On the surface of planet y, which has a mass of 4.83x1024 kg, a 30.0 kg object weighs 50.0 n. what is the radius of the planet?

The answer choice is B

The brother on the outer edge of the merry-go-round experiences greater centripetal acceleration due to the larger radius of his circular path.

The brother riding on the outer edge of the merry-go-round will experience greater centripetal acceleration than his sister who is positioned closer to the center. This is because centripetal acceleration depends on both the angular velocity and the radius of the path of the moving object. Since both are riding on the same merry-go-round and thus have the same angular velocity, the one farther from the center (the brother) has a larger radius, and therefore a greater centripetal acceleration.

Answer: 4

The mechanical advantage is the ratio of the force exerted  by the object to the force applied to do work on it.

Here, Jeff tried to lift a rock weighing 600 pounds by wedging board under the rock. Jeff who weighs 150 pounds uses all his weight to exert force on lever and lift rock.

Mechanical advantage, [tex]M.A.=\frac{weight\hspace{1mm}of\hspace{1 mm}rock}{weight\hspace{1mm}of\hspace{1 mm}Jeff}=\frac{600 pounds}{150 pounds}=4.[/tex]

Therefore, the mechanical advantage that lever provided to Jeff in lifting rock is 4.

The answer to this question is B. Nonmetal

Final answer:

Compression waves and water waves share similarities as longitudinal waves that transfer energy through a medium, but they differ in their propagation medium and oscillation nature.

Explanation:

Compression waves and water waves are both types of longitudinal waves that involve oscillations. They share the common characteristic of transmitting energy through a medium. However, they differ in the medium through which they travel and the nature of their oscillations.

The Answer would be 4j

The shape that most adequately recounts the course of the projectile would be:

B). Parabola

Thus, option B is the correct answer.

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When a positively charged particle enters a magnetic field, it experiences a force perpendicular to its velocity and the magnetic field, causing it to follow a curved path, typically resulting in circular or spiral motion.

If a positively charged particle moves into a magnetic field traveling in a straight line, its motion will change according to the Lorentz force law. When a positively charged particle enters a magnetic field, it experiences a force known as the Lorentz force that acts perpendicular to both the magnetic field and the velocity of the particle. As a result, the particle's path will bend and it will undergo circular motion or spiral along the field lines, depending on multiple factors such as the angle at which it enters the field.

For instance, if a positively charged particle is moving to the left and enters a magnetic field pointing towards the top of the page, the magnetic force acting on it will be directed into the page, causing it to deviate from its straight-line path. Similarly, if the particle is moving to the right, the force will be directed out of the page. If the magnetic field is uniform, the particle follows a curved path and may complete a full circle, with the radius of this circle determined by the particle's charge, velocity, and the magnetic field strength.

The direction of force and hence the subsequent motion of a positive particle differs from that of a negative particle due to their opposite charges. Different velocities or magnetic field strengths will result in different path curvatures, hence to measure the mass of a charged particle, one might need to observe its motion under various conditions. Doubling the charge or the magnetic field strength will affect the radius of the circular path, while doubling the velocity will change the shape of the path.

For neutral particles, there is no direct interaction with the magnetic field, and as such, their paths remain unaffected. To summarize, a positively charged particle's motion in a magnetic field results in a curved path that depends on its charge, velocity, magnetic field strength, and mass.

Final answer:

The experiment likely demonstrates heat transfer by conduction as heat is transferred through physical contact. Convection and radiation are other forms of heat transfer explained in the context of the experiment.

Explanation:

Kim's experiment most likely demonstrates **heat transfer by conduction.** Conduction is the transfer of heat through stationary matter by physical contact. In this experiment, the heat from the hot water is transferred to the iron rod, causing the wax on one end to melt due to the direct contact.

Convection involves the heat transfer by the macroscopic movement of a fluid, like in a forced-air furnace or weather systems. Radiation occurs when electromagnetic radiation is emitted or absorbed, like the warming of Earth by the Sun or thermal radiation from the human body.

To reach a maximum height of 200 meters when thrown upward from a height of 2 meters, the object must have an initial velocity of approximately 62.32 meters per second, using the kinematic equation with gravity as the acceleration and neglecting air resistance.

To find the initial velocity required to reach a maximum height of 200 meters when thrown up from an initial height of 2 meters, we need to use kinematic equations that describe motion under constant acceleration. Here, the acceleration is due to gravity, which is negative because it is directed downwards. Since air resistance is neglected, the initial velocity will be the same for any object thrown up to reach the specified height.

Using the kinematic equation v^2 = u^2 + 2as, where v is the final velocity (0 m/s at maximum height), u is the initial velocity, a is the acceleration due to gravity (-9.81 m/s^2), and s is the displacement (198 meters, which is the difference between the final height and the initial height), we can solve for u. Rearranging the equation gives u = sqrt(v^2 - 2as). Substituting v = 0 m/s, a = -9.81 m/s^2, and s = 198 m, the calculation of the initial velocity can be performed:

Initial Velocity, u = sqrt(0^2 - 2*(-9.81 m/s^2)*198 m) = sqrt(3883.56 m^2/s^2) = 62.32 m/s.

The initial velocity required is therefore approximately 62.32 meters per second.

Areas near oceans have milder climates than areas in the interior of continents due to the great storage capacity of water.

Areas near oceans have milder climates than areas in the interior of continents because of the great storage capacity of water. Water is able to absorb a tremendous amount of energy with very little resulting temperature change, which leads to more moderate temperatures in coastal areas. The oceans collect and store vast amounts of solar energy and transport that heat with their currents, resulting in smaller temperature variations from day to night and from winter to summer.

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The system schema goes person<string<cart

Then beneth that place earth and dram arrows pointing at person and cart because they r the only ones touching the earth. I do not know what the force diagram would look like so please dont ask

The work function of a metal is the minimum energy required to remove an electron from the metal surface. The energy can be calculated with the given light wavelength, but additional data is needed to find the specific work function of aluminium.

The work function of a metal is the minimum amount of energy required to remove an electron from the surface of the metal. This is a concept from the field of physics known as the photoelectric effect, commonly associated with Albert Einstein.

The energy of incident photons can be calculated using the formula E = hc/λ, where E is the energy, h is the Planck's constant, c is the speed of light, and λ is the wavelength of the light. The maximum kinetic energy of the ejected electrons, on the other hand, is given by the equation KE = E - W, where E is the energy of the incident photon and W is the work function of the metal.

Consequently, to find the work function or binding energy of a particular material, you can rearrange the equation into W = E - KE. For this specific problem though, more information would be necessary such as the kinetic energy of the ejected electrons to pinpoint the work function of aluminium metal in kj/mol specifically.

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Final answer:

The mantle makes up 70% of the Earth's total volume, which is the largest layer of the interior structure of the Earth. It accounts for 82.5% of the Earth's volume, with the core and crust making up the rest.

Explanation:

The component that makes up 70% of the Earth's total volume is the mantle. The mantle is predominantly composed of silicate rock and is situated between the Earth's crust and core. It comprises approximately 82.5% of the Earth's volume, making it the largest layer of the Earth's interior. The core is the second-largest layer, accounting for 16.1% of the volume, while the crust is the thinnest layer, making up only 1.4%. It is important to note that although water covers approximately 71% of the Earth's surface, it is not what comprises the largest volume of Earth's internal structure, as might be mistakenly inferred.

3 different elements make up beryllium sulfite.

Answer:

393.399 J/kg.°C

Explanation:

Specific heat capacity: This is the quantity of heat required to raise the temperature of a unit mass of a substance through a degree rise in temperature.

Heat lost by the brass = heat gained by water

CM(t₁-t₃) = cm(t₃-t₂)........................ Equation 1

Where C = specific heat capacity of the brass, M = mass of the brass, t₁ = initial temperature of the brass, t₂ = initial temperature of water, t₃ = temperature of the mixture.

Making C the subject of the equation

C = cm(t₃-t₂)/M(t₁-t₃)............................... Equation 2

Given: M = 0.59 kg, m = 2.8 kg, t₁ = 98 °C, t₂ = 5.0 °C, t₃ = 6.8 °C

Constant: c = 4200 J/kg.°C

Substitute into equation 2,

C = 2.8×4200(6.8-5.0)/0.59(98-6.8)

C = 21168/53.808

C = 393.399 J/kg.°C

Thus the specific heat capacity of the brass = 393.399 J/kg.°C

To calculate the specific heat capacity of a metal, use the heat transfer formula considering that the heat lost by the metal is equal to the heat gained by the water when they reach thermal equilibrium. By rearranging the formula, you can solve for the metal's specific heat capacity using the given mass and temperature change for both the metal and the water.

To determine the specific heat capacity of an unknown metal, you can use the heat transfer formula:

q

= m c ΔT

where q is the heat transferred, m is the mass, c is the specific heat capacity, and ΔT is the change in temperature.

Since the metal and water reach thermal equilibrium, we know that the heat lost by the metal is equal to the heat gained by the water:

Heat lost by metal = Heat gained by water

mmetal cmetal (Tinitial,metal - Tfinal) = mwater cwater (Tfinal - Tinitial,water)

You can rearrange the formula to solve for the specific heat capacity of the metal:

cmetal = ⁰(mwater cwater (Tfinal - Tinitial,water)) ⁰(mmetal (Tinitial,metal - Tfinal))

Now, plugging in the values, you can calculate the specific heat capacity of the metal.

The type of mass movement that happens very slowly is Creep.

Explanation:

Mass movement, usually known as mass wasting, is that the descent movement of a mass of surface materials, like soil, rock or mud. This mass movement generally happens on hillsides and mountains because of the influence of gravity and may happen terribly slowly or terribly quickly.

Among these 4 forces, the only force acting on the plane at a distance is weight.

In fact, weight is due to gravity, which is a non-contact force (it acts also from a distance). All the other forces, instead, are due to the contact between the plane (or parts of it) with the surrounding air: without the air, all the other 3 forces (thrust, lift, drag) would not be present, while weight would be always present.