slext the correct equations that show that the calie of the Rydberg constant is R =1.0974*10^7...

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...

Show that for all a; b; c 2 R the following system of equations is consistent...

Show that for all a; b; c 2 R the following system of equations is consistent x + 2y + z = a x + 3y + 3z = b x + 4y + 2z = c

Show that the pair of equations A = 1/2 ( B × r) , B =...

Show that the pair of equations A = 1/2 ( B × r) , B = ∇ × A is satisfied by any constant magnetic induction B.

A. GALILEO’S EQUATIONS FOR MOTION SHOW THE ALGEBRA STEPS TO REACH EQUATIONS 9, 10, 11, 12...

A. GALILEO’S EQUATIONS FOR MOTION SHOW THE ALGEBRA STEPS TO REACH EQUATIONS 9, 10, 11, 12 1. Velocity: v = (x2- x1)/(t2- t1),  which may be written v = Δx/Δt  [equation 1] 2. Acceleration: a = (v2- v1)/(t2- t1), which may be written a = Δv/Δt [equation 2) 3. Average velocity: <v> =(v1+v2)/2  [equation3] 4.  <v> = d/t   [equation 4] 5. COMBINING equations 3 and 4: (v1+v2)/2 = d/t  [equation 5] The equations below are results valid only for the case of constant acceleration. 6. Velocity:...

1. a) Find the solution to the system of linear equations using matrix row operations. Show...

1. a) Find the solution to the system of linear equations using matrix row operations. Show all your work. x + y + z = 13 x - z = -2 -2x + y = 3 b) How many solutions does the following system have? How do you know? 6x + 4y + 2z = 32 3x - 3y - z = 19 3x + 2y + z = 32

The wavelengths of spectral lines depends to some extent on the mass of the nucleus. This...

The wavelengths of spectral lines depends to some extent on the mass of the nucleus. This occurs because the nucleus is not an infinitely heavy mass that remains stationary. In fact, in reality, both the nucleus and the electron orbit about their common center of mass. It can be shown that a system of this type is entirely equivalent to a single object with a mass μμ (called the Reduced Mass) that orbits about the location of the nucleus at...

Constant Table: e0 =8.85´10-12C2×N--1×m-2 ; R=8.315J-mol-1×K-1; m0= 4π´10-7N×A-2; h = 6.63´10-34J×s; e = 1.602´10-19C; G=6.67´10-11N×m2-kg-2; me=9.11´10-31kg;...

Constant Table: e0 =8.85´10-12C2×N--1×m-2 ; R=8.315J-mol-1×K-1; m0= 4π´10-7N×A-2; h = 6.63´10-34J×s; e = 1.602´10-19C; G=6.67´10-11N×m2-kg-2; me=9.11´10-31kg; g=9.8 m/s2; (2) When a light beam of wavelength 620 nm is incident on a photodiode of 50% quantum efficiency, the photocurrent generated is 2 μA. What is the incident optical power? (A) 4 μW (B) 3 μW (C) 1 μW (D) 2 μW

- write N-S equations for incompressible flows in cartesian coordinates in long form (in x,y,z coordinates)...

- write N-S equations for incompressible flows in cartesian coordinates in long form (in x,y,z coordinates) (1 point) - also write continuity equation and N-S equations for incompressible flows in polar coordinates in long form (in r,θ,z) (since one of your friends ask you can find it easily in online resources or in books) (1 point) - Write down N-S equations in x direction for Planar Couette- Pouseille flow and derive an equation for velocity variation using boundary layer conditions...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that...

Consider the bead on a rotating circular hoop system that we saw in lecture. Recall that R is the radius of the hoop, ω is the angular velocity of rotation, and m is the mass of the bead that is constrained to be on the hoop as it rotates about the z-axis. We found that we could solve the constraints in terms of a single coordinate θ and that the Cartesian coordinates were given by x = −R sin(ωt)sinθ, y...

Show that the series \sum_{n=1}^{\infty} 1/(x^2 + n^2) defines a differentiable function f: R -> R...

Show that the series \sum_{n=1}^{\infty} 1/(x^2 + n^2) defines a differentiable function f: R -> R for which f' is continuous. I'm thinking about using Cauchy Criterion to solve it, but I got stuck at trying to find the N such that the sequence of the partial sum from m+1 to n is bounded by epsilon