Use the Bohr model to find the longest wavelength of light in the Paschen series for...

Use the Bohr model to find the longest wavelength of light in the Balmer series for...

Use the Bohr model to find the longest wavelength of light in the Balmer series for a doubly-ionized Li atom (Z = 3). Recall that the Balmer series corresponds to transitions to the n = 2 level. 13.5 nm 117nm 73nm 41.2nm 209nm 700nm none of the above

Use the Bohr model to find the longest wavelength of light in the Balmer series for...

Use the Bohr model to find the longest wavelength of light in the Balmer series for a triply-ionized Be atom (Z = 4). Recall that the Balmer series corresponds to transitions to the n = 2 level. 13.5 nm 117 nm 73.0 nm 41.1 nm 209 nm

use the bohr modle to find the longest wavlength of ight in the balmer series for...

use the bohr modle to find the longest wavlength of ight in the balmer series for a doubly-ionized Li atom (Z=3). Recall that the Balmer series corresponds to transitions to the n = 2 level.

Let's use the Bohr model equations to explore some properties of the hydrogen atom. We will...

Let's use the Bohr model equations to explore some properties of the hydrogen atom. We will determine the kinetic, potential, and total energies of the hydrogen atom in the n=2 state, and find the wavelength of the photon emitted in the transition n=2?n=1. Find the wavelength for the transition n=3 ? n=2 for singly ionized helium, which has one electron and a nuclear charge of 2e. (Note that the value of the Rydberg constant is four times as great as...

The ionized helium atom can be treated with a Bohr model with nuclear charge Z=2. The...

The ionized helium atom can be treated with a Bohr model with nuclear charge Z=2. The resulting energy levels are four times those of the hydrogen atom: Ehelium=4Ehydrogen= -(54.4eV)/n^2 From those energy levels, calculate the wavelengths of spectral lines from ionized helium for transitions that end on nf=1. Do any of these lie in the visible range? Would any spectral lines of ionized helium lie in the visible range?

Light from a laser of wavelength 475 nm is incident upon an atom of hydrogen in...

Light from a laser of wavelength 475 nm is incident upon an atom of hydrogen in the first excited state. (a) What is the highest energy level (value of n) to which the hydrogen atom can be excited by the laser?   (b) What happens if the laser wavelength is 295 nm? Another way to get the energy levels of the Bohr atom is to assume that the stationary states are those for which the circumference of the orbit is an...

Exercise: Consider the Bohr Theory Hydrogen atom. a) how much energy is needed to cause a...

Exercise: Consider the Bohr Theory Hydrogen atom. a) how much energy is needed to cause a transition of an electron from the 2nd excited state to the 3rd excited state? Remember the 2nd excited state corresponds to n=3, etc). b) what wavelength photon just has enough energy to initiate the transition?

(a) Use the Bohr model to calculate the period and frequency of an electron in the...

(a) Use the Bohr model to calculate the period and frequency of an electron in the second Bohr orbit of the hydrogen atom. period frequency (b) What is the range of frequency of the light emitted by the hydrogen atom? minimum frequency maximum frequency

(a) Use the Bohr model to calculate the period and frequency of an electron in the...

(a) Use the Bohr model to calculate the period and frequency of an electron in the second Bohr orbit of the hydrogen atom. period? frequency? (b) What is the range of frequency of the light emitted by the hydrogen atom? minimum frequency? maximum frequency?

Consider a Li++ ion as described by the Bohr model. (a) At some other time, the...

Consider a Li++ ion as described by the Bohr model. (a) At some other time, the electron in n=4 state. What possible wavelength of radiation emitted by this atom? Write the algebraic expression(s) and draw the diagram to illustrate the transitions. (b) What is the ground state energy of this system in eV? Write the expression and evaluate it. What value of the quantum number n does this correspond to? (c) Now assume the electron is in the n=1 state....