How are wavelength and frequency related?
As wavelength increases frequency increases.
b. As wavelength decreases frequency decreases.
As wavelength increases frequency decreases.
d. None of the above

Explanation:

Lodestone am iron were the only known magnetic materials in Gilbert's day, and his task was to investigate magnetism. Gilbert was so sure that the earth was a giant lodestone and used the earth as a primary reference, defining the north(magnetic) pole of a needle, or a a nail floating on a piece of cork, to be that which turns towards the Earth's north geographic pole. he wanted to prove this with a model Terella, using short pieces of iron.

This question is incomplete, the complete question is;

An electron moving along the x axis has a position given by x = 16 t[tex]e^{-t}[/tex] m, where t is in seconds. How far is the electron from the origin when it momentarily stops

Answer:

the electron is 5.88 m far from the origin when it momentarily stops

Explanation:

Given that;

the position of the electron is x =  16 t[tex]e^{-t}[/tex] m

now, if the electron stopped after a time t, then its velocity is zero

so

V = dx/dt = 0

d/dt( 16 t[tex]e^{-t}[/tex] m) = 0

16( -t[tex]e^{-t}[/tex] + [tex]e^{-t}[/tex] ) = 0

16(-t + 1) [tex]e^{-t}[/tex] = 0

16(1 - t) [tex]e^{-t}[/tex] = 0

1 - t = 0

t = 1 sec

so

x = 16 × 1 × [tex]e^{-1}[/tex] m

x = 16 × 1 × 0.36787 m

x = 5.88 m

Therefore, the electron is 5.88 m far from the origin when it momentarily stops

Answer:

q = 2.066* 10⁻¹³ C.

n = 1,291,250 electrons.

Explanation:

1)

       [tex]F_{g} = F_{c} (1)[/tex]

       [tex]F_{g} = G*\frac{m_{1}*m_{2}}{r_{12}^{2}} (2)[/tex]

       [tex]F_{c} = k*\frac{q_{1}*q_{2}}{r_{12}^{2}} (3)[/tex]

       [tex]G*\frac{(0.0024kg)^{2}}{r_{12}^{2}} = k*\frac{Q^{2}}{r_{12}^{2}} (4)[/tex]

       [tex]Q^{2} = \frac{6.67e-11*(0.0024kg)^{2}}{9e9Nm2/C2} = 4.27*e-26 C2 (5)[/tex]

2)

Answer: The correct option is A.

Move toward X but not rotate

Explanation:

This is because from the question, X is fixed and y is free to move. Since magnetic dipole of X is fixed, that is it can't move and that of y is free to move, therefore y will move toward x because it's forces of attraction is linear and not rotational and besides X and Y are on a linear path, therefore Y will move towards X that is fixed and it will not rotate since it's linear.

Answer:

4th ans

Explanation:

Answer:

System

Explanation:

A system is an object or group of objects that we wish to consider for a physics problem. Examples of systems are universe, house and its surroundings etc.

There are three different types of systems which are:

Answer:

20 C to F

Ans: 68F

-40 C to F

Ans:-40F

40C to F

Ans:104F

Answer:

s = 52.545 m

Explanation:

First, we calculate the distance covered during the 0.5 s when the driver notices the light and applies the brake.

[tex]s_{1} = vt\\[/tex]

where,

s₁ = distance covered between noticing light and applying brake = ?

v = speed = 18.6 m/s

t = time = 0.5 s

Therefore,

[tex]s_{1} = (18.6\ m/s)(0.5\ s)\\s_{1} = 9.3\ m\\[/tex]

Now, we calculate the distance for the car to stop after the application of brakes. For that we use 3rd equation of motion:

[tex]2as_{2} = V_{f}^{2} - V_{i}^{2}\\\\[/tex]

where,

s₂ = distance covered after applying brake = ?

a = deceleration = - 4 m/s²

Vf = final speed = 0 m/s

Vi = initial speed = 18.6 m/s

Therefore,

[tex]2(- 4\ m/s^{2})s_{2} = (0\ m/s)^{2} - (18.6\ m/s)^{2}\\\\s_{2} = \frac{(18.6\ m/s)^{2})}{8\ m/s^{2}}\\\\s_{2} = 43.245\ m[/tex]

So the total distance covered by the car before stopping is:

[tex]s = s_{1} + s_{2}\\s = 9.3\ m + 43.245\ m\\[/tex]

s = 52.545 m

Answer:

1.19m

Explanation:

Given parameters:

Speed of the trumpet sound  = 351m/s

Frequency of the note = 294Hz

Unknown:

Wavelength of the sound  = ?

Solution:

To solve this problem, we use the wave - velocity equation.

    V  = F x ∧  

V is the velocity of the body

F is the frequency

∧ is the wavelength

 So;

          351   = 294 x ∧  

       ∧   = [tex]\frac{351}{294}[/tex]   = 1.19m

Answer:

1.5m/s

Explanation:

Given parameters:

M1  = 75kg

V1  = 4m/s

M2  = 125kg

V2  = 0m/s

Unknown:

Final velocity of the two objects  = ?

Solution:

To solve this problem, we must understand that this is an inelastic collision. To conserve momentum;

          M1 V1   + M2 V2  = V (M1 + M2)

       ( 75 x 4 )  +  ( 125 x 0)   = V (75 + 125)

                   300  = 200V

                     V  = 1.5m/s

Answer:

It will take 29.31 seconds for the Boxster to catch the Scion

Explanation:

Given the data in the question;

lets say Toyota Scion xB is car A and Porsche Boxster convertible is B and Toyota Scion xB is car A

the distance travelled by car A is

x = [tex]V_{A}[/tex] × t

where  [tex]V_{A}[/tex] is the speed of the car and t is time

the distance travelled by car B before reaching car A will be;

x + x₀ = [tex]V_{B}[/tex] × t

Now lets replace x by [tex]V_{A}[/tex] × t

so

([tex]V_{A}[/tex] × t) + x₀ = [tex]V_{B}[/tex] × t

x₀ = ([tex]V_{B}[/tex] × t) - ([tex]V_{A}[/tex] × t)

x₀ = t ([tex]V_{B}[/tex] - [tex]V_{A}[/tex])

t = x₀ /  ([tex]V_{B}[/tex] - [tex]V_{A}[/tex])

so we substitute

t = 170 m  /  (24.4 - 18.6)  

t = 170 / 5.8

t = 29.31 s

Therefore; it will take 29.31 s for the Boxster to catch the Scion

Answer:

A

Explanation:

Answer:

A) a = 5.673 m/s²

The direction will be upwards vertically towards the point where it is suspended.

B) T = 113.2 N

Explanation:

A) We are given;

Weight of bowling ball; W = 71.7 N

Speed; v = 4.6 m/s

Rope length; r = 3.73 m

Now, formula for the centripetal acceleration is;

a = v²/r

Thus; a = 4.6²/3.73

a = 5.673 m/s²

The direction will be upwards vertically towards the point where it is suspended.

B) since weight is 71.7 N, it means that;

Mass = weight/acceleration = 71.7/9.8

Mass(m) = 7.316 kg

Thus,

Centripetal force is;

F_cent = 7.316 × 5.673

F_cent = 41.5 N

Thus, Tension in the rope is;

T = W + F_cent

T = 71.7 + 41.5

T = 113.2 N

Answer:

The raft moves towards the shore

Explanation:

Answer:

(A) J = -10.57 kg-m/s   (B) 17.61 N

Explanation:

Given that,

Mass of a volleyball, m = 0.263 kg

Initial speed of volleyball, u = 17.4 m/s

Final speed of volleyball, v = -22.8 (in opposite direction)

(a) We need to find the impulse delivered to the ball by the player.

Impulse = change in momentum

J = m(v-u)

Put all the values,

J = 0.263(-22.8-17.4) kg-m/s

= -10.57 kg-m/s

(b) The time of contact with the ball, t = 0.6 s

We need to find the magnitude of the average force exerted on the players first.

Impulse, J = Ft

[tex]F=\dfrac{J}{t}\\\\F=\dfrac{10.57 }{0.6}\\\\F=17.61\ N[/tex]

So, the magnitude of the average force exerted on the player is 17.61 N.

Answer:

 the statement is False       [tex]\frac{x_{ball} }{ x_{rec} }[/tex] = cos θ

Explanation:

Let's analyze this problem, the ball and the receiver leave the same point and we want to know if at the same moment they reach the same point, for this we must have both the ball and the receiver travel the same distance.

Let's start by finding the time it takes for the ball to reach the ground

        y = [tex]v_{oy}[/tex] t - ½ g t²

when it reaches the ground its height is y = 0

       0 = vo sin θ  - ½ g t²

       0 = t (vo sin θ - ½ g t)

The results are

       t = 0                             exit point

       t = 2 v₀ sin θ/g            arrival point

at this point the ball traveled

       [tex]x_{ball}[/tex]= v₀ₓ t

       x_{ball} = v₀ cos θ  2v₀ sin θ / g

       x_{ball}= 2 v₀² cos θ   sin θ/ g

Now let's find that distantica traveled the receiver in time

        [tex]x_{rec}[/tex] = v₀ t

        x_{rec} = v₀ (2 v₀ sin θ / g)

        x_{rec} = 2 v₀² sin θ / g

without dividing this into two distances

          [tex]\frac{x_{ball} }{ x_{rec} }[/tex] = cos θ

therefore the distances are not equal to the ball as long as behind the receiver

Therefore the statement is False

Answer:

False

Explanation:

Answer:

False

Explanation:

Answer:

Kinetic energy =1/2mv^2

Where m is the mass of the object. V is the velocity

K.E=0.5(8*5^2)

K.E=100J

Explanation:

Answer:

Explanation:

The skaters in a circle of radius; R = L/2

R = 3.2/2 = 1.6 m

From Ii*Wi = If*Wf

Note; i is initial while f is final

Answer:

Gravity only becomes noticeable when there is a really massive object like a moon, planet or star. We are pulled down towards the ground because of gravity. The gravitational force pulls in the direction towards the centre of any object.

Answer:

20.41 s

3534.80 m

Explanation:

In how many seconds will it reach the ground?

We are given the initial velocity of the body, which is 200 m/s at a 30° angle.

We know the acceleration in the vertical direction is -9.8 m/s², assuming that the upwards/right direction is positive and the downwards/left direction is negative.

Since we are using acceleration in the y-direction, let's use the vertical component of the initial velocity.

Let's use the fact that at the top of its trajectory, the body will have a final velocity of 0 m/s.

Now we have one missing variable that we are trying to solve for: time t.

Find the constant acceleration equation that contains v₀, v, a, and t.

Substitute known values into the equation.

Recall that this is only half of the body's trajectory, so we need to double the time value we found to find the total time the body is in the air.

The body will reach the ground in 20.41 seconds.

How far from the point of projection would it strike?

We want to find the displacement in the x-direction for the body.

Let's find the constant acceleration equation that contains time t, that we just found, and displacement (Δx).

Substitute known values into the equation. Remember that we want to use the horizontal component of the initial velocity and that the acceleration in the x-direction is 0 m/s².

The body will strike 3534.80 m from the point of projection.

Answer:

1200N/m

Explanation:

Given parameters:

Force on the motorcycle spring = 240N

Extension  = 2cm or 0.02m

Unknown:

Spring constant  = ?

Solution:

To a spring the force applied is given as :

       F  = K e

F is the applied force

K is the spring constant

e is the extension

              240  = k x 0.02

                 k  = 1200N/m

Answer:

The impulse is 90Ns.

Explanation:

Given that the formula for impulse is F×t, where F represents force and t is time (in seconds) :

Impulse = F × t

Impulse = 30 × 3 = 90Ns

Answer:

64.2 m/s

Explanation:

We are given that

Speed ,v=38 m/s

We have to find the maximum speed when his car reach on flat ground.

Using dimensional analysis

[tex]F_{res}\propto v^2[/tex]

If 35% acceleration reduced by F(res) at 38 m/s

Then, 100% acceleration  can be reduced  by F(res) at v' m/s

[tex]\frac{F_1}{F_2}=\frac{v^2}{v'^2}[/tex]

[tex]v'^2=\frac{F_2}{F_1}v^2[/tex]

[tex]v'=v\sqrt{\frac{F_2}{F_1}}[/tex]

Substitute the values

[tex]v'=38\times \sqrt{\frac{100}{35}}[/tex]

[tex]v'=64.2 m/s[/tex]

Hence, the maximum speed when his car can reach on flat ground=64.2 m/s

The maximum velocity of the car at constant acceleration on the road will be 62.2 m/s.

The air resistance is directly proportional to the square of the velocity of an object.

R ∝ v²

The speed of the car was reduced by 35 % at 38 m/s.

So, the speed of the car was reduced by 100% at v' m/s.

The relationship can be given by,

[tex]\dfrac {R_1}{R_2} = \dfrac {v^2}{v'^2}[/tex]

Put the values in the formula and calculate for [tex]v'[/tex],

[tex]v' = \sqrt {\dfrac {R_2 v^2}{R_1 }}[/tex]

[tex]v' = \sqrt {\dfrac { 100\times 38 ^2}{35 }}\\\\v' = 62.2 \rm \ m/s[/tex]

Therefore, the maximum velocity of the car at constant acceleration on the road will be 62.2 m/s.

Learn more about resistance and speed?

https://brainly.com/question/11574961

Answer:

A. the tendency of moving objects to stay in motion

Answer:

atmosphere

Explanation:

.........,....

Answer:

Risk rejection

Explanation:

There are several factors that contribute to the degree of driving risks and they include but not limited to the ability of the driver and the condition of a vehicle. Other factors are condition of the environment and the condition of the highway. When driving, a driver may wait until an oncoming vehicle passes before making a complete left turn as a risk rejection strategy. Left turns are more dangerous when making them because drivers tend to accelerate on to a left turn. The wider radius of a  left turn is know to led to higher speeds and greater pedestrian exposure. A driver is advised to have more mental and physical efforts when making a left turn.