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ContinuousSpectra.ppt Spectral Types – Continuous Spectra A spectrum of electromagnetic waves that involves a wide range (continuous range) of wavelengths. In the visible portion of the electromagnetic spectrum, a continuous spectrum would look like a rainbow Spectral Types – Continuous Spectra Kinetic Theory The Temperature of an object is a measure of the kinetic energy of the particles in the system. The higher the kinetic energy of the particles, the higher the temperature. Solids, liquids – Temperature primarily determined by vibrational kinetic energy of the particles in the system Gas – Temperature is determined by the translational kinetic energy of the particles in the gas Spectral Types – Continuous Spectra Continuous emission of electromagnetic waves When the particles in the solid, liquid, or gas accelerate, they will produce EM waves. Mechanisms: Particle vibrations (solids, liquids) Electron transitions in chemical bonds (solids, liquids) Particle-particle collisions (gasses) Spectral Types – Continuous Spectra Stellar Spectra EM waves emitted from a star result from the collisions of charged particles within the star. Particle in the star move with very high kinetic energies. Energy changes occur as a result of particle - particle collisions. Energy loss through collision Spectral Types – Continuous Spectra Stellar Spectra Since a wide range of energies can be experienced by the particles, a similarly wide range of frequencies of photons can be emitted. However, the temperature of the star determines how much kinetic energy is associated with the particle motion. The hotter the star, the more energetic the collision. Therefore, the higher the energies of the emitted photons. Spectral Types – Continuous Spectra Stellar Spectra Since for a photon E=hf The energy carried by the photon determines the position of the electromagnetic wave on in the electromagnetic spectrum. If the resulting frequency is within the visible window, the energy of the photon will determine the color of the electromagnetic wave. Spectral Types – Continuous Spectra Blackbody radiation λPeak Spectral Types – Continuous Spectra Blackbody radiation "Blackbody radiation" refers to an object or system which absorbs all radiation incident upon it and re-radiates energy which is characteristic of this radiating system only, not dependent upon the type of radiation which is incident upon it. Spectral Types – Continuous Spectra Stellar Spectra Because of the wide range of photon energies available through collisions of the particles in a star, a star will emit blackbody radiation. Since the frequency of emitted photons will be determined by the temperature of the star, there is a direct relationship between the color of the star and it’s temperature. Website to view a temperature adjustable blackbody radiation curve Spectral Types – Continuous Spectra Blackbody radiation Physical Laws Governing BB radiation Wien’s Law Wavelength of Peak Emission = 0.29 Temperature in K cm Spectral Types – Continuous Spectra Blackbody radiation Physical Laws Governing BB radiation Stefan’s Law Power Emitted per unit Area = σ T4 σ = 5.67 x 10-8 W / m2 – K4 Note: A Watt (W) is a Joule/Sec (Stefan-Boltzmann constant)
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