The Bohr Model of the hydrogen atom proposed that there were very specific energy states that...

1). The Bohr Model of the hydrogen atom proposed that there were very specific energy states...

1). The Bohr Model of the hydrogen atom proposed that there were very specific energy states that the electron could be in. These states were called stationary orbits or stationary states. Higher energy states were further from the nucleus. These orbits were thought to be essentially spherical shells in which the electrons orbited at a fixed radius or distance from the nucleus. The smallest orbit is represented by n=1, the next smallest n=2, and so on, where n is a...

Which of the following provisions of the Bohr atomic model of hydrogen turned out to be...

Which of the following provisions of the Bohr atomic model of hydrogen turned out to be false? The line spectrum of hydrogen is produced when photons are emitted having energies which are differences between quantum energy levels. b) The energy of the electron is quantized. An electron moves in a circular orbit around the nucleus. The energy of the electron is inversely proportional to the square of the quantum number n.

A Hydrogen atom has one proton in the nucleus and one electron in the shell. In...

A Hydrogen atom has one proton in the nucleus and one electron in the shell. In a classic model of the atom, in a certain state, this electron is in a circular orbit around the nucleus with an velocity of 1090729.85781991 m/s. What is the radius of the orbit? What is the angular momentum, L, of the electron at this radius? What is the quantum value, n, of the electron at this radius? What is the total energy of the...

A hydrogen atom is in the n = 4 state. In the Bohr model, how many...

A hydrogen atom is in the n = 4 state. In the Bohr model, how many electron wavelengths fit around this orbit?

In the Bohr model of the atom, what is true about the light emitted by an...

In the Bohr model of the atom, what is true about the light emitted by an atom? 1. The emitted photon’s frequency is the classic frequency at which an electron vibrates. 2. An electron accelerating around its orbit continuously emits radiation. 3. None of these 4. The energy of the emitted photon is equal to the difference in energy between the two orbits.

Consider the Bohr model of the hydrogen atom for which an electron in the ground state...

Consider the Bohr model of the hydrogen atom for which an electron in the ground state executes uniform circular motion about a stationary proton at radius a0. (a) Find an expression for the kinetic energy of the electron in the ground state. (b) Find an expression for the potential energy of the electron in the ground state. (c) Find an expression for the ionization energy of an electron from the ground state of the hydrogen atom. The ionization energy is...

Neils Bohr’s model of the hydrogen atom explained the unique set of spectral emission or absorbtion...

Neils Bohr’s model of the hydrogen atom explained the unique set of spectral emission or absorbtion lines seen for hydrogen or other atoms. Pick the statment that best summarizes the model. 1. The electrons all formed one single continuous ring around the nucleus. When light was shone at the atom, this ring expanded. Becuase the electrons were further apart and higher in energy, light was absorbed as this happened. The color of light absorbed was related to the number of...

Answer the following questions using the Bohr model of the hydrogen atom. a) A hydrogen atom...

Answer the following questions using the Bohr model of the hydrogen atom. a) A hydrogen atom is the n = 3 excited state when its electron absorbs a photon of energy 4.40 eV. Draw a diagram roughly to scale, of relevant energy levels for this situation. Make sure to show and label the initial energy of the H atom in the n=3 state, the energy level at which this atom loses its electron, and kinetic energy of the electron. b)What...

A hydrogen atom is in its ground state (n = 1). Using the Bohr theory of...

A hydrogen atom is in its ground state (n = 1). Using the Bohr theory of the atom, calculate (a) the radius of the orbit. (b) the velocity of the electron where vn = ?(kee2)/(mern) . (c) the kinetic energy of the electron (d) the static electric potential energy of the electron. (e) the total energy of the electron. (e) the energy gained by moving to a state where n = 5. (g) the wavelength, ?, of the EM waved...

31) For the Bohr hydrogen atom determine: (½ pt each = 2 pts total) (a) The...

31) For the Bohr hydrogen atom determine: (½ pt each = 2 pts total) (a) The radius of the orbit n = 4: (b) Whether there is an orbit having a radius of 4.00 Angstroms: *please be detailed (c) The energy level corresponding to n = 8: (d) Whether there is an energy level at– 2.5 x 10^17 J: