From the expectation values of p, x, p^2, x^2 (using laddet operators) verify the uncertainty relation...

Consider the ground state of the harmonic oscillator. (a) (7 pts) Calculate the expectation values <x>,...

Consider the ground state of the harmonic oscillator. (a) (7 pts) Calculate the expectation values <x>, <x2>, <p> and <p2>. (b) (3 ps) What is the product ΔxΔp, where the two quantities are standard deviations? (This is easy if you did part (a)). How does this answer compare with the prediction of the Uncertainty Principle?

Consider the following wave function: Psi(x,t) = Asin(2piBx)e^(-iCt) for 0<x<1/2B Psi(x,t) = 0 for all other...

Consider the following wave function: Psi(x,t) = Asin(2piBx)e^(-iCt) for 0<x<1/2B Psi(x,t) = 0 for all other x where A,B and C are some real, positive constants. a) Normalize Psi(x,t) b) Calculate the expectation values of the position operator and its square. Calculate the standard deviation of x. c) Calculate the expectation value of the momentum operator and its square. Calculate the standard deviation of p. d) Is what you found in b) and c) consistent with the uncertainty principle? Explain....

Consider a wave-packet of the form ψ(x) = e −x 2/(2σ 2 ) describing the quantum...

Consider a wave-packet of the form ψ(x) = e −x 2/(2σ 2 ) describing the quantum wave function of an electron. The uncertainty in the position of the electron may be calculated as ∆x = p hx 2i − (hxi) 2 where for a function f(x) the expectation values hi are defined as hf(x)i ≡ R ∞ −∞ dx|ψ(x)| 2f(x) R ∞ −∞ dx|ψ(x)| 2 . Calculate ∆x for the wave packet given above. [Hint: you may look up the...

Determine the observed values (if they exist) for linear momentum and position of a quantum particle...

Determine the observed values (if they exist) for linear momentum and position of a quantum particle free to travel in the x direction. Explain your answer using the Hiesenberg uncertainty principle.

2-Verify the given linear approximation at a = 0. Then determine the values of x for...

2-Verify the given linear approximation at a = 0. Then determine the values of x for which the linear approximation is accurate to within 0.1. (Enter your answer using interval notation. Round your answers to three decimal places.) 1 (1 + 4x)4 ≈ 1 − 16x

QA: Using by-hand formulas first (and Desmos only to verify later), (i) Find the x values...

QA: Using by-hand formulas first (and Desmos only to verify later), (i) Find the x values of the inflection points of exp(-x^2/2), which is related to the usual “bell curve” in statistics. (ii) Find the x values of the inflection points of 1/(1+x^2), which is related to a heavy-tailed version of a “bell curve”. Hint: try plus/minus 1/sqrt(3) as a guess, then show that f’’ is zero there.

1) Calculate the commutation [Px, x], [Py, x], and [Px, Py] 2) Write down explicitly the...

1) Calculate the commutation [Px, x], [Py, x], and [Px, Py] 2) Write down explicitly the position, momentum, angular momentum and the kinetic energy operators. 3) Express the following by using the Bra-Ket notation (discrete case) a. Orthogonality of basis vectors b. Normalization c. Expansion of any arbitrary state and expansion coefficient

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...

In parts (1) and (2), calculate the minimum uncertainty in the momentum for the objects described....

In parts (1) and (2), calculate the minimum uncertainty in the momentum for the objects described. Refer to Heisenberg's Uncertainty Principle in your textbook. A child runs through a door having a width of 0.79 m. Δpchild = A proton passes through a slit that has a width of 7 x 10-10 m. Δpproton = A car of mass 1170 kg travels at 20 m/s (45 mph). Assume that the velocity measurement is known to within 1 % on either...

If X ~ Bin (n, p) and Y ~ Bin (n, 1 - p). Verify that...

If X ~ Bin (n, p) and Y ~ Bin (n, 1 - p). Verify that for any k = 1, 2,.... P (X = k) = P (Y = n - k)