A tomato of mass 0.18 kg is dropped from a tall bridge. If the tomato has a speed of 11 m/s just before it hits the ground, what is the kinetic energy of the tomato?

Yes, the stuntman can jump from one building to the other building.

Further explanation:

The stuntman jump from one building inclined at some angle to the other traversing a parabolic path.

Given:

The velocity of stuntman is 5m/s.

The distance between the buildings is 4m.

The difference in the height of the buildings is 2.5m.

The angle of inclination is [tex]{15^ \circ }[/tex].

Concept used:

When stuntman jumps from the top of one building to the top of other building he start running first then he jump at a velocity of 5m/s inclined at an angle of [tex]{15^ \circ }[/tex] from the horizontal of first building.

The velocity of stuntman has two components [tex]{v_x}[/tex] and [tex]{v_y}[/tex], respectively in the X-direction and in the Y-direction.

The expression for the distance in horizontal direction is given as.

[tex]x = \left( {v\cos \theta } \right)t[/tex]

Rearrange the above expression for time.

[tex]t = \dfrac{x}{{\left( {v\cos \theta } \right)}}[/tex]                             …… (1)

Here, t is the time of flight, v is the velocity of object and [tex]\theta[/tex]  is the angle of inclination.

The expression for the distance in Y-direction is given by the second equation of motion.

[tex]y = ut + \frac{1}{2}\left( { - g} \right){t^2}[/tex]                        

Here, u is the velocity in Y-direction and (–g) is the acceleration due to gravity directed in the downward direction.

The expression for the component of velocity in Y-direction is given as.

[tex]u = v\sin \theta[/tex]

Substitute [tex]v\sin\theta[/tex] for u in the above expression.

[tex]y = \left( {v\sin \theta } \right)t + \frac{1}{2}\left( { - g} \right){t^2}[/tex]                       …… (2)

Substitute 5m/s for v, 4m for x and [tex]{15^ \circ }[/tex] for   in equation (1).

[tex]\begin{aligned}t&=\frac{{4\,{\text{m}}}}{{\left({\left( {5\,{\text{m/s}}}\right)\left( {\cos {{15}^ \circ }}\right)}\right)}}\\&=0.828\,{\text{s}}\\\end{aligned}[/tex]

Substitute [tex]0.828\,{\text{s}}[/tex] for t, 5m/s for v, [tex]9.8\,{\text{m/}}{{\text{s}}^{\text{2}}}[/tex] for g and [tex]{15^ \circ }[/tex] for [tex]\theta[/tex] in equation (2).

[tex]\begin{aligned}y&=\left( {\left( {5\,{\text{m/s}}} \right)\sin \left( {{{15}^ \circ }} \right)} \right)\left( {0.828\,{\text{s}}} \right) + \frac{1}{2}\left( { - 9.8\,{\text{m/}}{{\text{s}}^{\text{2}}}} \right){\left( {0.828\,{\text{s}}} \right)^2}\\&=1.071 - 3.36 \\&=- 2.29\,{\text{m}}\\\end{aligned}[/tex]

Thus, the stuntman can jump from one building to another because its vertical distance is less than the difference in height of buildings.

Learn more:

1.  Motion under force https://brainly.com/question/6125929.

2.  Projection of ball https://brainly.com/question/11023695.

3. Conservation of momentum https://brainly.com/question/9484203.

Answer Details:

Grade: High School

Subject: Physics

Chapter: Kinematics

Keywords:

Force, motion, parabolic path, acceleration due to gravity, time of flight, angle of inclination, inclined plane, buildings, height difference, cliff, horizontal direction, vertical direction, 2.29 m, 2.3m, 0.828sec.

The question involves calculating whether a stuntman can jump from one rooftop to another using principles of projectile motion. By calculating the horizontal and vertical components of the stuntman's velocity, and the time and distance he will travel, we determine he will fall approximately 2.9 meters. Since the other roof is only 2.5 meters lower, the stuntman will successfully make the jump.

The student's question involves determining whether a stuntman can safely jump from one building to another, given his initial velocity, the angle of his jump, and the distance and height difference between the buildings. This is a classic physics problem involving projectile motion, where we consider the horizontal and vertical components of the motion separately. We can ignore air resistance and use the kinematic equations to solve this problem.

Firstly, we need to find the horizontal and vertical components of the initial velocity. The horizontal component, vx, is v × cos(θ), and the vertical component, vy, is v × sin(θ), where v is the initial velocity and θ is the angle of launch. For a jump of 5.0 m/s at 15°:

The time, t, it takes to travel horizontally across the 4.0 m gap is found using t = d / vx, where d is the horizontal distance:

t = 4.0 m / 4.83 m/s ≈ 0.83 s

Now, let's determine if he will drop less than 2.5 m in this time frame. We use the equation of motion for vertical displacement, Δy = vyt + ½gt², with g being the acceleration due to gravity (9.81 m/s²) to find the vertical drop:

Δy = (1.29 m/s × 0.83 s) + (0.5 × -9.81 m/s² × (0.83 s)²) ≈ -2.9 m

The stuntman will fall approximately 2.9 m, thus he will make it to the other roof, which is 2.5 m lower than his initial jump point.

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Answer:

The force that car A exerts on car B and the force that car B exerts on car A are the same magnitude.

Explanation:

There can be two types of collision i.e. elastic and inelastic collision. Elastic collision is also known as head-on collision. In this type of collision, the momentum and kinetic energy before and after the collision remains the same.

If two identical small cars (car A & car B) have a head-on collision, then the force that car A exerts on car B and the force that car B exerts on car A are the same magnitude. It is due to Newton's third law of motion which states that there is an equal and opposite reaction when one object applies a force on another object. So, the correct option is (c).  

Answer:

[tex]H = 273.4 m[/tex]

Explanation:

Let the falling object took "n" seconds to reach the ground and it travels H height

So we will have

[tex]H = \frac{1}{2}gn^2[/tex]

now we know that it covers one fourth of total height in last second

So we can say that it will cover 3H/4 distance in (n-1) seconds

so we will have

[tex]\frac{3H}{4} = \frac{1}{2}g(n-1)^2[/tex]

now from above two equations

[tex]\frac{4}{3} = (\frac{n}{n-1})^2[/tex]

[tex]1.155(n-1) = n[/tex]

[tex]n = 7.46 s[/tex]

Now we have

[tex]H = \frac{1}{2}(9.81)(7.46^2)[/tex]

[tex]H = 273.4 m[/tex]

To vaporize 3.0 L of liquid oxygen with a density of 1.14 kg/L and a heat of vaporization of 213 kJ/kg, 728460 joules of energy would be absorbed.

The student is asking about the amount of energy required to vaporize a certain volume of liquid oxygen. Given that the density of liquid oxygen at its boiling point is 1.14 kg/L, and its heat of vaporization is 213 kJ/kg, we can calculate the energy needed for vaporization using these two properties.

First, calculate the mass of 3.0 L of liquid oxygen:

Mass = Density times Volume = 1.14 kg/L times 3.0 L = 3.42 kg

Then, calculate the energy required for vaporization:

Energy = Mass times Heat of Vaporization = 3.42 kg times 213 kJ/kg = 728.46 kJ

Since 1 kJ = 1000 J, we can convert the energy to joules:

Energy in joules = 728.46 kJ times 1000 J/kJ = 728460 J

Therefore, 728460 joules of energy would be absorbed by 3.0 L of liquid oxygen as it vaporizes.

To find the stopping potential and the maximum speed of ejected electrons from a metal with a given work function when exposed to a specific wavelength of light, physicists use the photoelectric effect principles. Calculations involve the use of Planck's constant, the speed of light, and the electron charge to first determine the energy of incident photons and then the electrons' kinetic energy and velocity.

To determine the stopping potential for electrons ejected from a metal when light of wavelength 400 nm shines on it, first, we use the photoelectric equation: E(Photon) = Work Function + Kinetic Energy(Max). The energy of a single photon (E) can be found with the equation E=hc/λ, where h is Planck's constant (6.626 x 10^-34 J·s), c is the speed of light (3.00 x 10^8 m/s), and λ is the wavelength in meters. For the stopping potential, the maximum kinetic energy of the ejected electrons is equal to the electrical energy qV, where q is the charge of an electron (1.602 x 10^-19 C) and V is the stopping potential.

Using these equations and the given work function, the maximum speed of electrons can be calculated using the formula for kinetic energy: KE = 0.5 * m * v^2, where m is the mass of the electron (9.109 x 10^-31 kg) and v is the velocity.

The exact calculations for the stopping potential and maximum speed are not provided here, since we are not certain about the correctness of these specific answers.

Speed and direction are the factors that affect an object's velocity.

The displacement that an object or particle experiences with respect to time is expressed vectorially as velocity. A vector quantity, that is. The change in an object's displacement with respect to time is known as velocity.

Displacement / Time = Velocity

The information is ,

Let V be the symbol for an object's velocity.

The measurement of V is now determined as

The concept of speed describes how quickly an object is traveling across a specific distance.

An object's speed just indicates how swiftly or slowly it is moving. It doesn't say which way the object is moving. Speed and direction are both referred to by the word velocity. A vector is an amount of velocity.

Now that the displacement is a vector quantity with direction, the equation for velocity is displacement / time.

As a result, an object's velocity is determined using its speed and direction.

Click here to learn more about velocity.

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Answer:

In The Atmosphere

Explanation:

edg2021

The two balls meet at approximately 272.5 meters above the surface of the tower after around 5.1 seconds.

To determine when and at what height the two balls meet, we'll analyze their motions individually and then together.

Step 1: Motion of the dropped ball

For the ball dropped from the roof at a height of 400 meters, the equation of motion under gravity is:

h₁ = 400 - 0.5 * g * t²

where:

h₁ is the distance traveled by the dropped ball in meters.

g is the acceleration due to gravity (9.8 m/s²).

t is the time in seconds.

Putting in the values, h₁ = 400 - 4.9 t²

Step 2: Motion of the thrown ball

For the ball thrown upwards with an initial velocity of 50 m/s, the equation of motion is:

h₂ = 50t - 0.5 * g * t²

where:

h is the distance traveled by the thrown ball in meters.

Putting in the values, h₂ = 50t - 4.9 t²

Step 3: Equating the distances

The balls meet when their total distance is 400 meters, so:

h₁ + h₂ = 400

Substituting the equations for h₁ and h₂, 400 - 4.9 t² + 50t - 4.9 t² = 400

Simplifying, -9.8 t² + 50t = 0

Factoring out t, t(50 - 9.8t) = 0

Thus, t = 0 (initial point, not useful) or t = 50 / 9.8 ≈ 5.1 seconds.

Step 4: Calculating the height

Using t ≈ 5.1 seconds in any height equation:

h₁ = 400 - 4.9 * (5.1)²

h₁ = 400 - 127.5

h₁ ≈ 272.5 meters

Therefore, the two balls meet approximately 272.5 meters above the surface of the tower after about 5.1 seconds.

Answer:

Acceleration, [tex]a=4.83\ m/s^2[/tex]              

Explanation:

It is given that,

Mass of the meteor, m = 521 kg

Force acting on the meteor, F = 2520 N

Let a is the acceleration of the meteor. It can be calculated using the Newton's second law of motion. According to this law the force acting on an object is equal to the product of mass and acceleration with which it is moving. Mathematically, it is given by :

[tex]F=m\times a[/tex]

[tex]a=\dfrac{F}{m}[/tex]

[tex]a=\dfrac{2520\ N}{521\ kg}[/tex]

[tex]a=4.83\ m/s^2[/tex]

So, the acceleration of the meteor is [tex]4.83\ m/s^2[/tex]. Hence, this is the required solution.

Answer:

false

Explanation:

The mass of the aluminum cylinder is 4,050 kg, obtained by multiplying the given density of aluminum with the given volume of the cylinder.

The mass (m) of the aluminum cylinder can be calculated using the formula for density (ρ), which is Density = Mass/Volume. In this case, since the density of the aluminum (ϱ) is 2.70 * 103 kilograms per cubic meter (kg/m3) and the volume (V) of the cylinder is 1.50 m3, we can rearrange the formula to find mass such that Mass = Density * Volume. Substituting the given values, we get m = 2.70 * 103 kg/m3 * 1.50 m3 = 4,050 kg. Therefore, the mass of the aluminum cylinder is 4,050 kg.

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me answer be ye Conduction

The units can be best determined by expressing them both in terms of SI base units.

The Système International (SI) unit is named after the French word for it. The International System of Units (ISO) is the name of the metric system that is used as the industrial standard for measurements (SI). SI units are crucial for the growth of science and technology.

It is composed of 7 base units, from which 22 derivative units are generated. Either a standard multiple or a fractional quantity can be used to express SI units. Prefix multipliers with powers of 10 in the range from [tex]10^{-24}[/tex]  To [tex]10^{24}[/tex]  Are used to define these numbers.

Now, according to the question :

J=kg×m²/s²

J/m²=kg/s²

and, N=kg×m/s²

⇒m×s²/(kg×m/s²)

=[tex]s^{4}[/tex]/kg

Hence, after comparing both of them, we can say that they are not equivalent.

To get more information about SI unit :

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The problem involves applying conservation of momentum principles to a two-dimensional collision between an apple and an orange tossed by astronauts. The final direction of the apple after the collision can be determined using the velocity components and trigonometry, specifically the arctan function. To provide the direction, additional details like initial direction are needed.

The student is seeking help with a physics problem involving the concepts of momentum conservation and two-dimensional collisions. In this problem, two astronauts (in a hypothetical scenario) are tossing an apple and an orange to each other when the fruits collide in space. The provided information lets us analyze the collision using the principles of momentum to find the final direction of the apple after the collision.

To solve for the direction of the apple after the collision, we must apply the law of conservation of momentum in two dimensions because the collision sends the objects off in different directions. Since there are no external forces, the total momentum in each direction (x and y) should remain constant. We use the before-collision and after-collision momenta to form equations and solve for the final velocity components of the apple, allowing us to calculate the final direction using trigonometry.

However, to provide the exact direction, a diagram or more information indicating the initial directions of the fruits would be required. Assuming the initial throw was along the x-axis and the final velocity of the orange is given in the y-axis, you can apply the arctan function to the velocity components of the apple to find the direction in terms of angle from the x-axis.

Answer:

c. a difference in electric potential

Explanation: