All in nM (nano metre, in vacuo):
The Balmer series: (up to 3 eV energy)
397
410
434
486
656
Niels Bohr studied the emission lines of Hydrogen.
Yes there will be. This is because when you take line spectrum of water vapor, then hydrogen and oxygen atoms will form their own line spectra and the final spectrum will be a combination of the two.
The electron transition from n=5 to n=1 in a hydrogen atom corresponds to the Balmer series, specifically the Balmer-alpha line which is in the visible part of the spectrum.
The ratio of the first line of the Lyman series to the first line of the Balmer series in the hydrogen spectrum is 1:5.
The hydrogen atom has four spectral lines because it undergoes transitions between its energy levels. These transitions produce four distinct wavelengths of light in the visible spectrum: 656.3 nm, 486.1 nm, 434.0 nm, and 410.2 nm. Each line corresponds to electrons moving between different energy levels in the atom.
the line spectrum of the hydrogen spectrum indicates that only certain energies are allowed for the electron of the hydrogen atom. In other words, the energy of the electron in the hydrogen atom is quantized.
they form on the scrotum of the hydrogen atom and the testicles from the other atom jam up in the hydrogen's b-hole
Because the bright line spectrum is generated by the transition of electrons in the atom among higher and lower energy levels, and no other atom of any other element has less than one electron in it.
stability of atoms line spectrum of hydrogen atom compton effect photoelectric effect black body radiation
Niels Bohr studied the emission lines of Hydrogen.
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.
hydrogen for my A+ peeps ;)follow my insta @braezybreemy snap @young_breee22
Yes there will be. This is because when you take line spectrum of water vapor, then hydrogen and oxygen atoms will form their own line spectra and the final spectrum will be a combination of the two.
Bohr.
The hydrogen line emission spectrum was discovered by physicists Johann Balmer, Johannes Rydberg, and Niels Bohr. They observed that hydrogen gas emitted specific wavelengths of light, which formed a distinct spectrum now known as the Balmer series.
Red, blue, green, and violet are found in the emission spectrum of hydrogen.
Niels Bohr used Planck's idea of quantization to propose his model of the atom, which successfully explained the line spectrum of hydrogen. Bohr suggested that electrons orbit the nucleus in quantized energy levels, emitting or absorbing photons of specific energies when transitioning between these levels, which correspond to the observed spectral lines.