differences between the energy levels of the orbits matched the difference between energy levels of the line spectra.
The only technology Bohr needed to develop his model for the atom was a spectrometer, which, in the mid-1800s, revealed the emission lines of hydrogen. In 1885, Johann Balmer developed a mathematical formula (the Balmer Series) that fully described these lines, but nobody could explain why it worked. Neils Bohr combined the quantum ideas of Max Planck and Albert Einstein with the atomic model proposed by Ernest Rutherford, and developed an atomic model from which the Balmer Series could be derived.
It helps explain metallic bonds.
The Bohr model was inadequate because it couldn't fully explain the behavior of complex atoms or molecules. It couldn't account for the fine structure of spectral lines or the observed distribution of electrons in atoms. Additionally, it couldn't explain the quantum mechanical behavior of particles at the atomic level.
The Fluid Mosaic Model is used to explain the components and properties of the plasma membrane. This model describes the plasma membrane as a dynamic structure composed of a lipid bilayer with embedded proteins that can move and interact within the membrane.
Ptolemy did not explain Venus phases in his geocentric model because he believed that Venus, like all other planets, moved around the Earth in perfect circles and did not exhibit phases like the Moon. His model could not account for the varying phases of Venus because it was based on circular motion and did not include elliptical orbits or the correct understanding of planetary motion.
The only technology Bohr needed to develop his model for the atom was a spectrometer, which, in the mid-1800s, revealed the emission lines of hydrogen. In 1885, Johann Balmer developed a mathematical formula (the Balmer Series) that fully described these lines, but nobody could explain why it worked. Neils Bohr combined the quantum ideas of Max Planck and Albert Einstein with the atomic model proposed by Ernest Rutherford, and developed an atomic model from which the Balmer Series could be derived.
Well, the different series represent different electronic transitions. But there is an important equation, the Rydberg formula which describes all of them.. I think you've learned of it since you mention the n values. This lead to the Bohr model of the hydrogen atom, which explained _why_ you had these levels.Or, almost. See, it turned out that those lines were not actually single lines, but several lines very close together.. And so they had to add more variables to describe how these levels-within-levels fit together.. and the answer to that eventually came from quantum mechanics.
Explain data model?
it couldn't explain all the observed transitions
on line because my friend has a savage series a
explain spiral model in sdlc
The Bohr model of the atom explains why excited hydrogen gas gives off certain colors of light. When an electron transitions from a higher energy level to a lower one, it emits light with specific wavelengths corresponding to the difference in energy levels, producing the characteristic spectral lines of hydrogen such as the Balmer series.
It is because there is a light bulb and things like that......
Explain OSI reference model with revant diag
Bohr's model of the atom doesn't explain hydrogen's flammability.
Dalton's atomic postulations stated that:Elements are made of tiny particles called atoms.All atoms of a given element are identical.The atoms of a given element are different from those of any other element; the atoms of different elements can be distinguished from one another by their respective relative weights.Atoms of one element can combine with atoms of other elements to form chemical compounds; a given compound always has the same relative numbers of types of atoms.Atoms cannot be created, divided into smaller particles, nor destroyed in the chemical process; a chemical reaction simply changes the way atoms are grouped together.
Niels Bohr developed an empirical equation, known as the Balmer formula, which calculates the wavelengths of lines in the spectrum of hydrogen atoms. This equation helped explain the discrete energy levels of electrons within an atom, leading to the development of the Bohr model of the atom.