Show that the Hooke’s law potential gives us Kepler’s second law, constant areal velocity.

(a) Show that Kelper’s second law (i.e. law of equal areas) is equivalent to the statement...

(a) Show that Kelper’s second law (i.e. law of equal areas) is equivalent to the statement of conservation of angular momentum. (b) Assuming circular orbits, show that Kepler’s third law (i.e. law of periods) is implied by Newton’s law of gravitation.

The answer regarding the Business Law What is supremacy Clause? What understanding it gives to us...

The answer regarding the Business Law What is supremacy Clause? What understanding it gives to us regarding constitution of US? Why “duty of care” makes the essential element in the cases relating to tort?

Show that the Kelvin-Planck and the Clausius expressions of the second law are equivalent.

Show that the Kelvin-Planck and the Clausius expressions of the second law are equivalent.

Curie-Weiss law: Derive the Curie-Weiss law (8.44) and show that the Curie constant C corresponds to...

Curie-Weiss law: Derive the Curie-Weiss law (8.44) and show that the Curie constant C corresponds to that in the Curie law (8.29).

Pls, show answer legible. 1. If a tire rolls with a constant velocity westward, in what...

Pls, show answer legible. 1. If a tire rolls with a constant velocity westward, in what direction is its angular velocity? Describe your method for finding this. 2. Can angular velocity have more than one component? Give an example to support your answer. 3. Is the direction of the angular velocity of the earth towards the North Pole, toward the South Pole, or neither of these? Explain.

We can derive the potential energy stored in an ideal spring when it is stretched or...

We can derive the potential energy stored in an ideal spring when it is stretched or compressed by computing the work done due to Hooke’s law. In this experiment we will be working with springs. When they are not being stretched by some external force, the coils of these springs are held tightly together by the spring’s rigidity. They are held so tightly that a small amount of weight can be hung from these springs, and they don’t stretch at...

Classical Mechanics - Let us consider the following kinetic (T) and potential (U) energies of a...

Classical Mechanics - Let us consider the following kinetic (T) and potential (U) energies of a two-dimensional oscillator : ?(?,̇ ?̇)= ?/2 (?̇²+ ?̇²) ?(?,?)= ?/2 (?²+?² )+??? where x and y denote, respectively, the cartesian displacements of the oscillator; ?̇= ??/?? and ?̇= ??/?? the time derivatives of the displacements; m the mass of the oscillator; K the stiffness constant of the oscillator; A is the coupling constant. 1) Using the following coordinate transformations, ?= 1/√2 (?+?) ?= 1/√2...

Finding the Spring Constant We can describe an oscillating mass in terms of its position, velocity,...

Finding the Spring Constant We can describe an oscillating mass in terms of its position, velocity, and acceleration as a function of time. We can also describe the system from an energy perspective. In this experiment, you will measure the position and velocity as a function of time for an oscillating mass and spring system, and from those data, plot the kinetic and potential energies of the system. Energy is present in three forms for the mass and spring system....

Let us consider a particle of mass M moving in one dimension q in a potential...

Let us consider a particle of mass M moving in one dimension q in a potential energy field, V(q), and being retarded by a damping force −2???̇ proportional to its velocity (?̇). - Show that the equation of motion can be obtained from the Lagrangian: ?=?^2?? [ (1/2) ??̇² − ?(?) ] - show that the Hamiltonian is ?= (?² ?^−2??) / 2? +?(?)?^2?? Where ? = ??̇?^−2?? is the momentum conjugate to q. Because of the explicit dependence of...

Darcy's law gives us the volume flow rate-volume per time (for example, cubic meters per day,...

Darcy's law gives us the volume flow rate-volume per time (for example, cubic meters per day, m^3/day). Another way to express volume is on a per-unit-area basis. For example, if we have a 1-m^3 cube, we know its base is 1 m^2 the cross-sectional area of the cube-and its height is 1m. If we fill the cube with water, we can say we have 1m of water per unit area. Darcy's law can be rearranged to calculate the volume flow...