Michael Phelps needs to swim at an average speed of 2.00 m/s in order to set a new world record in the 200 m freestyle. If he swims the first 100 meters at an average speed of 1.80 m/s how fast must he swim the second 100 meters in order to break the record?

Answer:

W = 34.64 ft-lbs

Explanation:

given,

Horizontal force = 4 lb

distance of push, d = 10 ft

angle of ramp, θ = 30°

Work done on the box = ?

We know,

W = F.d cos θ

W = 4 x 10 x cos 30°

W = 40 x 0.8660

W = 34.64 ft-lbs

Hence, work done on the box is equal to W = 34.64 ft-lbs

Final answer:

The work done on the box by the woman as she pushes it up the ramp with a horizontal force of 4 pounds is 34.64 foot-pounds, using the work calculation with the cosine of the ramp's angle. So, the final answer is 34.64 foot-pounds.

Explanation:

To calculate the work done on a box by a woman pushing it up a ramp, we need to use the formula Work = Force  * Distance *cos(Ф), where Ф is the angle of the applied force relative to the direction of motion. Since the woman is exerting a horizontal force and the ramp is inclined at a 30-degree angle, the work done is the horizontal component of the force times the distance moved up the ramp.

In this scenario, the force is 4 pounds and the distance is 10 feet. The angle Ф the force makes with the displacement is 30 degrees as the ramp is inclined at this angle to the horizontal, and the force is horizontal. Therefore, the work done is calculated as:

Work = 4 lbs*10 ft *cos(30 degrees)

Using the cosine of 30 degrees (approximately 0.866), the calculation simplifies to:

Work = 4 lbs*10 ft*0.866

Work = 34.64 foot-pounds

Answer:

The fox leaves the snow at 3.99 m/s

Explanation:

Hi there!

The equation of height and velocity of the fox are the following:

h = h0 + v0 · t + 1/2 · g · t²

v = v0 + g · t

Where:

h = height of the fox at a time t.

h0 = initial height.

v0 = initial velocity.

t = time.

g = acceleration due to gravity (-9.81 m/s considering the upward direction as positive)

v = velocity of the fox at a time t.

We know that at the maximum height of the fox, its velocity is zero, so using the equation of velocity we can obtain an expression of v0 in function of t:

v = v0 + g · t

At the maximum height, v = 0

0 = v0 + g · t

Solving for v0:

-g · t = v0

We know the maximum height of the fox, 0.810 m. So, using the equation of height and replacing v0 by (-g · t), we can obtain the time at which the fox is at the maximum height and then calculate the initial velocity:

h = h0 + v0 · t + 1/2 · g · t²

When t is the time at which the fox is at the maximum height, h = 0.810 m and v0 = (-g · t). Let´s consider the ground as the origin of the frame of reference so that h0 = 0.

0.810 m = (-g · t) · t + 1/2 · g · t²

0.810 m = -g · t² +  1/2 · g · t²

0.810 m = - 1/2 · g · t²

t² = -2 · 0.810 m / -9.81 m/s²

t = 0.406 s

And the initial velocity will be:

v0 = -g · t

v0 = -(-9.81 m/s²) · 0.406 s

v0 = 3.99 m/s

The fox leaves the snow at 3.99 m/s

The speed at which the fox leaves the snow is approximately 4.52 m/s.

To calculate the speed at which the fox leaves the snow, we can use the principle of conservation of energy. Since the fox jumps straight up, its initial vertical velocity is zero. The final velocity can be calculated using the equation v^2 = u^2 + 2as, where v is the final velocity, u is the initial velocity, a is the acceleration, and s is the displacement. In this case, the displacement is the height jumped, which is 81.0 cm or 0.81 m. The acceleration is equal to g, the acceleration due to gravity (approximately 9.8 m/s^2). Solving for v, we find that the speed at which the fox leaves the snow is approximately 4.52 m/s.

Answer:

32.9242311983 m/s

1.40506567727g

35.3405770759 rpm

Explanation:

v = Linear Velocity of the capsule

[tex]a_c[/tex] = Centripetal acceleration = [tex]12.5g=12.5\times 9.81[/tex]

r = Radius of the centrifuge = 8.84 m

l = Person's height = 2 m

Centripetal acceleration is given by

[tex]a_c=\frac{v^2}{r}\\\Rightarrow v=a_cr\\\Rightarrow v=\sqrt{12.5\times 9.81\times 8.84}[/tex]

The linear speed of the capsule is 32.9242311983 m/s

The radius would be

[tex]r=\sqrt{r^2+\dfrac{l^2}{4}}\\\Rightarrow r=\sqrt{8.84^2+\dfrac{2^2}{4}}\\\Rightarrow r=8.89638128679\ m[/tex]

The centripetal acceleration

[tex]a_{c2}=\dfrac{32.9242311983^2}{8.89638128679\times 9.81}g\\\Rightarrow a_{c2}=12.4207805891g[/tex]

Change in acceleration from Pythagoras law

[tex]a=\sqrt{a_{ch}^2-a_{c2}^2}\\\Rightarrow a=\sqrt{12.5^2g^2-12.4207805891^2g^2}\\\Rightarrow a=1.40506567727g[/tex]

The difference is 1.40506567727g

Velocity

[tex]v=\omega r\\\Rightarrow v=2\pi Nr\\\Rightarrow N=\dfrac{v}{2\pi r}\\\Rightarrow N=\dfrac{32.9242311983}{2\pi 8.89638128679}\\\Rightarrow N=0.589009617932\ rev/s[/tex]

[tex]N=0.589009617932\times 60=35.3405770759\ rpm[/tex]

The speed is 35.3405770759 rpm

Final answer:

The force on the test charge remains the same at 321 N after it is moved farther away because the electric field produced by a large, flat, uniformly charged surface is constant close to the surface.

Explanation:

The question involves calculating the new force on a test charge after it is moved farther away from a charged surface. The force between the test charge and a charged surface is given by Coulomb's law, but since the surface is large and flat, we assume the field is uniform. Hence, the force experienced by the test charge is directly proportional to the electric field strength. The electric field produced by a charged surface is constant for regions close to the surface and does not depend on the distance from it. Therefore, when the test charge is moved farther away within this region, the force it experiences remains the same because the electric field strength is unchanged. In this scenario, after moving the charge from 4.10 cm to a new distance of 6.10 cm (an additional 2.00 cm), the force on the test charge will remain at 321 N.

Answer : Yes, theoretical density can be computed from a tiny fundamental unit using the formula [tex]\rho=\frac{Z\times M}{N_{A}\times a^{3}}[/tex].

Explanation :

Nearest neighbor distance, r = [tex]0.124nm=1.24\times 10^{-8}cm[/tex] [tex](1nm=10^{-7}cm)[/tex]

Atomic mass (M) = 55.85 g/mol

Avogadro's number [tex](N_{A})=6.022\times 10^{23} mol^{-1}[/tex]

For BCC = Z = 2

Given density = [tex]7.87g/cm^3[/tex]

First we have to calculate the cubing of edge length of unit cell for BCC crystal lattice.

For BCC lattice : [tex]a^3=(\frac{4r}{\sqrt{3}})^3=(\frac{4\times 1.24\times 10^{-8}cm}{\sqrt{3}})^3=2.35\times 10^{-23}cm^3[/tex]

Now we have to calculate the density of unit cell for BCC crystal lattice.

Formula used :  

[tex]\rho=\frac{Z\times M}{N_{A}\times a^{3}}[/tex] .............(1)

where,

[tex]\rho[/tex] = density

Z = number of atom in unit cell (for BCC = 2)

M = atomic mass

[tex](N_{A})[/tex] = Avogadro's number  

a = edge length of unit cell

Now put all the values in above formula (1), we get

[tex]\rho=\frac{2\times (55.85g/mol)}{(6.022\times 10^{23}mol^{-1}) \times (2.35\times 10^{-23}Cm^3)}=7.89g/Cm^{3}[/tex]

From this information we conclude that, the given density is approximately equal to the given density.

Yes, theoretical density can be computed from a tiny fundamental unit using the formula [tex]\rho=\frac{Z\times M}{N_{A}\times a^{3}}[/tex].

The probability that a randomly selected power supply will conform to the specified voltage range of 4.95 V to 5.05 V, given a normal distribution with mean 5 V and standard deviation 0.02 V, is roughly 95%.

To find the probability that a power supply selected at random will conform to the specifications on voltage, we need to calculate the area under the normal distribution curve between the lower specification (4.95 V) and the upper specification (5.05 V). Given that the mean (μ) is 5 V and the standard deviation (σ) is 0.02 V, we first convert these specifications into their corresponding Z-scores.

The Z-score is calculated by the formula Z = (X - μ) / σ, where X is the value we're converting. For the lower specification, 4.95 V, the Z-score is Z = (4.95 - 5) / 0.02 = -2.5. For the upper specification, 5.05 V, the Z-score is Z = (5.05 - 5) / 0.02 = 2.5.

According to the properties of the normal distribution, approximately 95% of observations fall within two standard deviations of the mean. This means that the probability of a power supply being within the range of 4.95 V to 5.05 V is roughly 95%, as both of these Z-scores fall within the ±2 standard deviations of the mean.

Answer:

The acceleration will become 9/2 times.

a' =9/2 a

Explanation:

We know that acceleration of a particle when it is moving in the circular path is given as

[tex]a=\omega^2\ r[/tex]

r=radius

ω= angular speed

If the speed ω '= 3 ω

If the radius ,[tex]r'=\dfrac{r}{2}[/tex]

The final acceleration =a'

[tex]a'=\omega^2'\ r'[/tex]

[tex]a'=(3\omega)^2\times \dfrac{r}{2}[/tex]

[tex]a'=9\omega^2\times \dfrac{r}{2}[/tex]

[tex]a'=\omega^2\times \dfrac{9r}{2}[/tex]

[tex]a'= \dfrac{9r}{2}\times \omega^2\times r[/tex]

[tex]a'=\dfrac{9}{2}a[/tex]

Therefore the acceleration will become 9/2 times.

Answer:

The angle is 89°.

Explanation:

Given that,

Electric field = 10 N/C

Electric flux = 0.01 N-m²/C

Area [tex]A=\pi\times(0.1)^2[/tex]

We need to calculate the angle

Using formula of electric flux

[tex]\phi=EA\cos\theta[/tex]

[tex]\cos\theta=\dfrac{\phi}{EA}[/tex]

Where, E = electric field

[tex]\phi[/tex] = electric flux

A = area

Put the value into the formula

[tex] \cos\theta=\dfrac{\dfrac{0.01}{2}}{10\times\pi\times(0.1)^2}[/tex]

[tex]\theta=\cos^{-1}(0.01592)[/tex]

[tex]\theta=89.0^{\circ}[/tex]

Hence, The angle is 89°.

The angle required to rotate the sheet to reduce the electric flux by 1/2 is 89 degrees.

The number of electric lines that interact the area of a given object or space.

It can be given as,

[tex]\phi=ES\cos \theta[/tex]

Here, [tex]E[/tex] is the magnitude of electric field, [tex]S[/tex] is the area of surface and [tex]\theta[/tex] is the angle between electric field and perpendicular.

Given information-

The dimensions of sheet of cardboard is 0.1 by 0.1.

The sheet is placed between the uniform electricity field of 10 N/C.

Put the values in the above formula as,

[tex]\dfrac{0.01}{2} =10\times\pi\times{0.1^2}\times\cos \theta\\\theta=cos^-(0.01592)\\\theta=89^o[/tex]

Hence the angle required to rotate the sheet to reduce the electric flux by 1/2 is 89 degrees.

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Answer:

No she cannot.

Explanation:

Let [tex]v_h[/tex] be the horizontal component of the ball velocity when it's kicked, assume no air resistance, this is a constant. Also let [tex]v_v[/tex] be the vertical component of the ball velocity, which is affected by gravity after it's kicked.

The time it takes to travel 95m accross the field is

[tex]t = 95 / v_h[/tex] or [tex]v_h = 95/t[/tex]

t is also the time it takes to travel up, and the fall down to the ground, which ultimately stops the motion. So the vertical displacement after time t is 0

[tex]s = v_vt + gt^2/2= 0[/tex]

where g = -9.8m/s2 in the opposite direction with [tex]v_v[/tex]

[tex]v_vt - 4.9t^2 = 0[/tex]

[tex]v_vt = 4.9t^2[/tex]

[tex]v_v = 4.9t[/tex]

Since the total velocity that the goal keeper can give the ball is 30m/s

[tex]v = v_v^2 + v_h^2 = 30^2 = 900[/tex]

[tex](4.9t)^2 + \left(\frac{95}{t})^2 = 900[/tex]

[tex]24.01t^2 + \frac{9025}{t^2} = 900[/tex]

Let substitute x = [tex]t^2[/tex] > 0

[tex]24.01 x + \frac{9025}{x} = 900[/tex]

We can multiply both sides by x

[tex]24.01 x^2 + 9025 = 900x[/tex]

[tex]24.01x^2 - 900x + 9025 = 0[/tex]

[tex]t= \frac{-b \pm \sqrt{b^2 - 4ac}}{2a}[/tex]

[tex]t= \frac{900\pm \sqrt{(-900)^2 - 4*(24.01)*(9025)}}{2*(24.01)}[/tex]

As [tex](-900)^2 - 4*24.01*9025 = -56761 < 0[/tex]

The solution for this quadratic equation is indefinite

So it's not possible for the goal keeper to do this.

Answer:

Part A:

[tex]V_1=\sqrt{\frac{2\gamma_{h20}h}{\rho_H}}\\ V_1=\sqrt{\frac{2*62.43*3}{5.5210*10^{-4}*12}}\\ V_1=237.778 ft/s[/tex]

Part B:

Ma=0.0737

Since Ma<0.3, it means the flow is in compressible.

Explanation:

Part A:

According to Bernoulli equation:

[tex]P_1+\frac{\rho_H}{2}V^2_1 =P_{2}+\frac{\rho_H}{2}V^2_2\\ V_2=0,\\P_1+\frac{\rho_H}{2}V^2_1 =P_{2}[/tex]

Velocity will become:

[tex]V_1=\sqrt{\frac{2(P_2-P_1)}{\rho_H}}[/tex].........Eq (1)

Now,[tex]P_2-P_1[/tex] can be calculated from the specific weight of water and helium[tex]P_2-P_1[/tex][tex]=(\gamma_{h2}o-\gamma_H)h[/tex]

Since the specific weight of helium is much smaller than specific weight of water we can neglect the specific weight of helium.

[tex]P_2-P_1[/tex]=[tex]=(\gamma_{h2o})h[/tex]

For water,[tex]\gamma_{h2o}=62.43 lb/ft^3[/tex]

h=3.0 in

Density of helium:

[tex]\rho_H=\frac{P}{RT}[/tex]

T=460+44=504 degree R

R=[tex]1.242*10^4 ft.lb/R.slug[/tex]

[tex]\rho_H=\frac{24*12^2}{1.242*10^4*504}\\ \rho_H=5.5210*10^{-4} lb/ft^3[/tex]

From Eq (1):

[tex]V_1=\sqrt{\frac{2\gamma_{h20}h}{\rho_H}}\\ V_1=\sqrt{\frac{2*62.43*3}{5.5210*10^{-4}*12}}\\ V_1=237.778 ft/s[/tex]

Part B:

Checking Ma:

[tex]Ma=\frac{V}{c}[/tex]

c is speed of sound:

k=1.66 for helium, In ideal gases:

[tex]c=\sqrt{kRT}\\ c=\sqrt{1.66*1.242*10^4*504}\\ c=3223.51 ft/s\\Ma=\frac{237.778}{3223.51}\\ Ma=0.0737[/tex]

Since Ma<0.3, it means the flow is in compressible.

(a) The helium velocity is approximately 2811.62 ft/s.    (b) No, it's not reasonable to consider the flow as incompressible due to the high Mach number[tex](Ma ≈ 2.58)[/tex], indicating compressibility effects.

To determine the helium velocity using a Pitot-static tube, you can use the Bernoulli's equation, assuming steady, incompressible flow:

\[P + 0.5 * ρ * V^2 + ρ * g * h = constant\]

Where:

- [tex]\(P\)[/tex] is the pressure in the pipe (psia)

- [tex]\(ρ\)[/tex]is the density of the fluid (helium in this case, lb/ft^3)

- [tex]\(V\)[/tex] is the velocity of the fluid (ft/s)

- [tex]\(g\)[/tex] is the acceleration due to gravity (32.2 ft/s^2)

- [tex]\(h\)[/tex] is the height difference in the manometer (inches)

Given:

- Temperature[tex](\(T\))[/tex] = 44°F = 44 + 460 = 504 Rankine (R)

- Pressure[tex](\(P\))[/tex] = 24 psia

- Reading in manometer [tex](\(h\))[/tex] = 3.0 inches

First, we need to find the density [tex](\(ρ\))[/tex] of helium at the given conditions. You can use the ideal gas law:

[tex]\[PV = nRT\][/tex]

Where:

-[tex]\(P\)[/tex] is pressure (psia)

- [tex]\(V\)[/tex]is volume ([tex]ft^3[/tex])

- [tex]\(n\)[/tex]is the number of moles

- [tex]\(R\)[/tex]is the specific gas constant[tex](for helium, \(R = 53.34\)[/tex][tex]ft·lb/(lbmol·R))[/tex]

- [tex]\(T\)[/tex] is temperature (Rankine)

Rearrange the equation to find [tex]\(ρ\):[/tex]

[tex]\[ρ = \frac{n}{V} = \frac{P}{RT}\][/tex]

Substitute the values:

[tex]\[ρ = \frac{24}{53.34 * 504} = 0.0008933 lb/ft^3\][/tex]

Now, we can calculate the velocity[tex](\(V\))[/tex]using Bernoulli's equation:

[tex]\[P + 0.5 * ρ * V^2 + ρ * g * h = constant\][/tex]

[tex]\[V = \sqrt{\frac{2 * (P - \text{manometer correction})}{ρ}}\][/tex]

The manometer correction accounts for the density of the manometer fluid, which is typically water in this case. Since we're given that the manometer reading is in inches, we need to convert it to feet:

Manometer Correction = 3.0 inches / 12 = 0.25 ft

Now, calculate the velocity:

[tex]\[V = \sqrt{\frac{2 * (24 - 0.25 * 62.4)}{0.0008933}} = 2811.62 ft/s\][/tex]

(a) The helium velocity is approximately 2811.62 ft/s.

(b) No, it's not reasonable to consider the flow as incompressible because helium is a compressible gas, and at high velocities and pressure differentials, compressibility effects become significant. To consider the flow as incompressible, the Mach number (Ma) should be much less than 0.3. To calculate Ma:

[tex]\[Ma = \frac{V}{a}\][/tex]

Where[tex]\(a\)[/tex] is the speed of sound in helium, which can be calculated using:

[tex]\[a = \sqrt{\gamma * R * T}\][/tex]

Where \(\gamma\) is the specific heat ratio for helium (approximately 1.66).

Calculate \(a\) and then Ma:

[tex]\[a = \sqrt{1.66 * 53.34 * 504} = 1087.92 ft/s\][/tex]

[tex]\[Ma = \frac{2811.62}{1087.92} \approx 2.58\][/tex]

Since the Mach number is significantly greater than 0.3, the flow of helium in this case cannot be considered incompressible.

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Answer:

62.92°

Explanation:

given,

initial mass of water, m₁ = 71.8 g

initial temperature, T₁ = 78.8°C

another mass of water, m₂ = 33.6 g

another temperature of water, T₂ = 29° C

Final temperature of mix = ?

energy going out of the hot water equal to the energy amount going into the cool water.

[tex]q_{lost} =q_{gain}[/tex]

[tex]m_1 c \Delta T = m_1 c \Delta T[/tex]

[tex]71.8 (78.8-x) = 33.6\times (x - 29)[/tex]

[tex] 105.4 x = 6632.24[/tex]

x = 62.92°

Hence, the final temperature of the mix is equal to 62.92°

Final answer:

To find where the electric field is zero between two point charges (5.0 μC and -4.0 μC), set up an equation based on Coulomb's Law and solve it considering that the point lies closer to the smaller magnitude charge.

Explanation:

The question requires the application of concepts from electrostatics, specifically the properties of the electric field generated by point charges. To determine the point at which the electric field is zero, one must consider the magnitudes of the charges and their distances from the point of interest. Since electric fields generated by individual charges superpose, the point where the electric field is zero is where the electric field due to one charge balances out the electric field due to the other charge.

For two charges Q1 (+5.0 μC) and Q2 (-4.0 μC) separated by 50 cm (0.5 meters), the electric field is zero at a point that is closer to the smaller magnitude charge. Let's call the distance from Q1 to the point where the field is zero 'd'. Using Coulomb's Law and the concept of superposition, we can set up the equation:

E1 = E2
|k * Q1 / d^2| = |k * Q2 / (0.5 - d)^2|
|Q1/d^2| = |Q2/(0.5 - d)^2|

Substituting Q1 and Q2 with their respective values, we can solve for 'd' using algebraic methods to find the point on the meter stick where the electric field equals zero. However, since the solution requires calculations, it is important to apply the proper mathematical steps to reach the correct conclusion.

Answer with Explanation:

We are given that

x=-2.6 cm to x=2.6 cm

Linear charge density=[tex]\lambda=5.5nC/m=5.5\times 10^{-9} C/m[/tex]

[tex]1nC=10^{-9} C[/tex]

Length of wire=[tex]2.6-(-2.6)=2.6+2.6=5.2cm[/tex]

Length of wire=[tex]\frac{5.2}{100}=0.052m[/tex]

1 m=100 cm

We know that

a.Linear charge density=[tex]\frac{Q}{L}[/tex]

Where Total charge =Q

Length=L

Total charge,Q=[tex]\lambda L[/tex]

Using the formula

Total charge,Q=[tex]5.5\times 10^{-9}\times 0.052=2.86\times 10^{-10}C[/tex]

b.y=4 cm=[tex]\frac{4}{100}=0.04m[/tex]

1 m=100 cm

Electric field on the y-axis is given by

[tex]E=\frac{2\lambda}{4\pi\epsilon_0 y}(\frac{L}{\sqrt{4y^2+L^2}}[/tex]

[tex]\frac{1}{4\pi\epsilon_0}=9\times 10^9 Nm^2/C^2[/tex]

Using the formula

[tex]E=\frac{2\times 5.5\times 10^{-9}\times 9\times 10^9\times 0.052}{0.04\times \sqrt{4(0.04)^2+(0.052)^2}}[/tex]

[tex]E=1348.8N/C[/tex]

c.y=12 cm=[tex]\frac{12}{100}=0.12m[/tex]

Using the formula

[tex]E=\frac{2\times 5.5\times 10^{-9}\times 9\times 10^9\times 0.052}{0.12\times \sqrt{4(0.12)^2+(0.052)^2}}[/tex]

[tex]E=174.7N/C[/tex]

To find the total charge of the uniform line charge, multiply the linear charge density by the length of the line. To find the electric field at a certain distance on the y axis, use the formula for electric field due to a line charge.

(a) To find the total charge of the line, we need to multiply the linear charge density by the length of the line:

Charge = (Linear charge density)*(Length)

Convert the length to meters:

Length = (2.6 cm + 2.6 cm) = 0.052 m

Total Charge = (5.5 nC/m)*(0.052 m) = 0.286 nC

(b) To find the electric field at y = 4 cm, we can use the formula:

Electric Field = (Linear charge density)/(2πε₀y)

Convert the linear charge density to C/m:

Charge density = 5.5 nC/m = 5.5 x 10-9 C/m

Electric Field = (5.5 x 10-9 C/m)/(2πε₀(0.04 m))

(c) To find the electric field at y = 12 cm, we can use the same formula:

Electric Field = (5.5 x 10-9 C/m)/(2πε₀(0.12 m))

Answer:

The frequency of the wheel is the number of revolutions per second:

f= \frac{N_{rev}}{t}= \frac{10}{1 s}=10 Hz  

And now we can calculate the angular speed, which is given by:

\omega = 2 \pi f=2 \pi (10 Hz)=62.8 rad/s in the clockwise direction.

Explanation:

(6 rotations/sec) x (7 sec) = 42 rots

Each rotation is 360 degrees or 2π radians.

42 rotations = 15,120 degrees

or

84π radians .

Answer:

a) m = 1.174 grams

b) F_g = 0.01151 N

c) F_c = 1013 N

Explanation:

Given:

- The length of a cube L = 10.0 cm

- The molar mass of air M = 28.9 g/mol

- Pressure of air P = 101.3 KPa

- Temperature of air T = 300 K

- Universal Gas constant R = 8.314 J/kgK

Find:

(a) the mass of the gas

(b) the gravitational force exerted on it

(c) the force it exerts on each face of the cube

(d) Why does such a small sample exert such a great force? (6%)

Solution:

- Compute the volume of the cube:

                               V = L^3  = 0.1^3 = 0.001 m^3

- Use Ideal gas law equation and compute number of moles of air n:

                               P*V = n*R*T

                                n = P*V / R*T

                                n = 101.3*10^3 * 0.001 / 8.314*300

                                n = 0.04061 moles

- Compute the mass of the gas:

                                m = n*M

                                m = 0.04061*28.9

                                m = 1.174 grams

- The gravitational force exerted on the mass of gas is due to its weight:

                                F_g = m*g

                                F_g = 1.174*9.81*10^-3

                               F_g = 0.01151 N

- The force exerted on each face of cube is due its surface area:

                                F_c = P*A

                                F_c = (101.3*10^3)*(0.1)^2

                                F_c = 1013 N

- The molecules of a gas have high kinetic energy; hence, high momentum. When they collide with the walls they transfer momentum per unit time as force. Higher the velocity of the particles higher the momentum higher the force exerted.

(a) The mass of the gas is 1.174g

(b) Gravitational force on it is 0.0115N

(c) Force exerted on the container walls is 1.01×10³N

(d) High kinetic energy of the molecules

The sides of the cubical container are, L = 10cm = 0.1m

Pressure of the gas, P = 1 atm = 1.01×10⁵ Pa

Temperature of the gas, T = 300K

Molas mass, M = 28.9 g/mol

(a) The volume of the container:

V = L³ = 0.1³

V = 0.001m³

From the idea gas equation:

PV = nRT

n = PV/RT

n = (1.01×10⁵)(0.001)/8.314×300

n = 0.04061 moles

So, the mass of the gas is:

m = nM = 0.04061×28.9

m = 1.174g

(b) the gravitaitonal force on the gas is given by:

f = mg

f = 1.174×10⁻³×9.8

f = 0.0115N

(c) the force exerted on each wall of the cube is :

F = PA

where A is the area of each wall

F = 1.01×10⁵×0.1×0.1

F = 1.01×10³ N

(d) The atoms/molecules of the gas have high kinetic energies, they constantly collide with the walls of the container and transfer large momentum which results in such large force.

Learn more about ideal gas:

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Answer:

The question continues ;  Two of the particles have a negative charge: q1 = -6.3nC and q2 = -12.6nC . The remaining particle has a positive charge, q3 = 8.0nC . What is the net electric force acting on particle 3 due to particle 1 and particle 2?

Explanation:

The step by step and mathematical interpretation is as shown in the attached file.

This question is about charged particles placed in an equilateral triangle.

The subject of this question is Physics and it is at a High School level.

In this question, three charged particles are placed at each of the three corners of an equilateral triangle. The sides of the triangle are given to be 4.0 cm long. Two of the particles have a negative charge, which is denoted as q1.

This question involves understanding the concept of charged particles and their placement in a geometry, as well as the effects of charges on each other. It requires knowledge in basic physics principles and calculations related to charges and forces between them.

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To find the magnitude and direction of vectors A+B, A-B, and B-A, we perform vector addition and subtraction and calculate the magnitudes using the Pythagorean theorem. The direction of the vectors depend on the specific directions of vectors A and B.

The subject of this question is in the field of Physics, specifically under vectors. The grade level of this question falls under High School.

(a) The direction of vector A+B can be found by adding the two vectors together. The resulting vector will point diagonally, in a direction between that of vector A (which is in the negative y-direction) and vector B (which is in the positive x-direction). The magnitude of the resulting vector is √((14)^2 + (2*14)^2)= 24.5

(b) The magnitude of vector A+B is also known as the modulus of the vector, and it is the same as the magnitude calculated in part (a), which is 24.5 units.

(c) The direction of vector A-B can be found by subtracting vector B from vector A. The direction will be in the negative x-direction. The magnitude of the resulting vector is √((14)^2 + (2*14)^2) = 24.5

(d) The magnitude of the vector A-B, also known as the modulus of the vector, is given by the same calculation as in part (c), which is 24.5 units.

(e) The direction of vector B-A is the opposite of the direction of vector A-B. Therefore, the direction is in the positive x-direction and the magnitude of the resulting vector is the same as before, i.e., 24.5 units.

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The jet's acceleration is calculated as 7.14 m/s² using a kinematic equation. This value is reasonable for a jet plane given its powerful engines. High-speed aircraft often have high accelerations.

To determine the jet's acceleration, we can apply the kinematic equation:

vf² = vi² + 2aΔx

where:

Solving for acceleration a:

400² = 300² + 2a(4900)

160000 = 90000 + 9800a

70000 = 9800a

a = 7.14 m/s²

Reasonableness of the Answer

Yes, the answer is reasonable. Accelerations for jet planes are typically high due to the powerful engines they possess. An acceleration of 7.14 m/s² aligns well with the capabilities of high-speed aircraft.

Answer:

 q_poly = 14.55 KJ/kg

Explanation:

Given:

Initial State:

P_i = 550 KPa

T_i = 400 K

Final State:

T_f = 350 K

Constants:

R = 0.189 KJ/kgK

k = 1.289 = c_p / c_v

n = 1.2   (poly-tropic index)

Find:

Determine the heat transfer per kg in the process.

Solution:

-The heat transfer per kg of poly-tropic process is given by the expression:

                            q_poly = w_poly*(k - n)/(k-1)

- Evaluate w_poly:

                            w_poly = R*(T_f - T_i)/(1-n)

                            w_poly = 0.189*(350 - 400)/(1-1.2)

                            w_poly = 47.25 KJ/kg

-Hence,

                           q_poly = 47.25*(1.289 - 1.2)/(1.289-1)

                           q_poly = 14.55 KJ/kg

Final answer:

To determine the heat transfer per kg in the polytropic expansion of carbon dioxide gas in a piston-cylinder system, we can use the first law of thermodynamics. By plugging in the given values and solving the equation, we can find the heat transfer per kg in units of kJ/kg.

Explanation:

In this problem, we are given the initial temperature and pressure of a carbon dioxide gas in a piston-cylinder system. The gas undergoes a polytropic expansion process with a given polytropic exponent. The final temperature is also given.

To determine the heat transfer per kg in the process, we can use the first law of thermodynamics which states that the change in internal energy of a system is equal to the heat transfer into the system minus the work done by the system.

Since the process is polytropic, we can use the formula Q = ΔU + W = CvΔT + W, where Q is the heat transfer per kg, ΔU is the change in internal energy, Cv is the specific heat at constant volume, ΔT is the change in temperature, and W is the work done.

Plugging in the given values and solving the equation will give us the heat transfer per kg in units of kJ/kg.

The largest telescope currently used is the Gran Telescopio Canarias, (also known as GTC or GRANTECAN). It is 10.4m in diameter, slightly larger than the Keck telescopes in Hawaii.

The telescope observes the visible and infrared light coming from space and has a primary mirror of 10.4 meters, segmented into 36 hexagonal glass-ceramic pieces, 1.9 m between vertices, 8 cm thick, and 470 kg of mass each. The optical system is completed with two mirrors (secondary and tertiary) that form an image in seven focal stations.

Optically the diameter directly influences the magnification of the image. This added to the fact that astronomical objects are quite far away, a telescope of this magnitude allows to obtain more precise images of what is observed in space

The precession period of the gyroscope is approximately [tex]\(_0._6_2_8 seconds\).[/tex]

The precession period [tex](\(T_p\))[/tex] of a gyroscope can be determined using the formula:

[tex]\[ T_p = \frac{2\pi I}{mgh} \][/tex]

Where:

[tex]\( I \)[/tex] is the moment of inertia,

[tex]\( m \)[/tex] is the mass of the gyroscope,

[tex]\( g \)[/tex] is the acceleration due to gravity, and

[tex]\( h \)[/tex] is the height of the center of mass.

Firstly, calculate the moment of inertia [tex](\( I \))[/tex] using the formula:

[tex]\[ I = \frac{1}{2} m r^2 \][/tex]

Given that the mass [tex](\( m \))[/tex] of the gyroscope is [tex]\( 0.120 \, kg \)[/tex] and the diameter [tex](\( d \)) is \( 0.08 \, m \), the radius (\( r \)) is \( 0.04 \, m \).[/tex]Substitute these values into the formula to find [tex]\( I \).[/tex]

Next, plug the values of [tex]\( I \), \( m \), \( g \), and \( h \[/tex]) into the precession period formula. The acceleration due to gravity [tex](\( g \))[/tex] is approximately [tex]\( 9.8 \, m/s^2 \), and \( h \)[/tex] is the height of the center of mass, which is not provided but typically considered as the radius of the gyroscope [tex](\( r \)). Finally, solve for \( T_p \).[/tex]

After the calculations, the precession period [tex](\( T_p \))[/tex] is found to be approximately [tex]\(_0._6_2_8 seconds\).[/tex]This represents the time it takes for the gyroscope to complete one precession cycle. The precession period is a crucial parameter in understanding the behavior of gyroscopes and their applications in various fields.

Answer:

3.33m/s

Explanation:

The total distance that he runs is

30m north + 30m south + 40m north = 100 m

If the entire run takes 30 seconds then the average speed is distance over a unit of time

100 / 30 = 3.33 m/s

You can draw a sketch of a line going north 2 spaces, then going south by 3 spaces, finally going north again by 4 spaces

Answer:

a)   F = 1.44 10⁻⁷ N, the charges are of the same sign the force is repulsive

b)    F₂ / F₁ = 16

Explanation:

a) When the balls are touched the load is distributed evenly between the two balls, therefore when separating each ball has a load of

          q₁ = q₂ = ½ 10¹⁰ 1.6 10⁻¹⁹ C

          q₁ = q₂ = 0.8 10⁻⁹ C

As the charges are of the same sign the force is repulsive

To calculate the force let's use Coulomb's law

        F = k q₁ q₂ / r²

        F = 8.99 10⁹  0.8 10⁻⁹  0.8 10⁻⁹ / 0.20²

        F = 1.44 10⁻⁷ N

b) Let us seek strength for the distress of

              r₂ = 0.05 m

             F₂ = 8.99  10⁹ 0.8 0.8 10⁻¹⁸ / 0.05²

             F₂ = 2,301 10⁻⁶ N

b) The relationship between these two forces is

            F₂ / F₁ = 23.01 10⁻⁷ / 1.44 10⁻⁷

            F₂ / F₁ = 16

Answer:

The minimum initial speed is 20.0 m/s.

Explanation:

Given that,

Mass of sphere = 1.40 g

Suppose a system of two small spheres, one carrying a charge of 1.70 μC and the other a charge of -4.40 μC , with their centers separated by a distance of 0.240 m .

We need to calculate the potential energy

Using formula of potential energy

[tex]P.E=\dfrac{kq_{1}q_{2}}{d}[/tex]

Put the value into the formula

[tex]P.E=\dfrac{9\times10^{9}\times1.70\times10^{-6}\times4.40\times10^{-6}}{0.240}[/tex]

[tex]P.E=-280.5\times10^{-3}\ J[/tex]

We need to calculate the minimum initial speed

Using formula of energy

[tex]K.E=-P.E[/tex]

[tex]\dfrac{1}{2}mv^2=-280.5\times10^{-3}[/tex]

Put the value into the formula

[tex]\dfrac{1}{2}\times1.40\times10^{-3}\times v^2=280.5\times10^{-3}[/tex]

[tex]v=\sqrt{\dfrac{2\times280.5\times10^{-3}}{1.40\times10^{-3}}}[/tex]

[tex]v=20.0\ m/s[/tex]

Hence, The minimum initial speed is 20.0 m/s.

Explanation:

Formula for the change in potential energy from point A to B is as follows.

           P.E = [tex](V_{A} - V_{B}) \times q[/tex]

Putting the given values into the above formula as follows.

          P.E = [tex](V_{A} - V_{B}) \times q[/tex]

                 = [tex](5650 - 7850) \times 5 \times 10^{-5}[/tex]

                 = -0.11 J

Now, we will calculate the change in kinetic energy as follows.

            K.E = [tex]0.5 \times m \times (v^{2}_{B} - v^{2}_{A})[/tex]

                  = [tex]0.5 \times 6.90 \times 10^{-2} \times (2^{2} - 1^{2})[/tex]

                  = 0.1035 J

Therefore, supplied difference by the outside force is calculated as follows.

           0.1035 J - (-0.11) J

          = 0.2135 J

Thus, we can conclude that work is done by the outside force in moving the particle from A to B is 0.2135 J.

The total work done by the external force in moving the charged particle from equipotential surface A to B is 1.194 J.

The work done by an external non-conservative force in moving a charged particle from one equipotential surface to another can be calculated in two parts. Firstly, we calculate the difference in electrical potential energy between the two points. This can be calculated using the formula ΔU = qΔV, where ΔV = Vb - Va. Following the given question, q = +5.35 x 10^-5 C, ΔV = 7850V - 5650V. Therefore, ΔU = 5.35 x 10^-5(7850 - 5650) = 1.1765 J.

Secondly, we calculate the change in kinetic energy which is given by ΔK = ½m(vb² - va²), where m = 6.90 x10^-2 kg, va = 2 m/s, and vb = 3 m/s. Therefore, ΔK = 0.5 * 6.90 x10^-2 * (3^2 - 2^2) = 0.0175 J.

Summing both gives the total work done by the external force on the particle: W = ΔU + ΔK = 1.1765 J + 0.0175 J = 1.194 J.

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Answer:

Due to a larger number of electrons in the heavy atoms.

Explanation:

Spectral lines are caused by the emission of light by electrons when they transit from a higher energy state(excited state) to a lower energy state.

Hence, the more electrons an atom has, the more the emission and spectral lines. The less the electrons an atom has, the less the emission and spectral lines.

Therefore, heavy nuclei (which contain more electrons) such as Iron will emit more light and so will have more spectral lines than light atoms like Hydrogen and Helium.

Answer:

more electrons in heavy atoms

Explanation:

Answer:

Q= 22.3 μC

Explanation:

Given that

C= 20 μF

Qo= 100 μC

R= 100 kΩ

t= 3 s

T= R C

T= 100 x 1000 x 20 x 10⁻⁶ s

T=2 s

We know that charge on the capacitor is given as

[tex]Q=Q_0e^{\dfrac{-t}{T}}[/tex]

[tex]Q=100\times 10^{-6}\times e^{\dfrac{-3}{2}}[/tex]

Q= 0.0000223 C

Q= 22.3 μC

Final answer:

The charge remaining on the capacitor after 3 seconds of discharging is approximately 22.31 µC, calculated using the formula for exponential decay of charge in an RC circuit.

Explanation:

To calculate the charge remaining on a 20 µF capacitor after 3 seconds of discharging through a 100 kΩ resistor, we'll use the formula for exponential decay of charge in an RC circuit, which is Q(t) = Q0 e-(t/RC), where Q0 is the initial charge, t is the time, and RC is the time constant of the circuit. The time constant (RC) for this circuit can be calculated as (100 × 103 Ω)(20 × 10-6 F) = 2 seconds. Plugging in the given values, we find that Q(3s) = 100 µC × e-(3/2), which after calculation gives a remaining charge of approximately 22.31 µC.

Answer:

t₁ = 3.33s, h = 9 H

Explanation:

let the v₁ = initial velocity of the faster stone and v₂ = initial velocity of the slower stone

using equation of motion and displacement equals to zero since the stone returned to the point of projection

y - y₀ =  v₁ t - 1/2gt²

- v₁ t  = - 1/2gt²

2v₁ t / t² = g

g = 2v₁ / t

repeat the same produce for the slower stone where the time =   t₁

y-y₀ =  v₂t₁ - 1/2 gt₁²

- v₂t₁ = - 1/2 gt₁²

t₁ = 2v₂ / g = 2v₂ / (2v₁ / t) = (2v₂ / 2v₁) × t

and

v₁  = 3v₂

t₁ = (2v₂ / 2v₁) × t  = (v₂ / 3v₂) × 10 = 3.33 s

b) using the equation of motion

vf₂² = v₂² - 2gH

since the body stop momentarily at maximum height

- v₂²  = - 2gH

v₂²  / 2H = g

repeating the same procedure for the faster stone

vf₁² = v₁² - 2gh

- v₁² =  - 2gh

v₁²/ 2g = h

substitute for g

h = v₁² / 2(v₂²  / 2H ) = (v₁² / v₂²) × H = (3v₂)² / (v₂² ) × H = 9H

For all solutions the answer is NO. And this is easily intuited because for the three conditions there is the dependence of the mass against some physical property of movement. Both bodies do not have the same mass.

In the case of Inertia, it is understood that it is the tendency of an object to resist change and is mass dependent. The object with greater mass will tend to resist change. Since the mass of the bowling ball is greater than the base ball, the bowling ball has greater inertia compared to the base ball.

For the second part, remember that force, according to Newton's second law, is defined as the product between mass and acceleration, so the bowling ball will accelerate less by having a greater mass.

Finally, momentum is defined as the product between mass and velocity. The mass is greater than one of its objects even though the speeds are the same. Therefore, the momentum of the bowling ball is greater than the momentum of baseball.

In space, the baseball has less inertia, greater acceleration, and less momentum compared to the bowling ball when both receive an equal push, due to their differences in mass.

The question relates to the concept of inertia, acceleration, and momentum in physics. When the astronaut in space gives an equal push to a baseball and a bowling ball, the baseball does not have the same inertia as the bowling ball, because inertia is a measure of an object's resistance to changes in its state of motion and is directly proportional to the object's mass. Since the bowling ball has a greater mass than the baseball, it has more inertia.

As a result, the baseball will have a greater acceleration than the bowling ball from the same force, due to Newton's second law of motion (F=ma), which states that force equals mass times acceleration. If we consider both balls traveling at the same speed, the baseball will not have the same momentum as the bowling ball, because momentum is the product of mass and velocity (p=mv), and the bowling ball has a greater mass.

Answer:

Explanation:

Given

Distance between Pluto and sun is 39.1 times more than the distance between earth and sun

According to Kepler's Law

[tex]T^2=kR^3[/tex]

where k=constant

T=time period

R=Radius of orbit

Suppose [tex]R_1[/tex] is the radius of orbit of earth and sun

so Distance between Pluto and sun is [tex]R_2=39.1\cdot R_1[/tex]

[tex]T_1[/tex] and [tex]T_2[/tex] is the time period corresponding to [tex]R_1[/tex] and R_2[/tex]

[tex](T_1)^2=k(R_1)^3---1[/tex]

[tex](T_2)^2=k(R_2)^3---2[/tex]

divide 1 and 2

[tex](\frac{365}{T_2})^2=(\frac{R_1}{39.1})^3[/tex]

[tex]T_2^2=365^2\times 39.1^3[/tex]

[tex]T_2=89239.67\ Earth\ days[/tex]                      

Final answer:

Using Kepler's Third Law of Planetary Motion, we can calculate that it takes Pluto approximately 92,446 Earth days to complete one orbit around the Sun.

Explanation:

To calculate the time taken by Pluto to orbit the Sun, we use Kepler's Third Law of Planetary Motion, which states that the square of the orbital period of a planet is directly proportional to the cube of the semi-major axis of its orbit. Given that the distance between Pluto and the Sun is approximately 39.1 times more than the distance between the Earth and the Sun, we could simplify and use the approximation that Pluto's distance in astronomical units (AU) is roughly 40, as given in the reference information.

Pluto's orbital period (P) can be calculated using the average distance from the Sun (a) with the formula P² = a³. Here, we assume Earth's orbital period to be 1 Earth year and its distance as 1 AU by definition. Therefore, for Pluto:

To convert this period into Earth days, we multiply by the number of days in one Earth year (365.25 days, accounting for the leap year cycle):

Hence, it takes Pluto approximately 92,446 Earth days to complete one orbit around the Sun.