Fluid Statics - AP Physics 2

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Question

How much of an iceberg is submerged below the water if the density of ice is $917 \frac{\textup{kg}}{\textup{m}^3}$ and the density of water is $1000 \frac{\textup{kg}}{\textup{m}^3}$ ?

Answer

The volume of the submerged mass is the volume of the mass proportional to the density of the solid to the density of the fluid.

$V_{sub}= V_{solid}(\frac{\rho_{solid}}{\rho_{fluid}})$

Determine the amount of ice that is submerged.

$\frac{V_{sub}}{V_{solid}}= \frac{\rho_{solid}}{\rho_{fluid}}= \frac{917}{1000} = 91.7 %$

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Question

Which of the following is a statement of Archimedes' principle?

Answer

Archimedes' Principle states: When a body is completely or partially immersed in a fluid, the fluid exerts an upward force on the body equal to the weight of fluid displaced by the body. Thus, the buoyant force is dependent on the density of the liquid and volume of the immersed object, regardless of the object's mass or surface area.

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Question

A spherical ball of density $\rho =0.70 \frac{kg}{L}$ has a radius of . If the ball is placed on the surface of water and released, how much of the ball becomes submerged in the water?

$g = 10\frac{m}{s^2}$

Answer

We can use Archimedes's Principle to solve this problem which states that the upward buoyant force on an object is equal to the weight of the fluid that the object displaces. Therefore, if an object is floating, the upward buoyant force is equal to the weight of the object. So, let's begin by calculating that. We are given the radius of the object and told that it is a sphere. Therefore, we can use the expression for the volume of a sphere:

$V = \frac{4}{3}\pi r^3$

$V = \frac{4}{3}\pi (10cm)^3 = \frac{4000\pi}{3}cm^3$

$V = \frac{4000\pi}{3}cm^3\left ( \frac{1L}{1000cm^3}\right ) = \frac{4\pi}{3}L$

Now multiplying this by the density, we get:

$m = \left ( \frac{4\pi}{3}L\right )\left ( 0.70\frac{kg}{L}\right ) = 2.93kg$

This is also going to be the mass of the water displaced. We can therefore calculate the volume of water displaced:

$V = \frac{m}{\rho} = \frac{0.9\bar{3}kg}{\left ( 1.0\frac{kg}{L}\right )} = 2.93L$

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Question

If a object with a volume of $1:m^{3}$ is submerged below water, what is the net force acting on the object?

$\rho_{water}=1000: \frac{kg}{m^{3}}$ .

Answer

To answer this question, we'll need to consider the object submerged under water, and then use a force diagram in order to see which forces are acting on it.

The forces that are relevant to this question are the vertical forces, or those acting in the y-direction. Pointing down, we have the force due to gravity, which is the object's weight. Pointing upward is the bouyant force.

$\Sigma F_{y}=F_{B}-W$

Next, we can expand each of the variables in the above expression.

$\Sigma F_{y}=\rho Vg-mg$

$\Sigma F_{y}=(1000: \frac{kg}{:m^{3}})(1: m^{3})(9.8: \frac{m}{s^{2}})-(100: kg)(9.8: \frac{m}{s^{2}})$

$\Sigma F_{y}=8820: N$

Note that the depth in which the object was submerged is extraneous information.

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Question

A ball of mass is lightly dropped into a tub with a base of . After it sinks to the bottom, the water rises by . Determine the density of the ball.

Answer

The volume displaced will equal the volume of the ball.

$\rho=\frac{m}{V}$

$\rho=\frac{4 kg}{.0025m^3}$

$\rho=\frac{1600kg}{m^3}$

$\frac{1600kg}{m^3}\frac{1m^3}{100^3cm^2}\frac{1000cm^3}{1L}=1.6\frac{kg}{L}$

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Question

What is the net force on a ball of mass and volume of when it is submerged under water?

$g = 10\frac{m}{s^2}$

$\rho_{water} = 1.0\frac{g}{ml}$

Answer

The buoyant force on the ball is simply the weight of water displaced by the ball:

$F_b = V_{ball}\cdot\rho_{water}\cdot g = (0.2m^3)(1000\frac{kg}{m^3})(10\frac{m}{s^2}) = 2000 N$

The force of gravity on the ball is:

$F_g = mg = 15kg (10\frac{m}{s^2})= 150 N$

These forces oppose each other, so we can say:

$F_{net} = F_b - F_g = 2000N - 150N = 1850N$

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Question

A ball of mass is held under the surface of a pool. The instant it is released, it has an instantaneous acceleration of $4\frac{m}{s^2}$ toward the bottom of the pool. What is the volume of the ball?

$g = 10\frac{m}{s^2}$

$\rho_{water}=1.0\frac{kg}{l}$

Answer

The net force on the ball is expressed as:

$F_{net} = ma$

Since it is accelerating downward, we know that the force of gravity is stronger than the buoyant force, so we can write:

$F_{net}=F_g - F_b$

Substitute expressions for each variable:

$F_{net} = mg - V_{ball}\cdot\rho_{water}\cdot g$

Rearrange to solve for the volume of the ball:

$V_{ball} = \frac{m(g-a)}{\rho_{water}g} = \frac{(10kg)(10-4\frac{m}{s^2})}{(1000\frac{kg}{m^3})(10\frac{m}{s^2})}$

$V_{ball} = 0.006m^3$

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Question

Suppose that a hollow cylindrical object is floating on the surface of water. This object has a mass of 300g and is floating such that 4cm of its height is submerged under the surface of water, while 6cm of its height is above the water. How much mercury would need to be poured into this cylindrical object in order for it to sink?

$\rho_{H_2O}=1\frac{g}{cm^{3}}$

$\rho_{Hg}=13.6\frac{g}{cm^{3}}$

Answer

To answer this question, we'll need to make use of the concept of buoyancy and apply the following equation:

$F_{b}=\rho Vg$

Also, remember that in this equation, the density and volume are that of the fluid that is displaced, not that of the object!

Since we are told that the object has a mass of 300g and is initially floating, we can set the buoyant force equal to the weight of the object.

$F_{b}=W$

$\rho Vg=mg$

It's important to realize that the volume of the fluid displaced is going to be equal to that portion of the object's volume that is submerged underwater. Since we're told that the object is cylindrical, and that 4cm of its height is under water, we can set up the following relationship:

$V_{fluid: displaced}=Ah=A(4: cm)$

Where = Area of the cylinder and = height of cylinder underwater

Plugging this value into the above equation and canceling common units on both sides, we obtain:

$\rho Ahg=mg$

$\rho Ah=m$

$\left( 1\frac{g}{cm_{3}}\right )\left(A\right)\left(4cm\right)=300g$

$A=75:cm^{2}$

Now that we have found the area, we can calculate the mass that needs to be added to the cylinder in order to make it sink. To do this, we need to consider the scenario in which the cyclinder is completely submerged in the water the instant before it is about to sink. In this case, we're able to calculate the mass that needs to be added to the cylinder to make this happen.

$F_{b}^{'}=W^{'}$

$\rho V^{'}g=(m+x)g$

Where = the mass of mercury added to the cylinder

$\rho V^{'}=(m+x)$

$\rho Ah^{'}=(m+x)$

$(\frac{1g}{cm^{3}})\left ( 75cm^{2}\right )\left ( 10cm\right )=(300g+x)$

Thus far, we have determined that 450g of mercury needs to be added. Now, we just need to use the density of mercury in order to determine the volume needed.

$450g_{Hg}\left ( \frac{1cm^{3}}{13.6g} \right )\left ( \frac{1mL}{1cm^{3}} \right )=33mL$

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Question

A metal sample is suspended from a thread and submerged in a beaker of water. The metal sample does not touch the sides or bottom of the beaker. The beaker of water is on a laboratory scale as the metal sample is submerged. What happens to the scale reading as the sample is submerged?

Answer

Since the water is exerting an upward force $(F_B=\rho Vg)$ on the metal sample, it is receiving a force of equal magnitude pointing downward by Newton's third law. This downward force is transmitted by increased pressure in the water to the beaker and then to the scale.

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Question

How large would a balloon filled with helium need to be in order to lift a man? The density of helium is $\rho_{He}=0.164\frac{kg}{m^3}$ . The density of air is $\rho_{air}=1.29\frac{kg}{m^3}$ . The mass of the balloon is negligible.

Answer

The minimum size of the ballon will exert a buoyant force exactly equal to the gravitational force:

$mg=\rho Vg$

Now we have to be careful. The mass is not just the mass of the man, but it includes the mass of the helium, as well. Canceling the 's and using subscripts to be careful:
$100 kg +m_{He}=\rho_{air}V$

The mass of the helium is its density times its volume:

$100 kg +\rho_{he}V=\rho_{air}V$

Rearrange and solve for :

$V\left(1.29\frac{kg}{m^3}-0.164\frac{kg}{m^3}\right)=100kg$

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Question

Two spherical objects are placed in a bucket of water. One object has mass , while the other has mass . Both objects have the same diameter. The buoyant force acting on is __________ the buoyant force on

Answer

Buoyant forces can be thought of as the force caused by displacing the amount of water that was previously there. The buoyant force is the weight of the volume of the liquid displaced by the object. Since the two masses have the same diameter, they have the same volume and thus, the same buoyant force.

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Question

A heavy rock is placed in a bucket of water; the rock sinks to the bottom. What is the value of the buoyant force on the rock?

Answer

The buoyant force is the weight of the volume of water displaced by the immersed object. Since the rock is completely submerged, the buoyant force is the weight of water with the same volume as the rock. Despite the rock sinking, there is still a buoyant force; it is just less than the weight of the rock.

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Question

Suppose that two identical objects are submerged in water. Object A is submerged at a distance of 5m below the surface, whereas Object B is submerged at a distance of 10m below the surface. How does the buoyant force experienced by each object differ?

Answer

In this question, we're told that two identical objects are submerged in water. The only thing that differs between them is the distance under the surface of water at which they're submerged. We're then asked to determine how this affects the buoyant force that each one experiences.

To answer this, we'll need to remember the expression for buoyant force.

$F_{b}=\rho_{water}V_{water}g$

The above expression tells us that the magnitude of the buoyant force is proportional to the density of the water or fluid, the volume of the water displaced, and the acceleration due to gravity.

It's important to also realize that no where in this expression does it say that the buoyant force is related to the depth of the object. Therefore, because the two objects are the same, and because they're both fully submerged, they will both be displacing the same volume of water. Consequently, the buoyant force on each is the same.

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Question

Hanging from a scale is a sphere that is totally submerged in a pool of water. If the reading on the scale is , calculate the radius of the sphere.

Answer

The weight of the object is . If the scale reads , this tells us that the buoyancy force has a magnitude of . Mathematically:

We may relate these parameters by Archimedes' principle:

$\rho_{water} g V_{disp}=10N$

This allows us to solve for the volume of the sphere, and thus, the radius of the sphere.

$\frac{10N}{\rho_{water}g}=V_{disp}=V_{sphere}=\frac{10N}{1000\frac{kg}{m^3}\left(9.81\frac{m}{s^2} \right )}=0.001m^3$

Now we may use the formula for volume of a sphere to solve for the radius:

$V_{sphere}=\frac{4}{3}\pi r^3$

$r=\left(\frac{3}{4\pi}0.001m^3 \right )^{\frac{1}{3}}=0.0624m=6.24cm$

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Question

Determine the buoyant force on an object of volume in a fluid of density $1.5\frac{g}{mL}$

Answer

Use the equation for buoyant force:

$F_{buoyant}=\rho g V$

Where $\rho$ is the density of the medium around the object in question

is the gravitational acceleration near the surface of the earth

is the volume of the object in question

Convert $\frac{g}{mL}$ into $\frac{kg}{L}$

$1.5\frac{g}{mL}\frac{1000ml}{1L}\frac{1kg}{1000ml}=\frac{1.5kg}{L}$

Plug in values:

$F_{buoyant}=1.59.83.5$

$F_{buoyant}=51N$

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Question

Determine the net force on a copper ball $\left(\rho_{copper}=8.96\frac{kg}{L}\right)$ of radius submerged into water.

${\rho_{water}=1.0\frac{kg}{L}}$

Answer

Convert to and calculate volume:

$\frac{4}{3}\pi r^3=V_{sphere}$

$\frac{4}{3}\pi (.005)^3=V_{sphere}$

$5.2410^{-7}m^3=V_{sphere}$

Calculate buoyant force:

$F_{buoyant}=g\rho_{medium}V_{object}$

Plug in values:

$F_{buoyant}=9.81*5.2410^{-7}$

$F_{buoyant}=5.1410^{-6}N$

Calculate force due to gravity:

$F_g=\rho_{object}V_{object}g$

Plug in values and solve:

$F_{gravity}=4.610^{-5}N$

$F_{net}=F_1+F_2+...$

Plug in values:

$5.1410^{-6}+4.610^{-5}=F_{net}$

$F_{net}=5.1210^{-5}N$

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Question

Determine the net force (including direction) on a gold $\left(19.32 \frac{g}{cm^3}\right)$ marble of radius in liquid mercury $\left(13.59 \frac{g}{cm^3}\right)$ .

Answer

Consider all the forces on the gold marble:

$F_{net}=F_1+F_2+...$

$F_{net}=F_{buoyant}+F_{gravity}$

Recall the equation for buoyant force:

$F_{net}=V_{object}\rho_{object} g+m_{object}g$

Substitute:

$F_{net}=V_{object}\rho_{medium} g-mg$

Find the mass of the marble:

$D=\frac{m}{V}$

$m=19.32\left(\frac{4}{3}\pi.95^310 \right )$

Plug in values:

$F_{net}=\frac{4}{3}\pi.95^313.5910-\left(19.32\left(\frac{4}{3}\pi.95^3 \right )*10 \right )$

$F_{net}= 487.819-693.5$

$F_{net}=-205.68\frac{g\cdot m}{s^2}$

$F_{net}=-0.20568N$

Note how the buoyant force points up while the gravitational force points down.

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Question

Suppose that two different balls of equal volume are submerged and held in a container of water. Ball A has a density of $0.4: \frac{g}{cm^{3}}$ and Ball B has a density of $0.6: \frac{g}{cm^{3}}$ . After the two balls are released, both of them begin to accelerate up towards the surface. Which ball is expected to accelerate faster?

Answer

In this question, we're presented with a situation in which two balls of different densities but equal volumes are held underneath the surface of a container of water. Then, each ball is released and allowed to accelerate up to the surface. The question is to determine how the acceleration of each ball compares to the other. In order to answer this, let's start by imagining all of the forces acting on the submerged ball.

In the x-direction, the forces acting to the left of the ball are exactly equal to the forces acting on the right of the ball. Therefore, all of the forces acting in the x-direction cancel out, resulting in a net force of zero in the x-direction.

In the y-direction, we have to consider two things. The first is the upward buoyant force caused by the displacement of water. Since both balls have an identical volume, both of them displace the same amount of water. Consequently, both balls will experience the same upward buoyant force. However, we must also consider the downward force caused by the weight of the ball itself. In this scenario, the downward weight of Ball B is greater than that of Ball A.

We can write the net force acting on the ball in the y-direction as the difference between the upward buoyant force and the downward weight as follows:

$\Sigma F_{y}=B-W$

Due to the fact that Ball A has a smaller weight (a smaller component in the above equation), the result is that the net upward force is greater than that of Ball B. Thus, we would expect Ball A to have a greater acceleration.

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Question

A balloon of mass $45\textup{ g}$ is inflated to a volume of $2\textup{ L}$ with pure . Determine the buoyant force it will experience when submerged in water.

Answer

Use the equation for buoyant force:

$F_b=\rho|g|V$

Where

$\rho$ is the density of the medium

is the acceleration due to gravity

is the volume

Plugging in values:

$F_b=\frac{1kg}{L}|-9.8\frac{m}{s^2}|2L$

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Question

Will a ball of mass $10\textup{ kg}$ and radius $10 \textup{ cm}$ sink or float in water?

Answer

Determining density:

$d=\frac{m}{v}$

Volume of a sphere:

$v=\frac{4}{3}\pi r^3$

Combining equations:

$d=\frac{3m}{4\pi r^3}$

Converting to and plugging in values:

$d=\frac{3*10,000}{4\pi 10^3}$

$d=2.38\frac{g}{cm^3}$

It is denser than water, so it will sink.

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