when two objects slide against one another, which of the following statements about the force of friction between them is true?

Answer:

Below

Explanation:

Fn = mg cos(angle )    <======just plug in the values given

Fn = 43 * 9.81 * cos 35 = ~ 346 N

"The expression that shows number of remote control cars on the display self is 16s."

In order to create a mathematical expression, you need at least two numbers, variables, one arithmetic procedure, and a statement. In order to determine the total number of items in all of the self, we must multiply the number of self (n) by the number of self (x).

On a display stand, 16 remote-control vehicles are present. There are s display racks in total.

Therefore, there will be 16 times as many vehicles overall as s.

16 vehicles are displayed.

As a result, the expression '16s' indicates that there are 16 cars on exhibit.

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Answer: The force exerted on the wall by He is twice than by H2.

Explanation: I believe this is the answer because:

Pressure is defined as the force per unit area.

It means that pressure is directly proportional to the force. If the pressure is increased, more force will be exerted on the walls of the container.

According to Henry’s law, the partial pressure of gas in the gas mixture is directly proportional to the mole fraction of the gas.

Among the given gas mixture, the mole fraction of He is twice more than that of H2. So, the pressure exerted by the He gas is two times greater than H2.

Hence, the force exerted on the wall will be greater by He than by H2.

The ratio of the impact of the gases is:

H2 over He = 1/3 over 2/3 - 1 : 2

Therefore, the force exerted on the wall by He is twice than by H2.

I hope this helps!

The mean of the number of shot that she makes is 1.95

The probability of making a free throw is 0.39, and the probability of missing a free throw is 0.61 (1 - 0.39). Since each shot is independent, we can use the binomial distribution to calculate the probability of making x shots out of 5.

Consider p is the probability of success in each trials

The equation to calculate the mean of a binomial distribution is:

mean = n × p

where n is the number of trials

In this case, n = 5 and p = 0.39, so:

mean = n × p = 5 × 0.39 = 1.95

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Therefore, the initial speed of the ball must be 27.8 m/s to just clear the bar when kicked at an angle of 46.0 degrees.

Speed is a measure of how fast an object is moving, usually expressed as the distance traveled per unit of time. It is a scalar quantity, meaning that it has magnitude but no direction. The SI unit for speed is meters per second (m/s), although other units such as kilometers per hour (km/h) or miles per hour (mph) are also commonly used.

Here,

To solve part B, we can use the following kinematic equations:

y = yi + viyt - (1/2)gt² (vertical motion)

x = xi + vixt (horizontal motion)

where

y and x are the final vertical and horizontal displacements, respectively

yi and xi are the initial vertical and horizontal displacements, respectively (both are 0 in this case)

viy and vix are the initial vertical and horizontal velocities, respectively

g is the acceleration due to gravity (-9.81 m/s²)

t is the time of flight (the time it takes for the ball to reach the bar)

We want to find the initial velocity (v) that will allow the ball to just clear the bar, given an initial launch angle of 46.0 degrees above the horizontal. To do this, we can use the fact that the final vertical displacement (y) is equal to the height of the bar (10.0 ft = 3.05 m), and the final horizontal displacement (x) is equal to the distance from the ball to the bar (36.0 ft = 10.97 m).

y = 3.05 m

x = 10.97 m

θ = 46.0°

g = 9.81 m/s²

First, we can find the time of flight (t) by using the vertical motion equation:

y = yi + viyt - (1/2)gt²

3.05 m = 0 + visin(46.0°)*t - (1/2)(9.81 m/s²)*t²

Rearranging, we get a quadratic equation in t:

(1/2)(9.81 m/s²)t² - visin(46.0°)*t + 3.05 m = 0

Solving for t using the quadratic formula, we get:

t = [visin(46.0°) ± √((visin(46.0°))² - 4*(1/2)(9.81 m/s²)(3.05 m))]/(2(1/2)(9.81 m/s²))

We can ignore the negative solution, since time cannot be negative. Simplifying, we get:

t = [visin(46.0°) + √((visin(46.0°))² - 9.81 m/s²*3.05 m)]/4.905 m/s²

Now we can use the horizontal motion equation to find the initial velocity:

x = vixt

10.97 m = vicos(46.0°)*t

Substituting for t, we get:

10.97 m = vicos(46.0°)[visin(46.0°) + √((visin(46.0°))² - 9.81 m/s²*3.05 m)]/4.905 m/s²

Simplifying and solving for vi, we get:

vi = √(4.905 m/s² 10.97 m/[cos(46.0°)sin(46.0°) + √(sin²(46.0°) - 4(1/2)(9.81 m/s²)(3.05 m)/(vi²*cos²(46.0°)))])

= 27.8 m/s

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Answer:

This raboratory activity is broken up into four distinct parts so that the goals and variables of each part can be observed separately. In Part I, students manipulate the observe a magnetic field. In Part II, students manipulate the objects to observe an electric field. In Part III, students intentionally change the generated. In Part IV, students intentionally change the magnetic field. •and document the attraction with a magnet to ~ and document the attraction between the and measure the electric current •and observe the generation of a

In Part I of this lab activity, students manipulate objects to observe a magnetic field. In Part II, they manipulate objects to observe an electric field. In Part III, they intentionally change the generated electric field. In Part IV, they intentionally change the magnetic field and document the attraction with a magnet to and document the attraction between the objects and measure the electric current and observe the generation of a magnetic field.

The laboratory activity contains four distinct parts related to magnetic fields and electric fields. It is designed to help high school students understand the fundamental principles of electricity and electromagnetism in physics. Students manipulate, observe, document, and measure in all parts of the activity to gain comprehensive exposure.

The laboratory activity you're referring to is subdivided into four distinct parts, each focusing on different aspects of Physics related to magnetic fields and electric fields.

In Part I of the lab, students experiment with a magnet to understand the mechanics of a magnetic field. Part II shifts the focus onto electric fields where students manipulate various objects and document interactions.

For Part III and Part IV, students are required to measure the electrical current generated and observe the change in generation when different variables are intentionally altered in the magnetic field.

Overall, this activity offers comprehensive exposure to the fundamental principles of electromagnetism and electricity in physics.

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The energy required to heat the frozen dinner is 378,900 joules.

What is Power?

Power is the rate at which energy is transferred, converted, or used. It is a measure of how quickly work can be done, or how quickly energy can be transformed from one form to another.

In physics, power is defined as the work done per unit time, or the rate of energy transfer. The SI unit of power is the watt (W), which is defined as one joule per second (J/s).

To calculate the energy required to heat the frozen dinner, we can use the following formula:

First, we need to convert the power requirement from watts to joules per second (or watts):

1,263 W = 1,263 J/s

Next, we need to convert the heating time from minutes to seconds:

5.0 min = 300 s

Now we can plug these values into the formula:

Energy = 1,263 J/s x 300 s

Energy = 378,900 J

Therefore, the energy required to heat the frozen dinner is 378,900 joules.

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The acceleration of the system is 1.96 m/s^2; The tension in the string is 8.16 N.

Acceleration is the rate of change of velocity with respect to time.

(i) The acceleration of the system can be found using the equation:

a = (m1 - m2)g / (m1 + m2)

where m1 and m2 are the masses, g is the acceleration due to gravity.

Substituting the given values, we get:

a = (1.8 kg - 1.2 kg) × 9.8 m/s^2 / (1.8 kg + 1.2 kg)

a = 1.96 m/s^2

(ii) The tension in the string can be found using the equation:

T = m2 × (g - a) + μm1g / (1 + μ)

where μ is the coefficient of friction.

Substituting the given values, we get:

T = 1.2 kg × (9.8 m/s^2 - 1.96 m/s^2) + 0.2 × 1.8 kg × 9.8 m/s^2 / (1 + 0.2)

T = 8.16 N

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Answer:

the height at which the rock's kinetic energy is twice its potential energy is approximately 4.5 m.

Explanation:

When the rock is dropped from a height of 9.0 m, it initially has potential energy equal to mgh, where m is the mass of the rock, g is the acceleration due to gravity (9.8 m/s^2), and h is the height from which the rock was dropped. Therefore, the potential energy of the rock is:

U = mgh = (6.0 kg) * (9.8 m/s^2) * (9.0 m) = 529.2 J

As the rock falls, its potential energy is converted to kinetic energy, given by the expression (1/2)mv^2, where v is the velocity of the rock. At a height where the kinetic energy of the rock is twice its potential energy, we can write:

(1/2)mv^2 = 2mgh

Simplifying this expression, we get

v^2 = 4gh

At this height, the kinetic energy of the rock is given by:

K = (1/2)mv^2 = (1/2)m(4gh) = 2mgh = 2U

Substituting the values of m, g, and U, we get:

v^2 = 4gh = 4(9.8 m/s^2)h = (2 * 529.2 J) / 6.0 kg = 176 J/kg

Solving for h, we get:

h = (v^2) / (4g) = (176 J/kg) / (4 * 9.8 m/s^2) ≈ 4.5 m

Upon crossing the Chattooga River, the Jacob's last speed was measured at 6.5 m/s, with the direction of travel being to the south-east.

We measure two perpendicular velocities due to the kayaker and the river: 2.5 m/s downstream inside a southerly direction and 6 m/s across the river in such an easterly direction.

The Pythagorean Theorem makes the following predictions about the amount of a resultant velocity:

v = √(2.5)² + (6)²

v = √42.25

v = 6.5 m/s

The direction that results will be south-east.

As a result, the Jacob's final speed when it crosses the Chattooga River is determined to be 6.5 m/s, with the direction of travel being south-east.

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The maximum width of the gorge that the secret agent can clear is 33.2 m.

Gorge is a steep-sided valley that is typically formed when a river or stream cuts through a landscape. Gorges can occur in a variety of landscapes and can range greatly in size. They are often found in areas of limestone or sandstone, and are often filled with spectacular scenery, including waterfalls, rapids, and cliffs. Gorges can also be formed by ice, erosion, and glacial activity.

The maximum width of the gorge that the secret agent can clear is given by the equation:

W = 2v0^2 * sin(2θ) / g

Where W is the maximum width of the gorge, v0 is the initial speed of the agent, θ is the angle of the slope, and g is the acceleration due to gravity.

Substituting the given values into the equation, we get:

W = 2 * (12.9 m/s)^2 * sin(2 * 28°) / 9.81 m/s^2

W = 33.2 m

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Answer:

Decibel (dB) is the unit of sound.

Answer:

Decibels ( dB)

Explanation:

When measuring sound intensity in units, it is referred to as decibels

In the scientist sample of unknown gas when he looks at the spectrum of visible light is xenon.

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For an ideal mixture of two or more substances, the mixing entropy can be derived based on the same principles as for ideal gases. The reason is that ideal mixtures also have particles that are in constant random motion, and the entropy of mixing is still related to the number of possible ways the particles can be arranged.

In an ideal mixture, the assumption is that the molecules of different substances are the same size and shape, and have the same intermolecular forces with each other as they do with their own kind. This means that there are no attractive or repulsive forces between particles of different types, which simplifies the calculation of the entropy of mixing.

The mixing entropy of an ideal mixture is determined by the number of possible ways the molecules of the two substances can be distributed among the available volume. Just as in the case of ideal gases, this leads to an increase in entropy when the two substances are mixed, as there are more ways to distribute the molecules than when they are separated.

Therefore, the concept of an ideal mixture allows us to apply the same principles of thermodynamics to denser systems as we do for ideal gases, which makes it a useful tool for studying a wide range of physical and chemical processes involving mixtures.

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The mixing entropy formula applies to ideal mixtures because there are no intermolecular forces between different species, there are no volume changes upon mixing, and the mixing is completely random.

An ideal mixture is a hypothetical mixture of gases, liquids or solids where the components are assumed to behave as an ideal gas, and where the two types of molecules are the same size and interact with each other in the same way as molecules of the same type (same forces, etc.). In an ideal mixture, the mixing entropy formula applies due to the following reasons:

Therefore, the mixing entropy formula applies to ideal mixtures because there are no intermolecular forces between different species, there are no volume changes upon mixing, and the mixing is completely random.

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The acceleration of the object can be determined using the force exerted and mass. The acceleration of the object is with the mass of 5 kg having a net force of 20 N is 4 m/s².

Acceleration of an object is the rate of change in its velocity. Like velocity, acceleration is a vector quantity thus having both magnitude and direction.

According to Newton's second law of motion, force exerted on an object is the product of its mass and acceleration. Greater the force, the object will be accelerated more.

F = ma

given m = 5 kg

F = 20 N

a = F/m

 = 20 N/ 5 kg

 = 4 m/s²

Therefore, the acceleration of the object is  4 m/s².

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A) The work done on the book between points A and B is 5.32 J in the direction opposite to the book's motion.

B) The book is moving at 1.91 m/s at point C.

C) If +0.750 J of work was done on the book from point B to point C, the book would be moving at 2.31 m/s at point C.

(a) To find the work done on the book between points A and B, we need to use the work-energy principle, which states that the net work done on an object is equal to its change in kinetic energy:

Net work done = change in kinetic energy

The change in kinetic energy can be found by subtracting the initial kinetic energy at point A from the final kinetic energy at point B:

change in kinetic energy = (1/2)mvB^2 - (1/2)mvA^2

where m is the mass of the book, vA is the velocity of the book at point A, and vB is the velocity of the book at point B.

Substituting the given values, we get:

change in kinetic energy = (1/2)(1.50 kg)(1.25 m/s)^2 - (1/2)(1.50 kg)(3.21 m/s)^2

= -5.32 J

Since the final velocity is less than the initial velocity, the change in kinetic energy is negative. Therefore, the net work done on the book between points A and B is also negative. The magnitude of the net work done is:

|net work done| = |-5.32 J| = 5.32 J

Therefore, the work done on the book between points A and B is 5.32 J in the direction opposite to the book's motion.

(b) Since -0.750 J of work is done on the book from point B to point C, we can use the work-energy principle again to find the final velocity at point C:

Net work done = change in kinetic energy

Substituting the given values, we get:

-0.750 J = (1/2)(1.50 kg)(vC^2 - 1.25^2 m/s^2)

Solving for vC, we get:

vC = 1.91 m/s

Therefore, the book is moving at 1.91 m/s at point C.

(c) If +0.750 J of work was done on the book from point B to point C, we would have:

0.750 J = (1/2)(1.50 kg)(vC^2 - 1.25^2 m/s^2)

Solving for vC, we get:

vC = 2.31 m/s

Therefore, if +0.750 J of work was done on the book from point B to point C, the book would be moving at 2.31 m/s at point C.

The given question is incomplete, the complete question is

A 1.50-kg book is sliding along a rough horizontal surface. at point a it is moving at 3.21 m>s, and at point b it has slowed to 1.25 m>s. (a) how much work was done on the book between a and b? (b) if -0.750 j of work is done on the book from b to c, how fast is it moving at point c? (c) how fast would it be moving at c if +0.750 j of work was done on it from b to c?

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The height at which the rock's kinetic energy is twice its potential energy is 4.5 meters above the ground.

What is Potential Energy ?

Potential energy is energy that is stored in an object or system as a result of its position or configuration. It is a form of energy that has the potential to do work, meaning that it can be converted into other forms of energy such as kinetic energy or thermal energy

At any point during the fall, the total energy of the rock (E) is equal to the sum of its potential energy (U) and its kinetic energy (K):

E = U + K

The potential energy of the rock is given by:

U = mgh

where m is the mass of the rock, g is the acceleration due to gravity (9.8 m/s^2), and h is the height of the rock above some reference point.

The kinetic energy of the rock is given by:

K = (1/2)mv^2

At some height h, the kinetic energy of the rock is twice its potential energy. We can express this mathematically as:

K = 2U

Substituting the expressions for U and K and solving for h, we get:

(1/2)mv^2 = 2mgh

Simplifying and solving for h, we get:

h = (v^2)/(4g)

To find v, we can use the fact that the initial potential energy of the rock is equal to its final kinetic energy (since the rock is dropped from rest):

U = K

mgh = (1/2)mv^2

Simplifying and solving for v, we get:

v = sqrt(2gh)

Substituting this expression for v into the equation for h, we get:

h = (2gh)/(4g)

Simplifying and canceling the factor of g, we get:

h = 0.5h

Therefore, the height at which the rock's kinetic energy is twice its potential energy is halfway between the initial height and the ground.

Plugging in the values given in the problem, we get:

h = (9.0 m)/2 = 4.5 m

Therefore, the height at which the rock's kinetic energy is twice its potential energy is 4.5 meters above the ground.

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The quantity with units of [tex]kgm^3/s^1[/tex] is mass flow rate or mass flow density.

Mass flow, is a physical quantity that represents the amount of mass flowing through a unit area per unit time. It is the mass flow per unit area and is typically denoted by the symbol ṁ/A. It is a measure of how much mass is flowing per unit area in a given system.

For example, it is often used to describe the rate of mass transfer in a chemical reaction, where a mass flow density is used to measure the amount of reactant or product flowing per unit area per unit time. Mass flow density is also used to describe the rate of mass flow in a fluid through a particular area, such as in a pipe or channel.

The quantity with units of [tex]kgm^3/s^1[/tex] is mass flow rate or mass flux density.

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The concept Buoyant force is used here to determine the force which on the ground of the pool. The buoyant force is 15385.21 N.

The Buoyant force is defined as the upward force exerted on an object which is fully or partially immersed in a liquid. This force is also called the Upthrust. Due to this force a body immersed in a fluid appears to lose its weight.

The Buoyant force is calculated as:

F = mg × ρ fluid / ρ hippo

Density of hippo = Mass/volume

= 1600/1.57 = 1019.10 kg/m³

Density of fluid = 1 g/cm³ = 1000 kg/m³

F = 1600 × 9.8 × 1000/1019.10 = 15385.21 N

Thus the Buoyant force is 15385.21 N.

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The percent yield of this reaction is 80.6%. This means that only 80.6% of the predicted amount of the compound was actually produced, while the remaining 19.4% was lost due to incomplete reactions or other factors.

The percent yield can be calculated as follows:

percent yield = (actual yield / theoretical yield) x 100%

Substituting the given values, we get:

percent yield = (26.1 / 32.4) x 100%

percent yield = 0.806 x 100%

percent yield = 80.6%

A compound is a substance made up of two or more different elements that are chemically bonded together in a fixed ratio. This means that compounds have a unique chemical formula, which describes the types and numbers of atoms that make up the compound.

The properties of a compound are different from those of the individual elements that make it up. For example, water (H2O) is a compound made up of hydrogen and oxygen. Although hydrogen is a gas and oxygen is a gas, water is a liquid at room temperature. This is because the properties of a compound are determined by the arrangement of the atoms and the type of chemical bonds between them.

Compounds are important in many areas of physics, including materials science, chemical engineering, and electronics. They are used to make a wide range of products, from plastics and medicines to electronic devices and batteries. Understanding the properties and behavior of compounds is therefore essential for many areas of research and development.

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It takes approximately 61,649 years for the activity of plutonium waste to decrease from 20,000 to 625.

We can use the radioactive decay formula to find the time it takes for the activity of plutonium waste to decrease from 20,000 to 625:

A = A₀(1/2)^(t/T)

where

We can solve for t by taking the logarithm of both sides:

Substituting the values:

t = -24,000 years × log(625/20,000) / log(1/2)

t = 61,649 years

Therefore, it takes approximately 61,649 years for the activity of plutonium waste to decrease from 20,000 to 625.

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The mass of the Salamander is 0.09 Kg

Momentum is a physical quantity that describes the motion of an object. It is defined as the product of an object's mass and its velocity. Mathematically, momentum (p) can be expressed as:

p = mv

where m is the mass of the object and v is its velocity.

We know that;

Momentum before collision = Momentum after collision

(5 * 3.6) - (M * 2.2) = (5 + M) * 3.5

Let the mass of the Salamander

18 - 2.2M = 17.5 + 3.5 M

18 - 17.5 = 3.5 M + 2.2 M

M = 0.09 Kg

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I'm sorry, I'm not able to see the figure you mentioned. Can you please provide more information or context about the figure and the question you have related to it?

Work is the amount of energy transferred by a force, and can be calculated using the formula W = Fd, where F is the force, and d is the distance. In this case, the work is 100 joules, and the force is 10N. Therefore, the distance is d = W/F = 100/10 = 10 meters.

Energy is the ability to do work. It is a measure of the capacity to cause change. Energy can take many forms, including kinetic energy (energy of motion), potential energy (stored energy of position), electrical energy, thermal energy, light energy, sound energy, chemical energy, and nuclear energy. Energy can be converted from one form to another, but it cannot be created or destroyed. For example, energy from the sun can be converted into electrical energy and stored in batteries.

The power used is the rate of work done, and can be calculated using the formula P = W/t, where W is the work done, and t is the time. In this case, the power used is P = 100/4 = 25 Joules/second.

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The circuit where the capacitors reach half their maximum charge in the least amount of time when switch s is closed. is Circuit E.

A circuit is an electrical network composed of various electrical components, such as resistors, capacitors, inductors, transistors, diodes, and other electronic devices, that are interconnected to perform a specific function. The components are connected by conducting wires that carry electrical current through the circuit.

Circuits can be designed to perform a wide range of functions, such as amplification, filtering, switching, and many others. They are used in a variety of electronic devices, from simple toys and household appliances to complex computers and communication systems.

Circuits can be classified into two types: analog and digital. Analog circuits process continuous signals, while digital circuits process signals in discrete values. Both types of circuits are important and widely used in modern electronics. Circuit E takes less time to reach half of its maximum charge

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The magnetic pole is referred to as the region at each end of a magnet where the external magnetic field is strongest while a magnetic field is the region around a magnetic material or a moving electric charge within which the force of magnetism acts.

This is referred to as a vector field that describes the magnetic influence on moving electric charges, electric currents, and magnetic materials.

A bar magnet suspended in Earth's magnetic field orients itself in a north–south direction and is referred to as a magnetic pole which has magnetic field present in the region also.

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The required two cars move together after the collision with a velocity of 15.13 m/s.

Conservation of momentum is a fundamental principle in physics that states that the total momentum of a closed system of objects is conserved, meaning that it does not change over time, as long as no external forces act on the system.

Here,

Momentum of the Escalade: p₁ = m₁ * v₁
                                                   = 860 kg * 40 m/s * cos(72)
                                                     = 26731.13 kg m/s

The momentum of the mini-cooper: p₂ = m₂ * v₂
                                                                 = 220 kg * 22 m/s * cos(210)
                                                                 = -10399.48 kg*m/s
(negative because it's traveling in the opposite direction)

The total momentum before the collision is the sum of these two momenta:

p₁ + p₂ = 26731.13 kgm/s - 10399.48 kgm/s = 16331.65 kg*m/s

After the collision, the two cars stick together and move with a common velocity v. We can use the conservation of momentum principle again to find this velocity,

Total mass after the collision: m₁ + m₂ = 860 kg + 220 kg = 1080 kg

Total momentum after the collision: (m1 + m2) * v

Setting these equal, we get:

p₁ + p₂ = (m₁ + m₂) * v

16331.65 kg*m/s = 1080 kg * v

v = 15.13 m/s

Therefore, the two cars move together after the collision with a velocity of 15.13 m/s.

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The required final speed of the crate after 18 seconds is calculated to be 15 m/s.

The mass of the packing crate is given as 80 kg.

The applied force is 80 N for 12 s.

So, the force is given as,

f = (mv₁ - mv₂)/t

where,

f is force

m is mass

t is time

v₁ is final velocity

v₂ is initial velocity

80 × 12 = 80 v₁ - 80 × 0

v₁ = 12 m/s

After 12 seconds, the crate's final velocity is 12 m/s.

The force drops to zero, linearly for the next 6 seconds. So,

F = 80 - (80/6)t

In the case of the force's magnitude linearly decreasing,

∫F dt = m v₁ - m v₂

∫(80 - (80/6)t)dt = 80 v₁ - 80 × 12

80 t - 80t²/(2×6) = 80 v₁ - 960

For the next coming 6 seconds, t = 6 then,

80 × 6 - (80/12) × 6² = 80 v₁ - 960

⇒ v₁ = 15 m/s

Thus, after 18s, we can conclude that the final speed of the crate is 15 m/s.

The question is incomplete. The complete question is 'What is the final speed of the crate, 18.0 s after the force was first applied?'

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The magnitude of the force applied by the man is equal to the weight of the piano (190 kg) multiplied by the cosine of the ramp angle (10.0 degrees). The magnitude of the force is thus equal to 1647.2 N.

Force is an external influence that will cause an object to move, accelerate, decelerate, remain in motion, or stop. Forces are measured in Newtons (N) and are represented by vectors, which have both a magnitude and a direction. There are different types of forces such as contact forces, non-contact forces, and forces in nature. Examples of contact forces are friction, tension and normal force. Examples of non-contact forces are gravity and magnetism.

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