g)Determine energy of spring at the lowest point in oscillation. (i)Show that work done on spring...

Consider a 0.85 kg mass oscillating on a massless spring with spring constant of 45 N/m....

Consider a 0.85 kg mass oscillating on a massless spring with spring constant of 45 N/m. This object reaches a maximum position of 12 cm from equilibrium. a) Determine the angular frequency of this mass. Then, determine the b) force, c) acceleration, d) elastic potential energy, e) kinetic energy, and f) velocity that it experiences at its maximum position. Determine the g) force, h) acceleration, i) elastic potential energy, j) kinetic energy, and k) velocity that it experiences at the...

Spring Mass System – Sinusoidal motion properties A 300 g mass hanging from a spring vibrates...

Spring Mass System – Sinusoidal motion properties A 300 g mass hanging from a spring vibrates such that at its lowest point it is 2 cm above the table top and at its highest point it is 16 cm above the table. Its oscillation period (T) is 4 sec. What is its total travel distance between high to low? What is the position above the table of its equilibrium point? Determine the spring constant. (hint: think period) Determine the maximum...

1. (a) Determine the amount of work (in joules) that must be done on a 100...

1. (a) Determine the amount of work (in joules) that must be done on a 100 kg payload to elevate it to a height of 1005 km above the Earth's surface. ______MJ (b) Determine the amount of additional work that is required to put the payload into circular orbit at this elevation. _______ J 2. A vertical spring stretches 4.0 cm when a 12-g object is hung from it. The object is replaced with a block of mass 20 g...

A block with mass m =7.3 kg is hung from a vertical spring. When the mass...

A block with mass m =7.3 kg is hung from a vertical spring. When the mass hangs in equilibrium, the spring stretches x = 0.29 m. While at this equilibrium position, the mass is then given an initial push downward at v = 5 m/s. The block oscillates on the spring without friction. 1) What is the spring constant of the spring? N/m Submit 2) What is the oscillation frequency? Hz Submit 3) After t = 0.45 s what is...

Consider two particles of mass m connected by a spring with rest length L with potential...

Consider two particles of mass m connected by a spring with rest length L with potential energy given by V(x1, x2) = ½ k (x1 – x2 – L)2. Show that the total wavefunction for this system is the product of two terms, one term is the solution for free particle motion of the center of mass for a particle with the total mass and the other term is simple harmonic (vibrational) motion of the relative displacement x1-x2 of the...

A 0.400kg0.400kg block is initially at rest on a horizontal surface, and is attached to an...

A 0.400kg0.400kg block is initially at rest on a horizontal surface, and is attached to an initially unstreteched spring with a force constant of 2.00N/m2.00N/m. The coefficient of kinetic friction between the block and the surface is 0.4000.400. A constant force of 2.30N2.30N to the right is applied to the block. (A) Draw a free body diagram showing all forces on the block as it moves to the right. Determine (B) the initial Kinetic Energy of the block:  J, and (C)...

A 0.400kg0.400kg block is initially at rest on a horizontal surface, and is attached to an...

A 0.400kg0.400kg block is initially at rest on a horizontal surface, and is attached to an initially unstreteched spring with a force constant of 2.00N/m2.00N/m. The coefficient of kinetic friction between the block and the surface is 0.4000.400. A constant force of 2.30N2.30N to the right is applied to the block. (A) Draw a free body diagram showing all forces on the block as it moves to the right. Determine (B) the initial Kinetic Energy of the block:  J, and (C)...

Answer questions 1-3 below, answer in SI units and include the (+/-) sign, please show work...

Answer questions 1-3 below, answer in SI units and include the (+/-) sign, please show work 1) Caesar drops a 3.9kg ball from a height of 4.2m. What is the work done by the force of gravity on the ball? 2) Caesar drops a 4.1kg ball from a height of 5.3m. What is the change in the gravitational potential energy? 3)Suppose you throw a ball upwards, and as you watch its trajectory, you wonder about the gravitational potential energy --...

1 point) Find the work done by F along different paths between (1,0,1) and (1,1,0). You...

1 point) Find the work done by F along different paths between (1,0,1) and (1,1,0). You might simplify your computation by writing F=G+H=∇g+H, so that you have a decomposition ofFF into a conservative vector field and a simpler non-conservative vector field. F=〈e^(yz)+2y, xze^(yz)+zcos(y)−3z, xye^(yz)+sin(y)−2x〉 (a) The path is the straight line path between those two points. (Hint: the answer is not 2, 4, or 0.) Work is  . (b) The path consists of the line segment from (1,0,1) to the origin,...

For a helium cation (1 electron, 2 protons) in the lowest energy form: a. What orbital...

For a helium cation (1 electron, 2 protons) in the lowest energy form: a. What orbital is the electron in? b. What are the quantum numbers equal to? How many nodes are there? c. What is the equation for the wavefunction? d. What is the potential energy equal to? (your answer will be in terms of r) e. What is the energy, assuming RHe=2RH ? f. Write out the complete Shrödinger equation. (don't solve) g. Can this be solved? Explain