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In order for a hydrogen atom to have a continuous spectrum, the oscillation would have to be incoherent. In other words, there would be no fixed or steady state oscillation. In addition, the change in state of the oscillator would have to be incoherent. We know that the energy that is radiated from a hydrogen atom is due to changes in the energy states of the atom. Therefore, each of the states that the atom would have to reach must be perfectly random. This would produce a nearly continuous spectrum over a certain range in frequencies or wavelengths.
Any incandescent source such as candle flame, sun, carbon arc lamp would give continuous spectrum. When the temperature is low then red and orange may be there. As temperature increases then spectrum would extend towards violet end
If an atom's electrons were not restricted to particular energy levels, its spectrum would likely appear as a continuous spectrum rather than discrete lines. This is because the energy levels of the electrons in the atom contribute to the specific wavelengths of light emitted or absorbed, and without these restrictions, the energy transitions would be continuous, resulting in a continuous spectrum.
The answer is Rainbow!...
The type of spectrum observed would depend on the source of light. A continuous spectrum is produced by a hot, dense object like a solid, liquid, or dense gas. An emission spectrum is generated by a thin, hot gas, while an absorption spectrum is created by a cooler gas in front of a light source.
If the electron in a hydrogen atom obeyed classical mechanics instead of quantum mechanics, it would emit a continuous spectrum. This is because classical mechanics does not quantize energy levels like quantum mechanics does, leading to a continuous range of energy levels and thus a continuous spectrum when the electron transitions between them.
It's a line spectrum because of the quantization of energy- meaning you only see energy with levels n=1,2,3.... One would never see the energy level n=2.8 for instance- that would be the case if it were continuous rather than a line spectrum.
Neither, they would join the spectrum together and become violet.
a continuous spectrum with all colors blending together.
A metal would not be attracted to either water's hydrogens or oxygens because metals typically do not have a strong affinity for interacting with individual water molecules. Metals and water molecules generally do not have a strong enough interaction to cause attraction between them.
A continuous spectrum is produced when white light passes through a prism or when hot gas is heated to incandescence. In either case the light is separated into its component colors based on their different wavelengths. All the colors of the visible spectrum from red to violet are present in the resulting continuous spectrum.When white light passes through a prism the individual wavelengths of light are bent at different angles separating the light into a spectrum. This is known as dispersion. The prism separates the wavelengths of light into visible colors with the shortest wavelength being the color red and the longest wavelength being the color violet.When hot gas is heated to incandescence the gas molecules become excited and emit light. The light produced is a continuous spectrum because all the wavelengths of visible light are present. The intensity of the emitted light varies with the wavelength with the shortest wavelength having the greatest intensity and the longest wavelength having the least intensity.
The electromagnetic spectrum is called continuous because it consists of a range of electromagnetic waves with varying frequencies and wavelengths that blend seamlessly into one another without distinct boundaries or gaps. This continuous nature allows for a smooth transition between different types of electromagnetic radiation.