sciences, Technologies, Ingénierie et Mathématiques d’Abomey (UNSTIM) (Benin)
Article Information
DOI: 10.47772/IJRISS.2026.1026EDU0047
Subject Category: Science
Volume/Issue: 10/26 | Page No: 594-600
Publication Timeline
Submitted: 2026-01-20
Accepted: 2026-01-26
Published: 2026-01-31
Abstract
This study investigates the feasibility of electrical energy generation using a low-cost aluminum–carbon electrochemical cell operating in a saline electrolyte. The experimental setup consisted of aluminum foil as an anode, a carbon rod as a cathode, and a NaCl aqueous solution. Electrical performance was monitored over a three-week period through voltage and current measurements. The system produced an initial open-circuit voltage of up to 20 V and was capable of powering a low-power load. However, the output current remained limited (0.015–0.033 A), significantly restricting practical applications. Strong voltage fluctuations were observed, particularly during morning measurements, with a minimum voltage of 5.8 V, attributed to electrode degradation and electrolyte depletion. Despite these limitations, the system demonstrates potential for educational purposes and low-power backup applications. The integration of a battery storage system improved supply continuity. The study highlights both the feasibility and intrinsic limitations of rudimentary aluminum-based electrochemical energy systems.
Keywords
Electrochemistry; Aluminum-based cells; Saline electrolyte; Low-cost energy systems; Voltage instability
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