A block of mass m= 5.00-kg is moving to the right with a speed of v= 2.00 m/son a horizontal,frictionless surface. The block encounters a relaxed(that is, neither compressed nor extended)spring with spring constant k= 2,000.00 N/m.

a.What is the kinetic energy of the block before hitting the spring?

b.What is the kinetic energy of the block when the spring is at maximum compression?

c.How much energy is stored in the spring at maximum compression?

d.How far does the spring compress at its maximum compression?

e.If the spring converts its stored energy completely into motion of the block, what is the speedof the blockafter release from the spring?

f.(For this part of the problem,the surface is not frictionless) Suppose the speed of the block after release from the spring is 1.5 m/s to the left, how much work (sign and magnitude) was done by non-conservative forces between the time when the initial velocity is 2.00 m/s and the time when the velocity = -1.50 m/s?

A particle moves along a line with velocity function ?(?) = ?^2 − ?, where v is measured in meters per second. a. Find distance traveled by the particle in time interval [0, 6] seconds. b. Find the net displacement. 8. Estimate the area from -1 to 9 under the graph of f(x) = 81 – x^2 using five approximating rectangles and midpoints as sample points.

A) Which of the following sets of quantum numbers are valid (enter V) and which are invalid for the known elements? n = 2, l = 3, m_l = 0, m_s = +½ :

B) write the corresponding orbital notation for n = 6, l = 0?

A bullet of mass 148 g and a speed v impacts on a pendulum of mass 6.18 kg and length 200 cm. The bullet embeds itself in the pendulum bob. The pendulum then travels in a complete and perfect circle.

(a) If the pendulum is suspended by a light, stiff rod, what is the minimum speed of the bullet?


(b) If the pendulum is suspended by a string, what is the minimum speed of the bullet?

Calculate V and Z for methyl chloride at 100 ° C and 55bar for the ideal gas equation, by the equation of virial. Data: R = 83.14 cm 3 bar/molK; viral coefficient B equals -242.5 cm3/mol.

According to the case of Cobbs v. Grant, the court said there was not enough evidence to support a verdict of negligence, yet the original gastrectomy led to multiple hospital stays and two follow-up surgeries. These complications were known risks that can occur even if the surgeon performs the operation flawlessly. If you were the patient and knew about these risks, would you have decide to consent to the first surgery? What factors would you consider?

1. A vector, V, has a magnitude of 350 N and a direction of 55°.   Determine the following:
   1. V_x = ______
   2. V_y = ______

2. If V_x = 12 m and V_y = 17 m then determine the following:
   1. What is the magnitude, V, of this vector?
   2. What is the direction, θ, of this vector?

3. A hiker walks 2.5 km at an angle of 45 degrees north of west, and then hikes 4.0 km at an angle of 30 degrees north of east.    What is the displacement of the hiker from the origin (magnitude and direction)?   Determine the magnitude and direction by adding the vectors graphically and mathematically.   Be sure to attach your graph.

Magnitude (from graph): _______                                          Magnitude (mathematical) : ______

Direction (from graph):   _______                                             Direction (mathematical) : ______

4. A projectile is launched with a velocity of 130 m/s at an angle of 41 degrees (relative to the ground).   Determine the following:
   1. v_x = _____

2. v_y = _____

3. What is the maximum height of the projectile?

4. What is the range of the projectile?

5. Where is the projectile 4.0 s after it is launched?

6. If there was a 50 m high wall that is 1400 m away, would the projectile be able to clear this wall? Show why or why not.

5. If a river has a westward current of 1.30 m/s and you head due north across the river on a boat that has a speed of 1.5 m/s in still water, then what is speed of the boat relative to the shore?   At what angle does it cross the river?

An electron is placed in a region with a 1010 V/m electric field directed in the positive x-direction. The electron escapes this region after traveling 14.0 cm. What is the kinetic energy of the electron? What is the particle's velocity? Will a proton placed at the same initial position and traveling through a similar 14.0 cm path acquire the same amount of kinetic energy? Will the proton experience the same change in velocity? Why or why not?

I have seen this question on here before but the velocity portion was not present.

A 14.5-μF capacitor is charged to a potential of 40.0 V and then discharged through a 65.0­ Ω resistor.

1. How long after discharge begins does it take for the capacitor to lose 90.0% of its initial charge?

2. How long after discharge begins does it take for the capacitor to lose 90.0% of its initial energy?

3. What is the current through the resistor at the time when the capacitor has lost 90.0% of its initial charge?

4. What is the current through the resistor at the time when the capacitor has lost 90.0% of its initial energy?

Qn 1

A capacitor is attached to a battery with a terminal voltage of V. What happens to the capacitance of the capacitor if it is attached to a new battery with a terminal voltage of 2V, twice as large as the previous battery?

Question 2

A capacitor is attached to a battery with a voltage of V, and a charge Q is pulled from the battery and stored on the capacitor. If a second identical capacitor is attached in parallel with the first, how much total charge has now been pulled from the battery?

Question 3

A capacitor is attached to a battery with a terminal voltage of V. What happens to the charge on the the capacitor if it is attached to a new battery with a terminal voltage of 2V, twice as large as the previous battery?

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Question 4

Two identical capacitors with capacitance C are connected together in series. How does the capacitance of the combination compare to C?

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Question 5

When current flowing through a resistor increases, the voltage drop across the resistor must be

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Question 6

A certain wire made from a conducting material with resistivity ρ{"version":"1.1","math":"<math xmlns="http://www.w3.org/1998/Math/MathML"><mi>&#x3C1;</mi></math>"} has a certain length, L, and a certain diameter, D, giving it a resistance of R. If a second wire is made from a conductor with a resistivity that is twice as large, and the wire has a length of 2L and a diameter of 2D, how does the resistance of this wire compare to R?

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Question 7

A certain resistor is made of a semiconductor whose temperature coefficient of resistivity is negative. A constant voltage is applied to the resistor, but the resistor heats up significantly as current passes through the wire. What happens to the amount of current the resistor will carry?

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Question 8

A capacitor is attached in series to a resistor with a resistance R. The combination is connected to a battery and allowed to charge. After a certain amount of time, T, the capacitor has charged to 60% of its maximum value. If we repeat the experiment, but replacing the resistor with a new resistor of resistance 2R, what happens to the time it takes for the capacitor to charge to 60% of its maximum value again?

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Question 9

A resistor with a resistance of 3 Ohms is connected in parallel with a resistance with a resistance of 6 Ohms. What is the equivalent resistance of this combination?

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Question 10

In the diagram below, the current flowing through R1 is 0.3 Amps and the current flowing through R2 is 0.1 Amps. What is the current flowing through R3?

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