ABSTRACT
Solar cells, also called photovoltaic or PV cells, change sunlight directly to electricity. When sunlight strikes the solar cell, electrons are knocked loose. They move toward the treated front surface.
Solar cells generate an electrical current when light hits their surface. White light that we see from the Sun includes all colors of the visible spectrum and ranges in wavelength from about 400 nanometers (nm) to about 780 nm. Solar cells vary in their response to different wavelengths, or color, of light.
The objective of this work is to demonstrate how a solar cell responds differently to different wavelengths of light. You will develop this idea by covering the solar cell with color light filters and observing any changes in solar cell amperage output.
CHAPTER ONE
1.0 INTRODUCTION
Photovoltaic materials have become a vital source of research and renewable energy in recent years as demand for energy increases. Photovoltaic material may provide the solution to needs for energy as it may provide substantial amounts of renewable energy. Photovoltaic materials were first discovered by a French physicist Edmond Becquerel around 1839, who was able to use sunlight to produce an electric current in a solid material. Scientists began to truly understand this process in more than another century when they discovered that the photovoltaic effect caused certain materials to convert light energy into electrical energy at the atomic level. Now, simple photovoltaic systems provide power in every day devices such as calculators and wristwatches.
One of the main factors that affect the efficiency of PV cells is the wavelength of light. Light is composed of photons which range in wavelength. As the light hits the surface of the PV cell, certain photons are reflected as opposed to being absorbed.
Traditional photovoltaic cells turn a relatively small part of the sun’s light spectrum into electricity, limiting their efficiency and power output. The cell’s silicon material responds to a limited range of light wavelengths, ignoring those that are longer and shorter. As the wavelength varies from short to long, the cell’s output rises and falls in a jagged curve. Newer photovoltaic cell designs achieve higher efficiency by converting more wavelengths into useful energy.
1.1 AIM AND OBJECTIVE OF THE STUDY
The objective is:
- to develop a more efficient method of using light for solar energy, that is, to determine the effect of light wavelength on the electrical output of photovoltaic cells with the goal of improving the efficiency of solar panels.
- To demonstrate how a solar cells responds differently to different wavelengths of light. You will develop this idea by covering the solar cell with color light filters and observing any changes in solar cell amperage output.
1.2 SIGNIFICANCE OF THE STUDY
Solar cells, also called photovoltaic or PV cells, change sunlight directly to electricity. When sunlight strikes the solar cell, electrons are knocked loose. They move toward the treated front surface. An electron imbalance is created between the front and back. When the two surfaces are joined a current of electricity travels between the negative and positive sides.
This study seeks to determine if exposure to specific light wavelength can improve the efficiency of photovoltaic cells.
1.3 SCOPE OF THE PROJECT
The use of solar power as part of a portfolio of renewable energy technologies is a promising response to the world’s pressing energy challenges. In this work, the effect of the color of light and load resistance on a solar PV panel and the wavelength of light received by the panel, as well as the electrical load present on the system were determined. The voltage and current across the power load were measured in addition to the wavelength of the colors.
1.4 DEFINITION OF SOME TERMINOLOGIES USED IN THE STUDY
PHOTOVOLTAIC CELL (SOLAR PANEL): A photovoltaic cell (PV cell) is a specialized semiconductor diode that converts visible light into direct current (DC). Some PV cells can also convert infrared (IR) or ultraviolet (UV) radiation into DC electricity.
WAVELENGTH: Wavelength is the distance between identical points in the adjacent cycles of a waveform signal propogated in space or along a wire
PHOTOELECTRIC EFFECT: The photoelectric effect is the basic physical process by which a PV cell converts sunlight into electricity. When light shines on a PV cell, it may be reflected, absorbed, or pass right through. But only the absorbed light generates electricity.
Effects Of Amount And Wavelength Of Light On A Solar Cell. (n.d.). UniTopics. https://www.unitopics.com/project/material/effects-of-amount-and-wavelength-of-light-on-a-solar-cell/
“Effects Of Amount And Wavelength Of Light On A Solar Cell.” UniTopics, https://www.unitopics.com/project/material/effects-of-amount-and-wavelength-of-light-on-a-solar-cell/. Accessed 22 November 2024.
“Effects Of Amount And Wavelength Of Light On A Solar Cell.” UniTopics, Accessed November 22, 2024. https://www.unitopics.com/project/material/effects-of-amount-and-wavelength-of-light-on-a-solar-cell/
Here’s a typical structure for Effects Of Amount And Wavelength Of Light On A Solar Cell research projects:
- The title page of Effects Of Amount And Wavelength Of Light On A Solar Cell should include the project title, your name, institution, and date.
- The abstract of Effects Of Amount And Wavelength Of Light On A Solar Cell should be a summary of around 150-250 words and should highlight the main objectives, methods, results, and conclusions.
- The introduction of Effects Of Amount And Wavelength Of Light On A Solar Cell should provide the background information, outline the research problem, and state the objectives and significance of the study.
- Review existing research related to Effects Of Amount And Wavelength Of Light On A Solar Cell, identifying gaps the study aims to fill.
- The methodology section of Effects Of Amount And Wavelength Of Light On A Solar Cell should describe the research design, data collection methods, and analytical techniques used.
- Present the findings of the Effects Of Amount And Wavelength Of Light On A Solar Cell research study using tables, charts, and graphs to illustrate key points.
- Interpret Effects Of Amount And Wavelength Of Light On A Solar Cell results, discussing their implications, limitations, and potential areas for future research.
- Summarize the main findings of the Effects Of Amount And Wavelength Of Light On A Solar Cell study and restate its significance.
- List all the sources you cited in Effects Of Amount And Wavelength Of Light On A Solar Cell project, following a specific citation style (e.g., APA, MLA, Chicago).