Without light, life on Earth would not exist. It is the most essential component in all of the universe and it is very complex. In 1799, Thomas Young began to study sight and the behavior of light, otherwise known as optics. During his time, Young made many scientific advancements in the field of optics that have impacted the world we know today. This report will be discussing the topic of Thomas Young's Double-Slit Experiment. Take note of the diagrams as presented in paragraphs one and three. The main ideas of this topic are the properties of light, the interference of light, and the details that make up Young's experiment.
To start off, light has many complex properties. Light has the property of waves in the form of electromagnetic radiation. This electromagnetic radiation has a spectrum that can be separated into an extensive amount of bands based on the length of the wave. Light that is visible to the human eye represents only a fraction of the total wave lengths that are between 380nm and 730nm.
The human eye interprets each wave length as a different color; when ...
...nd violet wavelengths are the shortest, and violet is the least visible to the human eye. These wavelengths are scattered throughout the day and caused by a redirection of the light-waves direction due to gas molecules in the atmosphere (Mc Knight, p. 84). When the sun is setting towards the end of the day there are few blue wavelengths left and we see orange and red which are dominant and the longest wavelengths of visible light to the human eye. At the bottom of the photo (closest to the setting sun) red and orange are the dominant visible colors with the occasional blue and almost violet. If our eyes could not see orange and red our sunsets would be a dark blue or black.
Atomic Absorption (AA) Spectroscopy is a quantitative analysis technique that uses the absorption of light through a flame and gaseous chemicals. AA Spectroscopy can be used for a multitude of purposes, most notably finding the concentration of one or a few elements in a compound. AA Spectroscopy can work in two different ways using an open flame and gaseous chemicals or a graphite furnace. Flame AA Spectroscopy works by taking a compound or element and disassociating it into an aqueous solution. The solution is then blown through an incredibly small nozzle which nebulizes the liquid into a very fine mist. The nebulized liquid is then blown through a flame with a very small beam of light passing through it. This light beam detects different elements in the flame and uses the known light absorbance of the element to determine the concentration of the element in the solution. The other form of AA Spectroscopy uses a graphite furnace to heat up and incinerate a sample. A solid compound is placed in the furnace which then heats up to 2000-3000 C effectively atomizing the compound and in the process turning the rest into ash. The light beam is then shot through the furnace as the solid is being heated and subsequently atomized and the machine records the absorbance rate much like the Flame AA Spectroscopy would. The difference between flame and furnace spectroscopy is in the atomization of the sample; because the Flame Spectroscopy uses pressure to atomize the compound, much of the compound is lost when sprayed
During the crisis of modern science in the late nineteenth and early twentieth centuries, the postulates of early scientific discoveries had been refuted. In one of science’s most defining moments, an undisturbed photon of light was found to exhibit both wave-like and particulate qualities. The relationship between these two qualities would later be termed complementarity by Niels Bohr, one of the scientists at the forefront of this discovery. As Thomas S. Kuhn notes in The Structure of Scientific Revolutions, “Before [the theory of quantum mechanics] was developed by Plank, Einstein, and others early in [the twentieth] century, physics texts taught that light was transverse wave motion” (12). So staggering was this discovery that in his autobiography, Albert Einstein recounts, “All my attempts to adapt the theoretical foundations of physics [to the new quantum knowns] failed completely. It was as if the ground had been pulled out from under one, with no firm foundation to be seen anywhere upon which one could have been built.” Not surprisingly, this arrest of the fundamental postulates of classical physics sparked a reevaluation of the “world view” by the ...
In this experiment, Newton placed a second prism 5 or 6 yards away from the first. At first, when the light passed through the prisms, his results were the same as the first experiment. However, when the prisms were moved farther away from the wall onto which the light was being projected, the light projected from the prisms became white again. When they were moved even farther, the light became colored again, but the color scale was inverted from the original scale. According to the accepted theory of light, the second prism changed the color of the light projected onto the wall. Therefore, Newton’s results once again contradicted the accepted theory of light. He also rotated the prisms to test if this would have an effect on the light, but it did not. Due to these observations, Newton concluded that light was in fact a combination of all light on the spectrum of light, not just a mixture of light and
Quantum Mechanics developed over many decades beginning as a set of controversial mathematical explanations of experiments that the math of classical mechanics could not explain. It began in the turn of the 20th century, a separate mathematical revolution in physics that describes the motion of things at high speeds. The origins of Quantum Mechanics cannot be credited to any one scientists. Multiple scientists contributed to a foundation of three revolutionary principles that gradually gained acceptance and experiment verification from 1900-1930 (Coolman). Quantum Mechanics is
Williams, B. 1999. A History of Light and Lighting. [online] Available at: http://www.mts.net/~william5/history/hol.htm [Accessed: 5 Jan 2014].
Light is both part particle and part wave. Light is “the electromagnetic radiation that may be perceived by the human eye”. It consists of photons, which are massless bundles of concentrated electromagnetic energy. Light’s lower frequency is red, and the higher frequency is blue. Like sound, light has frequencies humans can’t detect. Ultraviolet light is at a frequency higher than violet, and infrared is at the frequency lower than the red of visible light. We get UV (ultraviolet) rays from the sun, and infrared is used in night vision to see better.
Masters, Barry R. "Albert Einstein and the Nature of Light." 2010. Optics and Photonics News. The Optical Society. Article. 31 March 2014. .
Signal detection theory is introduced by mathematicians and engineer in 1950 . It started to evolve from the developing electronics communication.
However Spectroscopy is not a recent development, as it has been utilized for many years since Isaac Newton made the first advances in 1666. Spectroscopy is the study of light as a function of wavelength that has been emitted, reflected or scattered from a solid, liquid, or gas. Fundamentals of Spectroscopy Spectroscopy is the distribution of electromagnetic energy as a function of wavelength. Spectrum is basically white light dispersed by a prism to produce a rainbow of colours; the rainbow is the spectrum of sunlight refracted through raindrops. All objects with temperatures above absolute zero emit electromagnetic radiation by virtue of their warmth alone; this radiation is emitted at increasingly shorter wavelengths as temperature is increased.
Light is what lets you experience colour. The pigment of the retina in your eyes is sensitive to different lengths of light waves which allows you to see different colours. The wavelengths of light that humans can see are called the visible colour spectrum.
An oscilloscope is an electronic test instrument that is used to observe an electronic signal, typically voltage, as a function of time. In other words, it is a voltage versus time plotter. Oscilloscopes come in two basic types, analogue or digital, and support various features and functions useful for measuring and testing electronic circuits. An oscilloscope is a key piece of test equipment for any electronics designer.
Application such as the sun emits most of its radiation in the visible range which our eyes recognize as the color of rainbow.
Oftentimes, a person can look at an image and draw a conclusion about it, only to find out later that he or she was incorrect. This phenomenon is due to what is called an optical illusion, in which an image is perceived incorrectly to be something else. This leads to the questions, why do optical illusions occur, and what can be done about them?
Electromagnetic radiation is energy that flows through free space. Electromagnetic radiation comes in a list of energies known as the electromagnetic spectrum. Electromagnetic spectrum is the complete range of the different wavelength of electromagnetic radiation. It consists of light, radio waves, visible light, infrared waves, ultraviolet light, x-rays, microwaves and gamma rays.