The Heisenberg Uncertainty Principle can be used to calculate the uncertainty in the energy of an...

3. (10 pts) Heisenberg Uncertainty Principle The uncertainty principle places a limit on specifying the location...

3. (10 pts) Heisenberg Uncertainty Principle The uncertainty principle places a limit on specifying the location and momentum of a particle simultaneously. Δ?Δ? ≥ ℏ/2 This is a consequence of the wave nature of particles, which we can see by examining the uncertainty in the single-slit diffraction of light. (a) In single-slit diffraction, the width of the slit ? represents the uncertainty in x position of the beam, ∆?: ∆? = ? We can imagine that we can try to...

Use the Heisenberg uncertainty relation to find the approximate kinetic energy of an electron that is...

Use the Heisenberg uncertainty relation to find the approximate kinetic energy of an electron that is trapped in a region of size 0.2 nm. State your answer in units of eV. Type in only the numerical value of the answer, no unit.

1. Use the Heisenberg uncertainty principle to calculate Δx for an electron with Δv = 0.265...

1. Use the Heisenberg uncertainty principle to calculate Δx for an electron with Δv = 0.265 m/s. 2. By what factor is the uncertainty of the (above) electron's position larger than the diameter of the hydrogen atom? (Assume the diameter of the hydrogen atom is 1.00×10-8 cm.) 3. Use the Heisenberg uncertainty principle to calculate Δx for a ball (mass = 158 g, diameter = 6.55 cm) with Δv = 0.265 m/s. 4. The uncertainty of the (above) ball's position...

Use the Heisenberg uncertainty principle to calculate ?x for an electron with ?v = 0.205 m/s....

Use the Heisenberg uncertainty principle to calculate ?x for an electron with ?v = 0.205 m/s. By what factor is the uncertainty of the (above) electron's position larger than the diameter of the hydrogen atom? (Assume the diameter of the hydrogen atom is 1.00×10-8 cm.) Use the Heisenberg uncertainty principle to calculate ?x for a ball (mass = 132 g, diameter = 6.40 cm) with ?v = 0.205 m/s. The uncertainty of the (above) ball's position is equal to what...

The Heisenberg uncertainty principle applies to photons as well as matter particles. Thus, a photon confined...

The Heisenberg uncertainty principle applies to photons as well as matter particles. Thus, a photon confined to a very tiny box with size ∆x necessarily has a large uncertainty in momentum (and thus energy). Since energy is equivalent to mass, a confined photon will create a large gravitational field. If the equivalent mass is very large, the confined photon will correspond to a black hole. Recalling that the Schwarzschild radius of a black hole was defined as rs = 2GM...

The Width of Spectral Lines: The average time after excitation at which a group of atoms...

The Width of Spectral Lines: The average time after excitation at which a group of atoms radiate is called the lifetime, t, of an excited state. Due to Heisenberg uncertainty principle, the excited state energy has a corresponding uncertainty of DE, which is responsible for the width of spectral lines known as natural linewidth (natural broadening). If t = 1.0´10-8 s, calculate the energy uncertainty of the excited sate. Compute the natural linewidth Df of light due to transition from...

1. Compared to a 2 eV photon, a 5 eV photon has A. lower frequency. B....

1. Compared to a 2 eV photon, a 5 eV photon has A. lower frequency. B. shorter wavelength C. longer wavelength D. higher speed E. lower speed A particle is trapped in a small box. Compared to the same particle trapped in a larger box, what can you say about the ground state energy? If the box is smaller, the energy is greater. B. If the box is larger, the energy is greater C.The size of the box has no...

We can observe the differences in energy levels by observing the light that is emitted when...

We can observe the differences in energy levels by observing the light that is emitted when atoms are heated. When atoms are heated, the electrons can jump up to a higher energy level. When one electron falls back down to a lower energy level, a single photon of light is emitted with an energy equal to the difference in energy of the two levels. We call this atomic emission spectroscopy. If an electron in an atom jumps from the n...

The ground-state energy of a harmonic oscillator is 6 eV. If the oscillator undergoes a transition...

The ground-state energy of a harmonic oscillator is 6 eV. If the oscillator undergoes a transition from its n=3 to n=2 level by emitting a photon, what is the energy (in eV) of the emitted photon?

A certain atom has an energy level 2.58 eV above the ground level. Once excited to...

A certain atom has an energy level 2.58 eV above the ground level. Once excited to this level, the atom remains at this level for 1.64E-7 s (on average) before emitting a photon and returning to the ground level. a) What is the energy of the photon (in electron volts)? What is its wavelength (in nanometers)? b) What is the smallest possible uncertainty in energy of the photon? Give your answer in electron volts. c) Show that|?E/E|=|??/?|if |??/?|?1. Use this...