A 1.0 kg mass at the end of a spring has an amplitude of 0.10 m and vibrates 2.0 times per second. What is its velocity when it is 0.10 m from equilibrium.

Answer:

B: A  material with relatively weak bonds between it's particle can be shped in to a thin sheet.

Explanation:

Answer:

It simply means that the longest side of the object is 4 m that is 400cm..

Explanation:

___________

Answer:

The temperature will decrease (get colder).

Explanation:

Enthalpy changes are heat changes accompanying physical and chemical changes. The enthalpy change is the difference between the sum of the heat contents of products and the sum of heat contents of reactants.

Answer:

hello the diagram related to this question is missing attached below is the missing diagram

Answer :

The magnitude of the electric field = 4KQ / L^2

direction = 45° east to south

Explanation:

The magnitude of the electric field = 4KQ / L^2

direction = 45° east to south

Answer:

earth

Explanation:

its the only planet.

Answer:

E = 16.464 J

Explanation:

Given that,

Mass of tetherball, m = 0.8 kg

It is hit by a child and rises 2.1 m above the ground, h = 21. m

We need to find the maximum gravitational potential energy of the ball. The formula for the gravitational potential energy is given by :

E = mgh

g is acceleration due to gravity

E = 0.8 kg × 9.8 m/s² × 2.1 m

= 16.464 J

So, the maximum potential energy of the ball is 16.464 J.

Given that,

Mass of a ball = 300 kg

To find,

The gravitational force acting on the ball.

Solution,

The force acting on the ball is force of gravity. It is equal to the weight of the ball.

W = mg

Substitute the value of m and g in the above formula

W = 300 kg × 10 m/s²

= 3000 N

Therefore, the ball attracts with a force of 3000 N.

Answer:

Length of pipe 0.5m

Explanation:

Step one

Given data

fundamental frequency of 320 Hz

n=1

Velocity v=334m/s

Note: the subsequent frequency of sound are a multiple of it fundamental frequency

Step two

Applying the formula we have

Fn=nv/2l

Substitute

320=1*334/2L

Cross multiply

320*2L=334

640L=334

Divide both sides by 640

L=334/640

L=0.5m

Answer:

The apple travels at 3.6 m/s

Explanation:

The Law Of Conservation Of Linear Momentum

The total momentum of a system of bodies is conserved unless an external force is applied to it.

The formula for the momentum of a body with mass m and speed v is:

P = mv

If we have a system of two bodies the total momentum is the sum of the individual momentums:

[tex]P=m_1v_1+m_2v_2[/tex]

If a collision occurs and the velocities change to v', the final momentum is:

[tex]P'=m_1v'_1+m_2v'_2[/tex]

Since the total momentum is conserved, then:

P = P'

Or, equivalently:

[tex]m_1v_1+m_2v_2=m_1v'_1+m_2v'_2[/tex]

Solving for v2':

[tex]\displaystyle v'_2=\frac{m_1v_1+m_2v_2-m_1v'_1}{m_2}[/tex]

The arrow has a mass of m1=0.2 kg and travels at v1=32.2 m/s. It hits an apple (assumed stationary at v2=0) of mass m2=0.77 kg and continues through the apple with a speed of v1'=18.3 m/s. We'll calculate the speed of the apple after the hit.

[tex]\displaystyle v'_2=\frac{0.2*32.2+0.7*0-0.2*18.3}{0.77}[/tex]

[tex]\displaystyle v'_2=\frac{2.78}{0.77}[/tex]

[tex]v'_2=3.6 \ m/s[/tex]

The apple travels at 3.6 m/s

Answer:

m = 3.9 [m³]

Explanation:

We must remember that the density of the substance is defined as the relationship between mass over volume. That is expressed in the following equation:

[tex]Ro = m/V[/tex]

where:

Ro = density = 1.3 [kg/m³]

m = mass [kg]

V = volume = 3 [m³]

Now replacing the values.

[tex]m =Ro*V\\m = 1.3*3\\\\m=3.9[m^{3}][/tex]

Answer:

The cyclist's average speed is 13.43 [tex]\frac{km}{h}[/tex]

Explanation:

Speed ​​is a quantity that expresses the relationship between the space traveled by an object and the time used for it. That is, speed is the magnitude that expresses the variation in position of an object and as a function of time, which would be the same as saying that it is the distance traveled by an object in the unit of time.

Average speed relates the change in position to the time taken to effect that change:

[tex]speed=\frac{change in position}{time} =\frac{distance}{time}[/tex]

In this case:

Replacing:

[tex]speed=\frac{47 km}{3.5 h}[/tex]

and solving, you get:

speed= 13.43 [tex]\frac{km}{h}[/tex]

The cyclist's average speed is 13.43 [tex]\frac{km}{h}[/tex]

Answer:

243.75kJ

Explanation:

Step one:

Given parameters

Height= 39meters

mass= 625g

g= 10m/s

Required

The potential energy PE

Step two:

the expression for the potential energy is given as

PE=mgh

PE=625*10*39

PE=243750 J

PE=243.75kJ

free lil peezy and drake is kool

Answer:

For constant traveled distance and applied forces, apply the for parallel to the direction of the movement.

Explanation:

[tex]W = F.d = |F||d|cos(\theta)\\[/tex]

There are 3 components in the amount of work produced when applying a force to an object.

1. The amount of force applied

2. The distance that the object is traveled

3. The angle between the force vector and the distance vector

Answer:

I can't see the picture

Explanation:

Answer:

[tex]s=-38.332m[/tex]

Explanation:

From the question we are told that

Cylinder of mass [tex]m=2.90 kg[/tex]

Radius [tex]R=30.0 m[/tex]

Mass of bucket [tex]M_b= 1.90 kg[/tex]

Fall time [tex]T_f= 3.70 seconds[/tex]

Generally the tension the bucket is mathematically given by

[tex]T-mg=ma[/tex]

For cylinder

 [tex]T=I*\alpha[/tex]

 where

[tex]I=1/2mR^2[/tex]

[tex]a=R*\alpha[/tex]

Giving

[tex]T=-1/2mR\alpha[/tex]

Therefore

[tex]a=\frac{-mg}{m+1/2m}[/tex]

[tex]a=\frac{-(1.9*9.81)}{1.9+0.5*(2.9)}[/tex]

[tex]a=-5.563880597 \approx -5.6m/s^2[/tex]

Generally the Newton's equation for motion is mathematically represented as

 [tex]s=ut+1/2at^2[/tex]

 [tex]s=0(3)+1/2*-5.6*(3.7)^2[/tex]

[tex]s=-38.332m[/tex]

Answer:

10.5min

Explanation:

Given parameters:

Distance  = 4200m

Speed  = 400m/min

Unknown:

Time taken for this run  = ?

Solution:

Speed is the distance divided by the time taken.

   Speed  = [tex]\frac{distance }{time }[/tex]  

  Time  = [tex]\frac{distance}{speed }[/tex]  

 Now insert the parameters and solve;

 Time  = [tex]\frac{4200}{400}[/tex]   = 10.5min

Answer:

Condensation

Explanation:

Increased pressure is called condensation or compressions because they are regions of high air pressure whilst rarefractions are low air pressure.

We have that the work the engine did is

w=1710000J

From the Question we are told that

Power  P=190,000 W

T= 9 s

Generally the equation for the work   is mathematically given as

[tex]w=pt\\\\w=190,000*9s\\\\w=1710000J[/tex]

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Answer:

I believe its the blue, sorry if I'm wrong

Answer:

1. Divide the weight by speed of the people pushing it to get net force

2. Whether one side of the object is pushing harder or not you will get ur answer, for example if the left side is pushing 3 newtons to the right and the right side pushing 5 newtons to the left, the net force would be 2 newtons of force pushing left and if its an even amount of force then it will be 0

3. If one side of an object pushes harder than the other side, then the object will move in favor of the one who is pushing harder.

4. 200 newtons or 200N

Explanation:

Explanation:

In a chemical reaction, when mass is conserved , the number of atoms or moles of the reactants must be equal to the number of moles or atoms in the products side.

From the diagram, we should carefully look to see if the number of atoms that makes up the reactants are equal to those on the product side.

 For example:

      A + B → AB

Here, mass is conserved because, on the reactant side, we have 1 atom of A and on the product side we have 1 atom of A

For B, on the reactant side, we have 1 atom of B and on the product side, we have 1 atom of B.

Answer:

Yes, because the number of each type of atom is the same in the products as it is in the reactants.

Explanation:

Answer:

When the student slides the rock along the flat surface of the frozen pond, according to Newton's second law of motion, the rock is given an initial velocity of motion. According to Newton's first law of motion, the rock will continue to slide indefinitely unless it is slowed or stopped by an opposite force. According to Newton's third law, the rock experiences a reaction force from the force of friction of the ice which slows it down at a rate given by Newton's second law of motion and the rock is seen to decelerate

Explanation:

Newton's first law of motion, states that an object will remain at rest or maintain a uniform motion in a straight line, unless impressed upon by an external force

Newton's second law states that an applied force is equal to the rate of change of momentum it produces

Newton's third law states action and reaction are equal and opposite.

Answer:

117 kg

Explanation:

Step one:

given data

time t= 6.5s

velocity v= 30m/s

Force F= 540N

Required

the mass m

Step two:

Recall from the expression

Ft= mv

make m subject of the formula

m= Ft/v

substitute

m= 540*6.5/30

m=3510 /30

m=117 kg

Answer:

joules

Explanation:

The electric energy transferred to a resistor in a time period is equal to the electric power multiplied by time, E=Pt, and can also be calculated using E=I2Rt. Electric companies measure their energy sales in a large number of joules called a kilowatt hour (kWh) which is equivalent to 3.6×106 J.

Answer:

Not accounting for friction, the ball would be falling at 14.0 m/s

Explanation:

Without a coefficient of kinetic friction being provided, we'll have to assume zero friction between the ball and the air.

In that case, the ball's horizontal speed will remain 10 m/s.  To find it's velocity in five seconds then, we just need to take gravity into account.

Let's assume acceleration from gravity is 9.8 m/s².  We can simply multiply that by five seconds to find out how fast it's going at that point:

[tex]9.8\frac{m}{s^2} \times 5s\\= 49 \frac{m}{s}[/tex]

So at five seconds, the ball is moving horizontally at 10 m/s and vertically at 479 m/s.

Now we can simply take the hypotenuse between those two vectors to get the actual speed:

[tex]s = \sqrt{9.8^2 + 10^2}\frac{m}{s}\\s = \sqrt{96.04 + 100}\frac{m}{s}\\s = \sqrt{196.04}\frac{m}{s}\\s = 14.0 \frac{m}{s}\\[/tex]

So lacking air to slow it down, the ball would be going at approximately 14.0 metres per second.

Answer:

wave D has higher frequency then wave c

wave C has longer wavelength

wave D has a higher pitch

Explanation:

Answer: Isn't frequency the amount of times something happened? So I'd say A also E

Explanation:

(Don't rely I'm not that smart)