3. Coyotes and rabbits that live in the same area
a. are in direct competition with each other.
b. have a predator-prey relationship.
C. belong to the same population.
d. have the same niche.
Plz helppopo

The size of the impulse exerted on the ball is 5.4 kg m/s

Explanation:

The impulse exerted on an object is equal to the change in momentum of the object itself:

[tex]I=\Delta p = m(v-u)[/tex]

where:

I is the impulse

m is the mass of the object

v is the final velocity of the object

u is its initial velocity

In this problem, we have:

m = 0.12 kg is the mass of the ball

u = 45 m/s is the initial velocity of the ball

v = 0 is the final velocity (the ball is brought to rest)

Substituting into the equation, we find the impulse:

[tex]I=(0.12)(0-45)=-5.4 kg m/s[/tex]

where the negative sign means that the direction of the impulse is opposite to the initial direction of motion of the ball. Therefore, the size of the impulse is

[tex]I=5.4 kg m/s[/tex]

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Explanation:

Earwax helps to protect your ears from infection so if you like chewing gum, this helps in removing the wax. But this might not happen at your young age. So if you grow and still likes chewing gum it will remove the wax completely thereby leading to loss on hearing

Answer:

5 x 10^8 W

Explanation:

Power = Energy ÷ time

given

Energy = 3 x 10^10J

time = 1 min = 60 s

Power = Energy ÷ time

= 3 x 10^10 ÷ 60

=  5 x 10^8 W

Final answer:

The power output of the steam turbine that does 3 × 10^10 joules of work in 1 minute is 500 megawatts.

Explanation:

The student asked about the power output of a steam turbine that does 3 × 10^10 joules of work in 1 minute. To determine the power output, we use the formula Power = Work / Time. The work done is 3 × 10^10 joules, and the time is 1 minute, which is 60 seconds. Therefore, the power output is:

Power = 3 × 10^10 J / 60 s = 5 × 10^8 watts or 500 megawatts.

This indicates that when functioning as a generator, this turbine can generate 500 megawatts of power.

Answer:

No Refraction takes places

Explanation:

When light travels from one medium to another at an angle of incidence 0 degree then no refraction takes place .

It is because according to Refraction law

                    [tex]n_{i}[/tex]sini = [tex]n_{r}[/tex]sinr

where [tex]n_{i} ,n_{r}[/tex] are the refractive index of medium of incidence and medium of refraction .

When i = 0 , left side of the equation becomes 0 and thus r (angle of refraction) must be zero. So No refraction takes place

Answer:

If the index of refraction of the medium is greater, the light slows down.

It is TRUE that earth's early atmosphere is almost unrecognizable compared to the atmosphere around us now

Explanation:

The early atmosphere of earth was mainly composed of carbon dioxide (up to 200 times more than current levels), methane, ammonia, and hydrogen sulfide. Most of the atmosphere was mainly created from gases spewed up into the atmosphere by volcanic eruptions. This was approximately 4.6 billion years ago.

However, an event referred to as the Great Oxygenation Event (about 2.6 billion – 400 million years ago ) changed the composition of the atmosphere. This was due to the evolution of photosynthetic organism that took up most of the carbon dioxide from the atmosphere and evolved out oxygen. The oxygen oxidized a lot elements, minerals and compounds in the atmosphere (including methane) and on the crust surface (such as iron). This changed, drastically, the composition of the earth's atmosphere.

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Answer:

Momentum: It is the quantity of motion of a moving body, measured as a product of its Mass and Velocity.

Explanation:

Definition of momentum :

Momentum is the quantity of motion of a moving body, measured as a product of its Mass and Velocity.

For example:

A bowling ball of large mass moving very slowly can have the same momentum as a cricket ball of small mass that is thrown with a very high velocity

Answer:

5000ml is the answer

Explanation:

multiply 5 time 1000

Answer:

The radiant energy is converted into electronic energy before it is transformed into thermal energy.

Explanation:

Radiant energy occurs in the form of "Electromagnetic radiation" and it can pass through all types of matter travelling through the universe. There are numerous advantages of radiant energy. When the radiant energy is incident upon a substance the energy from the sun light excites the electrons in the atom. This sets the atoms in vibrational motion.

Thermal energy is the kinetic energy of moving particles. The thermal energy increases with increase in movement and number of moving particles. When the atoms make a transition from electronically excited state to vibrational state, the energy transfer increases the temperature of the substance. This is felt as thermal energy. Hence, the radiant energy is changed into "electronic energy" before it is converted into "thermal energy".

A conservative force is a force that when work is done against this force the work done does not depend on the path taken only the initial and final position.

Answer:

True

Explanation:

Answer:

starting point you choose to describe the location, or position, of an object. A description of position depends on a reference point because if the reference point changes than the distance and direction can change. Before the weight was moving two forces were acting on it.ation:

The CORRECT answer is TRUE.

The average velocity is 20 km/h west

Explanation:

The velocity of an object is given by:

[tex]velocity = \frac{d}{t}[/tex]

where

d is the displacement

t is the time elapsed

The displacement of an object is a vector connecting the initial position and the final position of motion.

In this problem, the car moved

40 km East

80 km West

Therefore, the displacement is given by (taking West as positive direction)

[tex]d=80 km - 40 km = 40 km[/tex] West

The time elapsed is

t = 2 h

Therefore, the average velocity is

[tex]v=\frac{40 km}{2h}=20 km/h[/tex] in the West direction.

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Final answer:

The average velocity of the car is -20 km/h toward the West, calculated by dividing the net displacement (-40 km) by the total time (2 hours).

Explanation:

To find the average velocity of the car, we need to consider the total displacement and the total time. Displacement is the change in position of the car, and since velocity is a vector quantity, it also includes direction. The car first moves 40 km East and then 80 km West, resulting in a total displacement of 40 km East - 80 km West = -40 km (where negative indicates the direction West).

The total time taken is 2 hours. Therefore, the average velocity v is calculated as:

v = Total Displacement / Total Time = -40 km / 2 hours = -20 km/h

The negative sign indicates that the average velocity is directed toward the West.

To find the work needed to accelerate the crate from 5.000 m/s to 10.00 m/s, we calculate the change in kinetic energy, which comes out to be 187.5 J when rounded to the nearest tenth.

To determine the work done on the crate, we can use the work-energy principle which states that the work done on an object is equal to the change in its kinetic energy. The kinetic energy (KE) of an object is given by the equation KE = ½mv², where m is the mass and v is the velocity.

First, we calculate the initial kinetic energy (KEi) using the initial speed of 5.000 m/s:

KEi = ½ × 5.000 kg × (5.000 m/s)² = ½ × 5.000 × 25.00 = 62.50 J

Next, we calculate the final kinetic energy (KEf) using the final speed of 10.00 m/s:

KEf = ½ × 5.000 kg × (10.00 m/s)² = ½ × 5.000 × 100.0 = 250.0 J

The work done (W) on the crate is the change in kinetic energy, so:

W = KEf - KEi = 250.0 J - 62.50 J = 187.5 J

Therefore, the amount of work needed to accelerate the crate is 187.5 J, which can be rounded to the nearest tenth of a joule as 187.5 J.

Final answer:

The amount of work needed to accelerate the crate is 187.5 Joules (to the nearest tenth of a joule).

Explanation:

The amount of work needed to accelerate the crate can be calculated using the formula:

Work = Change in kinetic energy

First, calculate the initial kinetic energy:

Kinetic energy = (1/2) * m * v^2

= (1/2) * 5.000 kg * (5.000 m/s)^2

= 62.5 Joules

Next, calculate the final kinetic energy:

Kinetic energy = (1/2) * m * v^2

= (1/2) * 5.000 kg * (10.00 m/s)^2

= 250 Joules

Finally, calculate the change in kinetic energy:

Change in kinetic energy = Final kinetic energy - Initial kinetic energy

= 250 Joules - 62.5 Joules

= 187.5 Joules

Therefore, the amount of work needed to accelerate the crate is 187.5 Joules (to the nearest tenth of a joule).

The eyes creates an image by focusing light on the retina.

The retina is the light sensitive part of the eyes. Images are formed when light is focused on the retina. The light sensitive nerve endings that are connected to the optic nerve conveys visual information to the brain.

Hence, the lens of the eye creates an image by focusing light on the retina of the eye.

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The periodic table arranges element by increasing atomic number

Answer:

first law: an object remains in uniform motion except an external force has acted upon it eg a ball in stable motion doesn't move until one moves or kicks it

second law:the body acted upon by an external force gains a momentum which is directly proportional to the applied force and acts in the direction of the force

third law: to every action there is an equal and opposite reaction eg if u push someone the person moves backward away from you and not towards you

Answer:

Newton's Second law of motion: "Force = mass × acceleration."

Newton's Third law of motion: "Every action has an equal and opposite reaction."

Explanation:

An example of Newton's third law is when a rocket is launched, the boosters apply force on the ground and the ground pushes back, which makes the rocket take off.

"When an object A exerts a force (called action) on an object B, then object B exerts an equal and opposite force (called reaction) on object A"

Explanation:

Newton's third law of motion states that:

"When an object A exerts a force (called action) on an object B, then object B exerts an equal and opposite force (called reaction) on object A"

it is important to note that the pair of forces (action and reaction) do not act on the same object, but on different objects: therefore, they never appear in the same free-body diagram of an object.

There are several examples where Newton's third law is applied in daily life. For instance:

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Answer:

The order in which the fractures occurred

I took the test

Answer:

The spinning of the Earth would make him to weigh less.

Explanation:

Given data,

The radius of the Earth, R = 6.4 x 10⁶ m

The rotational period, T = 86400 s

The mass of the man, m = 100 kg

The centripetal force at equator,

                             f = m v²/R

Since,

                              T = 2π/ω   & v = Rω

                              v²/R = 4π²R/T²                  

Substituting in the equation for centripetal force,

                                    f =  4π²mR/T²      

Substituting the values,

                                    f = 4π² x 100 x 6.4 x 10⁶ / 86400²

                                       = 3.39 N

The centripetal force is directed along the radius towards the center, the centrifugal force acts opposite to it.

The gravitational force acting the man towards the center,

                                   F = mg

                                      = 100 x 9.8

                                       = 980 N            

The net force acting on the person,

                                   F'  = F - f

                                        = 980 N - 3.39 N  

                                        = 976.61 N

Hence, this would make him to weigh less.      

The heat transferred during the process from state 2 to state 1 in a closed system, after adding 40 kJ of heat and doing 60 kJ of work in state 1 to 2, then having 20 kJ of work done on it, is -80 kJ, meaning 80 kJ of heat is removed.

Given the information that a closed system changes from state 1 to state 2 while 40 kJ of heat is added and 60 kJ of work is done by the system, we can use the first law of thermodynamics to determine the heat transferred during the reverse process (state 2 to state 1). The first law of thermodynamics states that the change in internal energy (
Delta U
) of a system is equal to the heat added to the system (Q) minus the work done by the system (W), so:
Delta U = Q - W.

For the process 1 to 2:

Heat added (Q1 to 2) = +40 kJ

Work done by the system (W1 to 2) = -60 kJ

Therefore,
Delta U1 to 2 = 40 kJ - (-60 kJ) = 100 kJ.

Since the system returns to the initial state, the change in internal energy for the entire cycle is zero:

Delta U cycle =
Delta U1 to 2 +
Delta U2 to 1 = 0

So,
Delta U2 to 1 = -
Delta U1 to 2 = -100 kJ

For the process 2 to 1, we are given:

Work done on the system (W2 to 1) = +20 kJ

Using the first law again for process 2 to 1:

Delta U2 to 1 = Q2 to 1 - W2 to 1

-100 kJ = Q2 to 1 - 20 kJ

Q2 to 1 = -100 kJ + 20 kJ = -80 kJ.

Therefore, 80 kJ of heat is removed from the system during the process from state 2 to state 1.

The gravitational force of the planet pulling on the sun is equal to the gravitational force of the sun pulling on  the planet

Explanation:

We can solve this problem by applying Newton's third law, which states that:

"When an object A exerts a force (called action) on an object B, then object B exerts an equal and opposite force (called reaction) on object A"

In this problem, we can identify:

- The sun as object A

- The planet as object B

By applying Newton's third law, we can state that:

- The action is the gravitational force exerted by the sun on the planet

- The reaction is the gravitational force exerted by the planet on the sun

According to the law, the two forces are equal in magnitude and opposite in direction: so, we can conclude that

The gravitational force of the planet pulling on the sun is equal to the gravitational force of the sun pulling on  the planet

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Answer:

Of the same magnitude

Explanation:

The work done is 375 J

Explanation:

The work done by a force in moving an object is given by

[tex]W=Fd cos \theta[/tex]

where

F is the magnitude of the force

d is the displacement

[tex]\theta[/tex] is the angle between the direction of the force and the displacement

In this problem,

F = 75 N is the force applied to the couch

d = 5 m is the displacement

Assuming the force applied to the couch is parallel to the motion, [tex]\theta=0[/tex]

And so, the work done is

[tex]W=(75)(5)(cos 0)=375 J[/tex]

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Final answer:

When moving a couch with a force of 75 N over a distance of 5 meters, you and a friend will do a total of 375 Joules of work. The calculation is based on the formula Work = Force x Distance.

Explanation:

When you and a friend move a couch to another room and exert a force of 75 N over 5m, you can calculate the amount of work done with the formula Work = Force x Distance. In this scenario, since the force exerted is 75 N and you move the couch over a distance of 5 meters, the work done can be computed as:

Work = 75 N x 5 m = 375 Joules.

This means you and your friend will do a total of 375 Joules of work in moving the couch to another room, assuming the movement is in the direction of the applied force and that friction or other forces are not taken into account for this particular calculation.

The period of the pendulum in the Moon is 3.9 s

Explanation:

The period of a simple pendulum is given by the equation

[tex]T=2\pi \sqrt{\frac{L}{g}}[/tex] (1)

where

L is the length of the pendulum

g is the acceleration due to gravity

Here we have a pendulum whose period on Earth is

[tex]T_e = 1.6 s[/tex]

where on Earth, the acceleration due to gravity is

[tex]g_e = 9.8 m/s^2[/tex]

So eq.(1) can be written as

[tex]T_e = 2\pi \sqrt{\frac{L}{g_e}}[/tex] (2)

When the same pendulum is moved to the Moon, its length does not change, so its period on the Moon is given by

[tex]T_m = 2\pi \sqrt{\frac{L}{g_m}}[/tex] (3)

where

[tex]g_m = \frac{1}{6}g_e[/tex] is the acceleration due to gravity on the Moon (1/6 of that on the Earth)

Dividing eq.(3) by eq.(2), we get

[tex]\frac{T_m}{T_e}=\sqrt{\frac{g_e}{g_m}}=\sqrt{\frac{g_e}{\frac{1}{6}g_e}}=\sqrt{6}[/tex]

Therefore, the period of the pendulum on the moon is

[tex]T_m = \sqrt{6}T_e = \sqrt{6}(1.6)=3.9 s[/tex]

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Answer: 1.4m

Explanation:

Answer:

Upward force is lift.

Downward force is gravity.

Thrust act towards left.

Drag act towards right.

Explanation:

The forces acting on the airplane are:

1. Downward force which is due to Earth's gravitation and hence gravitation force acts in the downward direction.

2. Air applies a force in the upward direction in order to make the airplane float in air. This force is called lift force as it lift the airplane in the air.

3. Forward force acts on the airplane which is thrust force which causes the airplane to move forward.

4. The air resists the motion of the airplane and hence applies a force in the backward direction known as drag force.

The mass of the ball is 6.7 kg

Explanation:

The momentum of an object is defined as

[tex]p=mv[/tex]

where

p is the momentum

m is the mass of the object

v is its velocity

For the ball in this problem we have the following data:

v = 1.5 m/s (velocity)

p = 10.0 kg m/s (momentum)

Solving the equation for m, we find the mass of the ball:

[tex]m=\frac{p}{v}=\frac{10}{1.5}=6.7 kg[/tex]

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Answer:

The velocity at the ground is 63.25 m/s and time taken is 6.325 s.

Explanation:

Given:

As the object is released, the initial velocity is, [tex]u=0\ ms^{-1}[/tex]

Displacement of the object is, [tex]d=200\ m[/tex]

To find:

Velocity at the bottom, [tex]v=?[/tex]

Time to reach the bottom, [tex]t=?[/tex]

The acceleration of the object is due to gravity and hence equal to [tex]a=g=10\ m/s^2[/tex]

Now, using the following equation of motion:

[tex]v^2=u^2+2ad\\v^2=0+2(10)(200)\\v^2=4000\\\textrm{Taking square root both sides}\\v=\sqrt{4000}=63.25\ m/s[/tex]

Now, using the equation of motion relating time and velocity:

[tex]v=u+at\\63.25=0+10t\\t=\frac{63.25}{10}=6.325\ s[/tex]

Therefore, the velocity at the ground is 63.25 m/s and time taken is 6.325 s.

To find the maximum speed at which the toolbox will slide on the bed of the truck, we need to compare the maximum static frictional force between the toolbox and the truck bed to the maximum centrifugal force required to keep the toolbox in circular motion around the curve. By setting these forces equal to each other and using the equations for static friction and centripetal acceleration, we can calculate the maximum speed.

When a toolbox slides on the back of a truck, the forces acting on the toolbox are the gravitational force pulling it downwards and the frictional force between the toolbox and the surface of the truck bed. In order for the toolbox to slide, the frictional force must be overcome. The maximum static frictional force can be calculated using the equation F_friction = μ * F_normal, where μ is the coefficient of static friction and F_normal is the normal force.

To calculate the maximum speed at which the toolbox will slide, we need to find the maximum centripetal force required to keep the toolbox in circular motion as the truck goes around the curve. The maximum centripetal force can be calculated using the equation F_centripetal = m * a_c, where m is the mass of the toolbox and a_c is the centripetal acceleration.

Setting the maximum static frictional force equal to the maximum centripetal force, we can find the maximum speed at which the toolbox will slide:

μ * F_normal = m * a_c

Since the toolbox is on a horizontal surface, the normal force is equal to the weight of the toolbox, which can be calculated using the equation F_normal = m * g, where g is the acceleration due to gravity. Substituting this in the equation above, we get:

μ * m * g = m * a_c

Simplifying and solving for a_c, we have:

Now, we can use the equation for centripetal acceleration to solve for the maximum speed:

a_c = v^2 / r

Solving for v, we have:

Substituting the values of the radius of the curve and the acceleration due to gravity, we can calculate the maximum speed at which the toolbox will slide.

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Answer:

Honestly i think the answer is B

Explanation: