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AP Physics 2 : Buoyant Force

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Example Question #11 : Buoyant Force

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?

Possible Answers:

Neither ball will accelerate

There is no way to determine the relative acceleration of the two balls

Ball B will have greater acceleration

Ball A and Ball B will have the same acceleration

Ball A will have greater acceleration

Correct answer:

Ball A will have greater acceleration

Explanation:

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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Example Question #11 : Fluids

Determine the net force (including direction) on a gold $\left(19.32 \frac{g}{cm^3}\right)$ marble of radius .95cm in liquid mercury $\left(13.59 \frac{g}{cm^3}\right)$ .

Possible Answers:

.412N down

.206N up

.338N down

.412N up

0.206N down

Correct answer:

0.206N down

Explanation:

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:

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

$m=19.32*\left(\frac{4}{3}\pi*.95^3*10 \right )$

Plug in values:

$F_{net}=\frac{4}{3}\pi*.95^3*13.59*10-\left(19.32*\left(\frac{4}{3}\pi*.95^3 \right )*10 \right )$

$F_{net}= 487.819-693.5$

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

$F_{net}=-0.20568N$

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

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Example Question #13 : Buoyant Force

Determine the buoyant force on an object of volume 3.5m^3 in a fluid of density $1.5\frac{g}{mL}$

Possible Answers:

23N

95N

78N

51N

68N

Correct answer:

51N

Explanation:

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:

$F_{buoyant}=1.5*9.8*3.5$

$F_{buoyant}=51N$

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Example Question #14 : Buoyant Force

A balloon of mass $45\textup{ g}$ is inflated to a volume of $2\textup{ L}$ with pure CO_2 . Determine the buoyant force it will experience when submerged in water.

Possible Answers:

$15\textup{ N}$

$19.6\textup{ N}$

None of these

$3.4\textup{ N}$

$28.1\textup{ N}$

Correct answer:

$19.6\textup{ N}$

Explanation:

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:

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

F_b=19.6N

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Example Question #15 : Buoyant Force

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

Possible Answers:

Sink

It will be partially submerged

Float, but only because of surface tension

Float

Not enough information

Correct answer:

Sink

Explanation:

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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Example Question #16 : Buoyant Force

A block of mass 5kg and volume V = 3.5L is held in place under water. What is the instantaneous acceleration of the block, and in what direction, when it is released?

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

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

Possible Answers:

$3\frac{m}{s^2}, down$

$6\frac{m}{s^2},up$

$0\frac{m}{s^2}$

$6\frac{m}{s^2},down$

$3\frac{m}{s^2},up$

Correct answer:

$3\frac{m}{s^2}, down$

Explanation:

According to Archimedes's principle, when the block is placed under water, 3.5L of water are displaced. We can then calculate the buoyant force provided by the water:

$F_{buoyant} = m_{displaced}g$

Where:

$m= \rho_w V = \left ( 1.0\frac{kg}{L}\right )(3.5L) = 3.5kg$

Plugging in our values to the first expression:

$F_b = (3.5kg)\left ( 10\frac{m}{s^2}\right )$

F_b = 35N

Then we can use Newton's 2nd law to determine the acceleration of the block:

$F_{net}=ma$

There are two forces acting on the block, gravity and buoyancy, and they are in opposite directions. If we designate a downward force as positive, we get:

F_g -F_b = ma

Substituting in the expression for force due to gravity:

mg-F_b = ma

Rearranging for acceleration:

$a = \frac{mg-F_b}{m}$

Substituting in values:

$a = \frac{ (5kg)\left ( 10\frac{m}{s^2}\right )-35N}{5kg}$

$a = 3\frac{m}{s^2}$

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Example Question #11 : Buoyant Force

A scuba diver with a total mass m = 80kg is dressed so his density $\rho = 1,000 \frac{kg}{m^3}$ and is holding a spherical ball with a volume 0.2m^3 while submerged in water. What is the density of the ball if the upward acceleration of the ball and diver is $a = 1.5\frac{m}{s^2}$ ?

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

$\rho_w = 1000\frac{kg}{m^3}$

Possible Answers:

$424\frac{kg}{m^3}$

$281\frac{kg}{m^3}$

$623\frac{kg}{m^3}$

$974\frac{kg}{m^3}$

$817\frac{kg}{m^3}$

Correct answer:

$817\frac{kg}{m^3}$

Explanation:

We will start with Newton's 2nd law for this problem:

$F_{net} = ma$

Where there are 4 total forces acting on the scuba diver and ball: gravity and buoyancy acting on both the scuba diver and the ball. However, the diver has the same density as the water, so the gravitational and buoyancy forces acting on the diver will cancel out. If we designate an upward force as being positive, we can say:

$F_{b_{ball}}-F_{g_{ball}}=m_Ta$ (1)

Where:

$F_{b_{ball}}=m_{w,displaced}g$

$F_{g_{ball}}=m_bg$

m_T = m_d+m_b

Where:

$m_w = \rho_w V_b$

$m_b = \rho_b V_b$

So,

$F_b = \rho_w V_bg$

$F_{g}=\rho_bV_bg$

$m_T = m_d+\rho_bV_b$

Plugging these expressions back in to expression (1), we get:

$\rho_w V_bg-\rho_b V_bg = (m_d + \rho_b V_b)a$

Now let's start rearranging for the density of the ball:

$\rho_wV_bg - m_da = \rho_bV_b(a+g)$

$\rho_b = \frac{\rho_wV_bg-m_da}{V_b(a+g)}$

$\rho_b = \frac{\left ( 1000\frac{kg}{m^3}\right )(0.2m^3)\left ( 10\frac{m}{s^2}\right )-(80kg)\left ( 1.5\frac{m}{s^2}\right )}{(0.2m^s)(1.5\frac{m}{s^2}+10\frac{m}{s^2})}$

$\rho_b = 817\frac{kg}{m^3}$

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Example Question #18 : Buoyant Force

A block of mass 2kg is sinking in water at a constant velocity. There is a constant drag force of F_D = 3N acting on the block. What is the volume of the block?

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

$\rho_w = 1000\frac{kg}{m^3}$

Possible Answers:

1.7L

2.6L

2.3L

1.4L

Correct answer:

1.7L

Explanation:

We will start with Newton's 2nd law for this problem:

$F_{net}=ma$

Since the block is traveling at a constant velocity we can say:

$F_{net}=0$

There are 3 forces acting on the block: gravitational, buoyant, and drag force. If we denote a downward force being positive, the expression becomes:

F_g -F_b -F_d = 0

Where:

$F_g = m_{block}g$

$F_b = m_{w,displaced}g$

F_d = 3N

Substituting these in:

$m_{block}g - m_{w,displaced}g - 3N = 0$

Where according to Archimedes's principle:

$m_w = \rho_wV_b$

Plugging this in:

$m_{block}g - \rho_w V_bg - 3N = 0$

Rearranging for volume:

$m_{block}g - 3N = \rho_w V_bg$

$V_b = \frac{m_{block}g - 3N }{\rho_w g}$

Plugging in values:

$V_b =\left (\frac{(2kg)\left ( 10\frac{m}{s^2}\right )-3N}{\left ( 1000\frac{kg}{m^3}\right )\left ( 10\frac{m}{s^2}\right )} \right )\left ( \frac{1000L}{1m^3}\right )$

V_b = 1.7L

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Example Question #19 : Buoyant Force

A bowling ball with mass 6kg and radius 10cm is submerged under water and held in place by a string. What is the tension in the string?

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

$\rho_w = 1000\frac{kg}{m^3}$

Possible Answers:

26N

18N

57N

41N

Correct answer:

18N

Explanation:

Since the ball is held in place, we know that:

$F_{net}=0$

There are three forces acting on the ball: gravitational, buoyant, and tension. If we denote a downward force as positive, we get:

F_g -F_b - F_t=0 (1)

F_g = mg

$F_b = m_{w,displaced}g$

And using Archimedes's principal:

$m_w = \rho_w V_b$

Where:

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

Plugging all of these into expression (1), we get:

$m_bg - \frac{4}{3}\pi r^3 \rho_wg = F_t$

Plugging in our values, we get:

$F_t =(6kg)\left ( 10\frac{m}{s^2}\right ) - \frac{4}{3}\pi (0.10m)^3\left ( 1000\frac{kg}{m^3}\right )\left ( 10\frac{m}{s^2}\right )$

F_t= 18N

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Example Question #11 : Fluids

A semi-hollow, spherical ball with an empty volume of 0.8L is submerged in water and has an initial mass of 0.4kg . The ball develops a leak and water begins entering the ball at a rate of $0.6\frac{L}{min}$ . How long does it take before the buoyant force on the ball is equal to the gravitational force?

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

$\rho_w = 1000\frac{kg}{m^3}$

Possible Answers:

30s

50s

20s

10s

40s

Correct answer:

40s

Explanation:

We are asked when:

F_g = F_b

$m_bg = m_{w,displaced}g$

$m_b = m_{w,displaced}$

$m_b = \rho_wV_b$

Now we need to develop an expression for the mass in the ball using the rate at which water enters the ball:

$m_b = m_i + \dot{m}t$

Where:

$\dot{m} = \dot{V}\rho_wt$

$m_b = m_i + \dot{V}\rho_wt$

Plugging this into expression (1):

$m_i + \dot{V}\rho_wt= \rho_wV_b$

Rearranging for time, we get:

$t= \frac{\left ( \rho_wV_b- m_i \right )}{\dot{V}\rho_w}$

Plugging in our values, we get:

$t= \frac{\left ( 1\frac{kg}{L}\right )(0.8L)- (0.4kg)}{\left ( 0.6\frac{L}{min}\right )\left ( 1\frac{kg}{L}\right )}$

$t = \frac{2}{3}min = 40s$

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AP Physics 2 : Buoyant Force

Study concepts, example questions & explanations for AP Physics 2

All AP Physics 2 Resources

Example Questions

Example Question #11 : Buoyant Force

Example Question #11 : Fluids

Example Question #13 : Buoyant Force

Example Question #14 : Buoyant Force

Example Question #15 : Buoyant Force

Example Question #16 : Buoyant Force

Example Question #11 : Buoyant Force

Example Question #18 : Buoyant Force

Example Question #19 : Buoyant Force

Example Question #11 : Fluids

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