![]() ![]() Gas discharge tubes contain low pressure to reduce the movement of gas molecules in air.This is achieved by producing a very strong electric field between the metal electrodes. The high voltage (greater than 1000 V) is essential to permit the electric current to pass through air.The metal electrodes are placed within an enclosed glass tube that contains a particular gas. Each element produces a unique emission spectrum.Įxamples of Various Spectra Gas Discharge Tubesĭischarge tubes are used to generate atomic emission spectra from gases.Ī discharge tube is a simple apparatus consisting of two metal electrodes connected to a high voltage potential difference. The absorption or emission spectrum would be unique for an element, and thus, can be used to identify elements.Įmission spectra of noble gases differ in the position and total number of emission lines. These streaks of light are called emission lines.Įlements have unique emission and absorption spectra.Ĭonsequently, no two elements will produce identical absorption and emission spectra. This produces an emission spectrum where only certain frequencies/wavelengths of light are present on a black background. The amount of energy released produces EMR of specific frequencies/wavelengths because it equals the difference between energy states. In a sample of hot gas where electrons are in their excited energy states due to the provision of heat as an energy source, these electrons can return to their ground states and release energy in the form of EMR. This type of spectrum is called an absorption spectrum.įor atoms of a particular element, there are usually more than one absorption line present because a ground state electron can be excited to different excited energy states by absorbing different amounts of energy (in the form of light). Therefore, absorption of light during electronic excitation causes there to be absent frequencies/wavelengths of light in the otherwise continuous spectrum. These absent lines are called absorption lines. When the same source of light is passed through atoms, ground state electrons can absorb specific amounts of energy to transition to higher energy states.ĭifferent energy of light corresponds to different frequencies/wavelengths. When white light is dispersed through a glass prism, it forms a continuous spectrum. White light consists of visible light of all wavelengths. Since atoms have multiple excitation states, there may be multiple electronic transitions, causing the emitted electromagnetic radiation to vary in energy and thus have different frequencies and wavelengths. When electrons return from their excited state to the ground state, energy is released in the form of electromagnetic radiation (EMR).ĭuring this process, electrons will release the same amount of energy as they absorbed (law of conservation of energy). Although it is hard to see in this printed version, in a well-dispersed spectrum, many subtle gradations in color are visible as your eye scans from one end (violet) to the other (red).If the energy provided does not exactly match this energy difference, it is does not absorbed by the electron.Įxcited electrons do not remain in their excited energy states permanently. When white light passes through a prism, it is dispersed and forms a continuous spectrum of all the colors. ![]()
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