A solid conducting sphere with radius RR that carries positive charge QQ is concentric with a very thin insulating shell of radius 2RR that also carries charge QQ. The charge QQ is distributed uniformly over the insulating shell.

A. Find the magnitude of the electric field in the region 02R. Express your answer in terms of the variables R, r, Q, and constants
π
and
ε
0.

Answer:

The two values of θ are 41.03° and 138.97°.

Explanation:

The force on a current carrying wire is given by the following equation:

[tex]\vec{F} = I\vec{L}\times \vec{B}[/tex]

The cross-product can be written with a sine term:

[tex]F = ILB\sin(\theta)\\0.025 = IL(0.04)\sin(\theta)\\\sin(\theta) = \frac{0.025}{0.04IL}\\\theta = \arcsin(\frac{0.025}{0.04IL})[/tex]

If we assume that the wire is 0.28 m long and the current is 3.40 A, then sin(θ) becomes 0.6565.

Finally, the two values of θ are 41.03° and 138.97°.

Answer:

1058.78 ft/sec

Explanation:

Horizontal Component of Velocity; This is the velocity of a body that act on the horizontal axis. I.e Velocity along x-axis

The horizontal velocity of a body can be calculated as shown below.\

Vh = Vcos∅.......................... Equation 1

Where Vh = horizontal component of the velocity, V = The velocity acting between the horizontal and the vertical axis, ∅ = Angle the velocity make with the horizontal.

Given: V = 1178 ft/sec, ∅ = 26°

Substitute into equation 1

Vh = 1178cos26

Vh = 1178(0.8988)

Vh = 1058.78 ft/sec

Hence the horizontal component of the velocity = 1058.78 ft/sec

Answer:

223 degree

Explanation:

We are given that

Magnitude of resultant vector= 8 units

Resultant vector makes an angle with positive -x in counter clockwise direction

[tex]\theta=43^{\circ}[/tex]

We have to find the magnitude and angle of the equilibrium vector.

We know that equilibrium vector is equal in magnitude  and in opposite direction  to the given vector.

Therefore, magnitude of equilibrium vector=8 units

x-component of a  vector=[tex]v_x=vcos\theta[/tex]

Where v=Magnitude of vector

Using the formula

x-component of resultant  vector=[tex]v_x=8cos43=5.85[/tex]

y-component of resultant vector=[tex]v_y=vsin\theta=8sin43=5.46[/tex]

x-component of equilibrium vector=[tex]v_x=-5.85[/tex]

y-component of equilibrium vector=[tex]-v_y=-5.46[/tex]

Because equilibrium vector lies in III quadrant

[tex]\theta=tan^{-1}(\frac{v_x}{v_y})=tan^{-1}(\frac{-5.46}{-5.85})=43^{\circ}[/tex]

The angle [tex]\theta'[/tex]lies in III quadrant

In III quadrant ,angle =[tex]\theta'+180^{\circ}[/tex]

Angle of equilibrium vector measured from positive x in counter clock wise direction=180+43=223 degree

Answer:

[tex]r=44m[/tex]

Explanation:

β is calculated as:

[tex]\beta =(10dB)log_{10}(I/I_{o} )\\ I=I_{o}10^{\frac{\beta }{10dB} }\\ I=(1.0*10^{-12}W/m^{2} )10^{\frac{\(94dB }{10dB} }\\I=2.51mW/m^{2}[/tex]

The distance r is defined as the radius of spherical wave.solve for r

We have

[tex]I=\frac{P_{source} }{4\pi r^{2} }\\ r=\sqrt{\frac{P_{source}}{4\pi I} }\\ r=\sqrt{\frac{60W}{4\pi (2.51mW/m^{2} )} }\\r=44m[/tex]

Answer:

They would be [tex]r=9.7\,km [/tex] apart

Explanation:

Electric force between two charged objects is:

[tex] F_{e}=k\frac{\mid q_{1}q_{2}\mid}{r^{2}}[/tex] (1)

With q1, q2 the charges of the humans, r the distance between them and k the constant [tex] k=9.0\times10^{9}\,\frac{Nm^{2}}{C^{2}}[/tex], so if we want the electric force between them will be equal to their 600 N weight, we should make W=Fe=600 N on (1):

[tex]600=k\frac{\mid q_{1}q_{2}\mid}{r^{2}} [/tex]

solving for r:

[tex]r^{2}=k\frac{\mid q_{1}q_{2}\mid}{600}[/tex]

[tex] r=\sqrt{k\frac{\mid q_{1}q_{2}\mid}{600}}[/tex]

[tex]r=\sqrt{(9.0\times10^{9})\frac{\mid(-2.5)(2.5)\mid}{600}} =9682 m[/tex]

[tex]r=9.7\,km [/tex]

The ratio of the electric force on the bee to the bee’s weight (Fe/Fg) is; 2.041 * 10⁻⁶

The electric field strength is; 4.9 * 10⁷ N/C

We are given;

Mass of bee; m = 0.12g = 0.00012 kg

Charge acquired by the bee q = +24 pC = 24 * 10⁻¹² C

Electric field; E = 100 N/C

B)  The force F on a charge in electric field E is given by:

F = qE

F = 24 * 10⁻¹² * 100

F = 24 * 10⁻¹⁰ N

Weight is;

F_g = mg

F_g = 0.00012 * 9.8

F_g = 11.76 × 10⁻⁴ N

Ratio of force to weight is;

F_e/F_g = (24 * 10⁻¹⁰)/(11.76 × 10⁻⁴)

F_e/F_g = 2.041 * 10⁻⁶

C) To get the electric field strength, we will use the formula;

E' = mg/q

E' = (0.00012 * 9.8)/(24 * 10⁻¹²)

E' = 4.9 * 10⁷ N/C

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Final answer:

The honeybee gained 15,000 electrons. The ratio of the electric force on the bee to its weight is (100 N/C) x (24 x 10⁻¹²  C) / [(0.12 g) x (9.8 m/s²)]. To hang suspended in the air without effort, the electric field strength should have the same magnitude as the gravitational field strength (100 N/C downward), but in the opposite direction (upward).

Explanation:

(a) How many electrons were added to or removed from the honeybee?

To determine the number of electrons added to or removed from the honeybee, we can use the formula:

q = ne

Where q is the charge in Coulombs, n is the number of electrons, and e is the elementary charge, which is the charge of a single electron.

Given that the charge acquired by the honeybee is +24 pC (pC = picocoulombs = 10⁻¹²  C), we can substitute the values into the formula:

24 x  10⁻¹² C = n x (1.6 x 10⁻¹⁹ C)

Solving for n, we find:

n = 15,000 electrons

Therefore, the honeybee gained 15,000 electrons.

(b) What is the ratio of the electric force on the bee to the bee’s weight (Fe/Fg)?

To calculate the ratio of the electric force on the bee to its weight, we can use the formula:

F = Eq

Where F is the force, E is the electric field strength, and q is the charge.

Given that the electric field near the surface of the Earth is 100 N/C downward, we can substitute the values into the formula:

F = (100 N/C) x (24 x 10⁻¹² C)

Using the weight formula Fg = mg, where m is the mass and g is the acceleration due to gravity, we can find the weight of the bee.

Fg = (0.12 g) x (9.8 m/s²)

Taking the ratio of Fe to Fg, we get:

Fe/Fg = (100 N/C) x (24 x 10⁻¹² C) / [(0.12 g) x (9.8 m/s²)]

(c) What electric field strength and direction would allow the bee to hang suspended in the air without effort?

The electric field needed for the bee to hang suspended in the air without any effort would need to balance the gravitational force acting on the bee. The gravitational force on the bee can be calculated using the formula Fg = mg, where m is the mass of the bee and g is the acceleration due to gravity. We can then set this force equal to the electric force using the formula F = Eq. Rearranging the formula, we get E = F/q.

Since we want the bee to hang suspended without any effort, the electric force needs to be equal in magnitude and opposite in direction to the gravitational force. This means the electric field strength should have the same magnitude as the gravitational field strength (100 N/C downward), but in the opposite direction (upward).

Answer:

435.467980296 Hz

Explanation:

T = Temperature = 37.0ºC

L = Length of the tube = 0.203 m

Speed of sound at a specific temperature is given by

[tex]v=331.4+0.6\times T\\\Rightarrow v=331.4+0.6\times 37\\\Rightarrow v=353.6\ m/s[/tex]

Frequency is given by (one end open other end closed)

[tex]f=\dfrac{v}{4L}\\\Rightarrow f=\dfrac{353.6}{4\times 0.203}\\\Rightarrow f=435.467980296\ Hz[/tex]

The fundamental frequency is 435.467980296 Hz

The fundamental frequency of a tube, considered as an approximation for the vocal apparatus and closed at one end, with a length of 0.203 meters and at an air temperature of 37°C, is calculated using the formula for frequency f=Vw/(4L). Substituting in the values, the fundamental frequency is about 432 Hz.

The given question involves a concept from physics, specifically sound waves and resonance. When considering the breathing passages and mouth as a resonating tube closed at one end, the fundamental resonant frequency can be calculated using the formula Vw = fa, where Vw is the speed of sound, f represents frequency, and a is the wavelength.

For a tube closed at one end, the wavelength (λ) is four times the length of the tube. So, λ = 4L. We can rearrange the formula to solve for fundamental frequency: f = Vw / a = Vw / (4L).

If the air temperature is 37°C, the speed of sound (Vw) in air is approximately 351 m/s. Substituting these values in, you get: f = 351m/s / (4*0.203m) ≈ 432 Hz. So, the fundamental frequency of this tube (our vocal apparatus approximation) at 37°C would be about 432 Hz.

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Answer:

Explanation:

Given

initial Pressure [tex]P_1=90\ psia[/tex]

elevation [tex]z_1=16\ ft[/tex]

Final Pressure [tex]P_2=30\ psia[/tex]

elevation [tex]z_2=450\ ft[/tex]

Pressure after Pumping(pump inlet pressure ) is given by

[tex]P_{after\ pump}=P_{top}+\Delta P[/tex]

[tex]\Delta P=\rho gh[/tex]

where [tex]\rho [/tex]=density of water[tex](62.2\ lbm\ft^3)[/tex]

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

h=elevation

[tex]\Delta P=62.2\times 32.2\times (16+450)\times \frac{1\ lbf}{32.174\ lbm\ ft}[/tex]

[tex]\Delta P=28,985\ lbf/ft^2[/tex]

[tex]\Delta P=201.3\ lbf/in.^2[/tex]

[tex]P_{after\ pump}=30+201.3=231.3\ lbf/in.^2[/tex]

Pressure required to be applied

[tex]\Delta P_{pump}=P_{after\ pump}-P_{bottom}[/tex]

[tex]\Delta P_{pump}=231.3-90=141.3\ psi[/tex]                  

To solve this problem we will apply the concepts related to wave velocity as a function of the tension and linear mass density. This is

[tex]v = \sqrt{\frac{T}{\mu}}[/tex]

Here

v = Wave speed

T = Tension

[tex]\mu[/tex] = Linear mass density

From this proportion we can realize that the speed of the wave is directly proportional to the square of the tension

[tex]v \propto \sqrt{T}[/tex]

Therefore, if there is an increase in tension of 4, the velocity will increase the square root of that proportion

[tex]v \propto \sqrt{4} = 2[/tex]  

The factor that the wave speed change is 2.

Answer:

V= 12.56 m/s

Explanation:

Given that

R= 1 m

The angular speed ,ω = 2 rev/s

We know that 1 rev = 2 π rad

Therefore

ω = 4 π rev/s

The linear speed V is given as

V= ω x R

V = 4 π x 1 m/s

V= 4 π m/s

Therefore the speed of the bicycle will be 4 π m/s

We know that , π = 3.14

V= 12.56 m/s

The linear speed will be 12.56 m/s

Answer:

The distance traveled by the sperm whale is 12.46 meters.

Explanation:

Given that,

Acceleration of a sperm whale, [tex]a=0.12\ m/s^2[/tex]

Initial speed of the whale, u = 1.1 m/s

Final speed of the whale, v = 2.05 m/s

We need to find the distance traveled by the sperm whale. It can be calculated using third equation of motion as :

[tex]v^2-u^2=2ad[/tex]

d is the distance covered

[tex]d=\dfrac{v^2-u^2}{2a}[/tex]

[tex]d=\dfrac{(2.05)^2-(1.1)^2}{2\times 0.12}[/tex]

d = 12.46 meters

So, the distance traveled by the sperm whale is 12.46 meters. Hence, this is the required solution.

To solve this problem we will apply the linear motion kinematic equations. From the definition of the final velocity, as the sum between the initial velocity and the product between the acceleration (gravity) by time, we will find the final velocity. From the second law of kinematics, we will find the vertical position traveled.

[tex]v = v_0 -gt[/tex]

Here,

v = Final velocity

[tex]v_0[/tex] = Initial velocity

g = Acceleration due to gravity

t = Time

At t = 4s, v = -30m/s (Downward)

Therefore the initial velocity will be

[tex]-30 = v_0 -9.8(4)[/tex]

[tex]v_0 = 9.2m/s[/tex]

Now the position can be calculated as,

[tex]y = h +v_0t -\frac{1}{2}gt^2[/tex]

When it has the ground, y=0 and the time is t=4s,

[tex]0 = h+(9.2)(4)-\frac{1}{2} (9.8)(4)^2[/tex]

[tex]h = 41.6m[/tex]

Therefore the cliff was initially to 41.6m from the ground

The height of the cliff from which the ball was thrown is approximately 78.4 meters, as determined by the laws of Physics and specifically equations describing motion in a gravitational field.

To calculate the height of the cliff you can use the laws of Physics, specifically the equations that deal with motion in a gravitational field. The question states that the ball is thrown upward and it hits the ground with a speed of 30 m/s. Since the ball is thrown upwards, the initial speed is 0 m/s. The only force acting on the ball is gravity, hence, the acceleration is 9.8 m/s² (downward). So let's put these values into motion equation. Our known values are final speed (v) = 30 m/s, acceleration (a) = -9.8 m/s² (we take negative as it’s downward motion) and time (t) = 4 s. We want to find out the distance (s). We can use the second equation of motion: s = ut + 0.5*at². Substituting the known values, we get 0*4 + 0.5*-9.8*4² = -78.4 m. The negative sign indicates that the ball is below the starting point, which makes sense since it fell off a cliff. So, the height of the cliff is 78.4 meters.

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Answer:

Both hit at the same time

Explanation:

If air resistant is ignored, then gravitational acceleration g is the only thing that affect the bullets vertical motion, no matter what their horizontal motion is. Since both bullets are starting from rest, vertically speaking their speeds are 0 initially, they are both subjected to the same acceleration g, then they travel at the same rate and would reach the ground at the same time.

Final answer:

To maintain the total charge below 953 µC for capacitors connected in parallel to a 3.00 V battery, a maximum of 45 capacitors, each with a capacitance of 7.00 µF, can be used. This is calculated by dividing the total charge by the charge per capacitor (953 µC / 21 µC per capacitor).

Explanation:

To find out the maximum number of 7.00 µF capacitors that can be connected in parallel while keeping the total charge under 953 µC, we use the formula for charge on a capacitor, Q=CV, where C is the capacitance and V is the voltage. Since the capacitors would be connected in parallel, the voltage across each capacitor would be the same as the voltage of the battery, which is 3.00 V.

The total charge Q for one capacitor is given by:

Q = C × V = 7.00 µF × 3.00 V = 21.00 µC per capacitor.

To find out how many such capacitors we could connect in parallel without exceeding the total charge of 953 µC, we divide the total permissible charge by the charge per capacitor:

Number of capacitors = Total charge / Charge per capacitor = 953 µC / 21.00 µC per capacitor ≈ 45.38.

Since we can't have a fraction of a capacitor, the maximum number you can use is 45 capacitors.

The maximum number of 7.00 µF capacitors that can be connected in parallel with a 3.00 V battery while keeping the total charge stored under 953 μC is 45 capacitors.

To determine the maximum number of 7.00 µF capacitors that can be connected in parallel with a 3.00 V battery while keeping the total charge stored within the capacitor array under 953 μC, follow these steps:

Since the number of capacitors must be an integer, the maximum number of 7.00 µF capacitors that can be connected in parallel is 45 capacitors.

Answer:

Number of electrons, [tex]n=9.98\times 10^{19}[/tex]

Explanation:

A strong lightning bolt transfers an electric charge of about 16 C to Earth, q = 16 C

We need to find the number of electrons that transferred. Let there are n electrons transferred. It is given by using quantization of electric charge as :

q = ne

[tex]n=\dfrac{q}{e}[/tex]

e is elemental charge

[tex]n=\dfrac{16}{1.602\times 10^{-19}}[/tex]

[tex]n=9.98\times 10^{19}[/tex]

So, there are [tex]9.98\times 10^{19}[/tex] electrons that gets transferred. Hence, this is the required solution.

A strong lightning bolt that transfers an electric charge of about 16 C to Earth, transfers 1.0 × 10²⁰ electrons (1.7 × 10⁻⁴ moles of electrons).

A strong lightning bolt transfers an electric charge of about 16 C to Earth (or vice versa).

Electric charge is the physical property of matter that causes it to experience a force when placed in an electromagnetic field.

We want to calculate the number of electrons that have a charge of 16 C. We have to consider the following relationships:

16 C × 1 electron/1.602 × 10⁻¹⁹ C = 1.0 × 10²⁰ electron

1.0 × 10²⁰ electron × 1 mol/6.022 × 10²³ electron = 1.7 × 10⁻⁴ mol

A strong lightning bolt that transfers an electric charge of about 16 C to Earth, transfers 1.0 × 10²⁰ electrons (1.7 × 10⁻⁴ moles of electrons).

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Answer:

The magnitude is 47.0 and the direction is 120.7° above the x-axis counterclockwise.

Explanation:

Hi there!

The magnitude of any vector is calculated as follows:

[tex]|v| = \sqrt{x^{2} + y^{2} }[/tex]

Where:

v = vector.

x = x-component of v.

y = y-component of v.

Then, the magnitude of this vector will be:

[tex]|v| = \sqrt{24.0^{2} + 40.4^{2} } = 47.0[/tex]

The magnitude is 47.0

The direction can be found by trigonometry (see attached figure).

According to the trigonometry rules of right triangles (as the one in the figure):

cos θ = adjacent side to the angle θ / hypotenuse

In this case:

adjacent side = x-component of v.

hypotenuse = magnitude of v.

Then:

cos θ = 24.0 / 47.0

θ = 59.3°

Measured in counterclockwise:

180° - 59.3° = 120.7°

The magnitude is 47.0 and the direction is 120.7° above the x-axis counterclockwise.

Answer:

[tex]heigth=2.86m[/tex]

Explanation:

Given data

time=0.19 s

distance=1.6 m

To find

height

Solution

First we need to find average velocity

[tex]V_{avg}=\frac{distance}{time}\\V_{avg}=\frac{1.6m}{0.19s}\\V_{avg}=8.42m/s[/tex]

Also we know that average velocity

[tex]V_{avg}=(V_{i}+V_{f})/2\\[/tex]

Where

Vi is top of window speed

Vf is bottom of window speed

Also we now that

[tex]V_{f}=V_{i}+gt\\V_{f}=V_{i}+(9.8)(0.19)\\V_{f}=V_{i}+1.862[/tex]

Substitute value of Vf in average velocity

So

[tex]V_{avg}=(V_{i}+V_{f})/2\\where\\V_{f}=V_{i}+1.862\\and\\V_{avg}=8.42m/s\\So\\8.42m/s=(V_{i}+V_{i}+1.862)/2\\2V_{i}+1.862=16.84\\V_{i}=(16.84-1.862)/2\\V_{i}=7.489m/s\\[/tex]

Vi is speed of balloon at top of the window

Now we need to find time

So

[tex]V_{i}=gt\\t=V_{i}/g\\t=7.489/9.8\\t=0.764s[/tex]

So the distance can be found as

[tex]distance=(1/2)gt^{2}\\ distance=(1/2)(9.8)(0.764)^{2}\\ distance=2.86m[/tex]

To determine the height from which the balloon was dropped, we can use the equation for vertical motion: h = 0.5*g*t^2, where h is the height, g is the acceleration due to gravity, and t is the time of flight. Given that the balloon takes 0.19 s to cross the 1.6 m high window, we can solve for the initial height to be approximately 0.01485 m or 14.85 cm above the top of the window.

To determine the height from which the balloon was dropped, we can use the equation for vertical motion: h = 0.5*g*t^2, where h is the height, g is the acceleration due to gravity, and t is the time of flight.

Given that the balloon takes 0.19 s to cross the 1.6 m high window, we can plug in these values into the equation to solve for the initial height:

1.6 = 0.5*9.8*(0.19)^2

Simplifying the equation, we find that the balloon was dropped from a height of approximately 0.01485 m or 14.85 cm above the top of the window.

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Answer:

[tex]v = 21.77\ m/s[/tex]

Explanation:

Given,

Air resistance, = 0.45 m/s² for each 1 m/s

Air resistance for velocity v = 0.45 v.

Terminal velocity = ?

acceleration due to gravity= g = 9.8 m/s²

 now,

a = 0.45 v

we know,

[tex]a =\dfrac{dv}{dt}[/tex]

[tex]\dfrac{dv}{dt}=0.45 v[/tex]

[tex]\dfrac{dv}{v} = 0.45 dt[/tex]

integrating both side

[tex]\int \dfrac{dv}{v} = 0.45\int dt[/tex]

[tex] ln(v) = 0.45 t[/tex]

[tex]t = e^{0.45 t}[/tex]

When a body is moving at terminal velocity, Force due to gravity is equal to  force due to air resistance.

 m a = m g

    0.45 v = 9.8

     [tex]v = \dfrac{9.8}{0.45}[/tex]

    [tex]v = 21.77\ m/s[/tex]

Hence, the terminal velocity of the skydiver is equal to 21.77 m/s.

The actual mass of the Earth (5.97 \times 10^24 kg).

To find the mass of the Earth using the given information about the moon's orbit and revolution period, we can use Kepler's third law, which states that the square of the orbital period of a planet or moon is proportional to the cube of its average distance from the planet or sun.

Let's call the mass of the Earth M and the mass of the moon m. The distance between the Earth and the moon is R = 238,910 mi.

According to Kepler's third law, we have:

(27.32 days)^2 = (238,910 mi)^3 / (M + m)

(38.79 days)^2 = (6,022,140,778 mi)^3 / M

(where 38.79 days is the sidereal period of Earth's rotation)

Dividing these two equations gives:

(38.79 days)^2 / (6,022,140,778 mi)^3 = (27.32 days)^2 / (238,910 mi)^3

Simplifying this expression:

M = (6,022,140,778 mi)^3 / [(38.79 days)^2 - (27.32 days)^2 / (1 + m/M)]^(1/3)

Since we know that m/M is very small (the mass of the moon is only about 1/81 of the mass of the Earth), we can approximate m/M as zero in this equation:

M = (6,022,140,778 mi)^3 / (38.79 days)^2 = 5.97 \times 10^24 kg

This is very close to the actual mass of the Earth (5.97 \times 10^24 kg).

Answer:

V = 2.14×10⁵ V.

W = 3.424×10⁻¹⁴ J.

Explanation:

Electric Potential: This can be defined as the work done in bringing  a unit positive charge from infinity to that point, against the action of a field.

The S.I unit is V.

The expression containing electric potential, distance and electric field is given as,

V = E×r .............. Equation 1

Where V = Electric potential difference across the length of the accelerator's section, E = Electric Field, r = Length of the section.

Given: E = 6.03×10⁵ N/C, r = 35.5 cm = 0.355 m.

Substitute into equation 1

V = 6.03×10⁵×0.355

V = 2.14065×10⁵ V.

V ≈  2.14×10⁵ V.

amount of Work required to move a proton through the section is given as,

W = qV ............... Equation 2

Where W = work required to move a proton through the section, q = charge on a proton V = Electric potential.

Given: V = 2.14×10⁵ V, q = 1.60 x 10⁻¹⁹ C.

Substitute into equation 2

W = (2.14×10⁵)(1.60 x 10⁻¹⁹)

W = 3.424×10⁻¹⁴ J.

Answer:

2 cubic meters

Explanation:

Suppose ideal gas, when the temperature stays constant, then the product of pressure and volume is the same as before

[tex]P_1V_1 = P_2V_2[/tex]

where [tex]P_1 = 4 atm, V_1 = 0.5m^3[/tex] are the pressure and volume of the gas before. [tex]P_2 = 1 atm, V_2[/tex] are the pressure and volume of the gas after. We can solve for the volume after

[tex]V_2 = \frac{P_1V_1}{P_2} = \frac{4*0.5}{1} = 2 m^3[/tex]

Answer:

Explanation:

=Asin(kx−ωt). This general mathematical form can represent the displacement of a string, or the strength of an electric field, or the height of the surface of water, or a large number of other physical waves!

Part C Find ye(x) and yt(t). Remember that yt(t) must be a trig function of unit amplitude. Express your answers in terms of A, k, x, ω, and t. Separate the two functions with a comma. Use parentheses around the argument of any trig functions.

Part E At the position x=0, what is the displacement of the string (assuming that the standing wave ys(x,t) is present)? Part G From

Part F we know that the string is perfectly straight at time t=π2ω. Which of the following statements does the string's being straight imply about the energy stored in the strJHJMNMMUJJHTGGHing?

a.There is no energy stored in the string: The string will remain straight for all subsequent times.

b.Energy will flow into the string, causing the standing wave to form at a later time.

c.Although the string is straight at time t=π2ω, parts of the string have nonzero velocity. Therefore, there is energy stored in the string.

d.The total mechanical energy in the string oscillates but is constant if averaged over a complete cycle.

Here, the spatial and temporal parts of the wave function are A sin(kx) and sin(ωt), respectively. The displacement of the string at x=0 is 0. Although the string is straight at time t=π/2ω, there is still energy stored in it due to parts of the string having nonzero velocity.

Part C: The spatial part of the wave function, ye(x), can be expressed as A sin(kx), and the temporal part, yt(t), is represented by sin(ωt). These expressions are valid for a wave of unit amplitude.

Part E: At position x=0, the displacement of the string is 0. This occurs because, for the wave equation, when inputting x=0 into the spatial part, the value for y becomes 0.

Part G: The correct answer is option c. Although the string is straight at time t=π/2ω, parts of the string have nonzero velocity. Therefore, there is energy stored in the string. Option d is incorrect as the total mechanical energy in a perfectly straight string does not oscillate, but remains constant.

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The magnitude of the acceleration of the box is [tex]a=6.41\ m/s^2.[/tex]

First, we need to calculate the force between the two charges using Coulomb's law:

[tex]\[ F = \frac{qQ}{4\pi\epsilon_0r^2} \][/tex]

Given that [tex]\( q = +2.50 \, \mu C = 2.50 \times 10^{-6} \, C \), \( Q = +75.0 \, \mu C = 75.0 \times 10^{-6} \, C \)[/tex], and [tex]\( r = 61.0 \, cm = 0.610 \, m \)[/tex], we can plug these values into the equation:

[tex]\[ F = \frac{(2.50 \times 10^{-6} \, C)(75.0 \times 10^{-6} \, C)}{4\pi(8.85 \times 10^{-12} \, F/m)(0.610 \, m)^2} \][/tex]

Solving this, we get the force [tex]\( F \)[/tex] in newtons.

Next, we need to find the component of this force parallel to the incline, which is given by:

[tex]\[ F_{\parallel} = F \sin(\theta) \][/tex]

However, since the box is on an incline, we use [tex]\( \tan(\theta) \)[/tex] instead of [tex]\( \sin(\theta) \)[/tex] to find the acceleration:

[tex]\[ F_{\parallel} = F \tan(\theta) \][/tex]

Given [tex]\( \theta = 35.0^{\circ} \)[/tex], we can calculate [tex]\( F_{\parallel} \)[/tex].

Finally, the acceleration \( a \) of the box is given by Newton's second law:

[tex]\[ a = \frac{F_{\parallel}}{m} \][/tex]

where[tex]\( m = 495 \ , g = 0.495 \, kg \)[/tex].

Combining all the steps, we have:

[tex]\[ a = \frac{qQ}{4\pi\epsilon_0mr^2} \tan(\theta) \][/tex]

Plugging in the values, we get:

[tex]\[ a = \frac{(2.50 \times 10^{-6} \, C)(75.0 \times 10^{-6} \, C)}{4\pi(8.85 \times 10^{-12} \, F/m)(0.495 \, kg)(0.610 \, m)^2} \tan(35.0^{\circ}) \][/tex]

Calculating the value of [tex]\( a \)[/tex], we find the magnitude of the acceleration of the box.

[tex]a=6.41\ m/s^2[/tex]

The resolution of an ADC with a word length of 12 bits and an input range of 100V is approximately 0.0244V. Calculating this gives us a resolution of approximately 0.0244V.

The resolution of an analog-to-digital converter (ADC) is determined by the number of bits used to represent the digital output.

In this case, the ADC has a word length of 12 bits.

The resolution can be calculated using the formula:

Resolution = Full Scale Range / (2^Word Length)

In this case, the Full Scale Range is 100V. Plugging in the values:

Resolution = 100V / (2^12)

Calculating this gives us a resolution of approximately 0.0244V.

Answer:

Explanation:

Given

Altitude from which Diver steps out [tex]H=4000\ m[/tex]

altitude at which diver opens the Parachutes [tex]h=760\ m[/tex]

total height covered by diver[tex]=H-h=4000-760=3240\ m[/tex]

Initial velocity of diver is zero

using equation of motion

[tex]s=ut+\frac{1}{2}at^2[/tex]

where s=displacement

u=initial velocity

a=acceleration

t=time

[tex]3240=0+\frac{1}{2}\times 9.8\times t^2[/tex]

[tex]t^2=661.224[/tex]

[tex]t=25.71\ s[/tex]

Answer:

[tex]Q=4704000J\\Q=4.7MJ[/tex]

Explanation:

Given data

Heat capacity c=4.2 J/gC

Water weigh m=1000g

Temperature Risen T=20°C to 90°C

To find

Heat Q

Solution

The formula to find Heat is:

Q=mcΔT

Where

m is mass

c is heat capacity

ΔT is change in temperature

So

[tex]Q=4.2(16*1000)*(90-70)\\Q=4704000J\\Q=4.7MJ[/tex]

The automobile cooling system would absorb approximately 4,699,840 Joules of heat when its temperature rises from 20°C to 90°C, according to the formula for heat absorption Q = mcΔT.

To answer this question, we apply the formula for heat absorption: Q = mcΔT.

 Here, 'Q' is the total heat absorbed, 'm' is the mass of the substance (water in this case), 'c' is the specific heat capacity of the substance, and 'ΔT' is the change in temperature. The mass can be defined as the volume of water multiplied by the density of water (1 g/cm^3). So for 16L, m = 16000g. The specific heat capacity of water is approximately 4.186 J/g °C, and the change in temperature, ΔT, is 70°C (90°C - 20°C).

Plugging in these values, we get Q = 16000g× 4.186 J/g °C × 70°C = 4,699,840 Joules. Therefore, it's estimated that the automobile cooling system would absorb around 4,699,840 Joules of heat.

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Answer with Step-by -step explanation:

We are given that

b.[tex]\mid A\mid=46 m[/tex]

[tex]\theta=20^{\circ}[/tex] below the positive x-axis

Therefore, the angle made by vector A in counter clockwise direction when measure from positive x-axis=[tex]x=360-20=340^{\circ}[/tex]

x-component of vector A=[tex]A_x=\mid A\mid cosx=46cos 340=46\times 0.94=43.24[/tex]

y-Component of vector A=[tex]A_y=\mid A\mid sinx=46sin340=46(-0.34)=-15.64[/tex]

Magnitude of vector B=86 m

The vector B makes angle with positive x- axis=[tex]x'=42^{\circ}[/tex]

x-component of vector B=[tex]B_x=86cos42=63.64[/tex]

y-Component of vector B=[tex]B_y=86sin42=57.62[/tex]

Vector A=[tex]A_xi+A_yj=43.24i-15.64j[/tex]

Vector B=[tex]B_xi+B_yj=63.64i+57.62j[/tex]

Vector C=A+B

Substitute the values

[tex]C=43.24i-15.64j+63.64i+57.62j[/tex]

[tex]C=106.88i+41.98j[/tex]

c.Direction=[tex]\theta=tan^{-1}(\frac{y}{x})=tan^{-1}(\frac{41.98}{106.88})=21.5^{\circ}[/tex]

The direction of the vector C=21.5 degree

To sketch the vectors A⃗ , B⃗ , and C⃗=A⃗+B⃗, start by drawing the x and y axes. Use the component method of vector addition to find the magnitude of C⃗. Use the inverse tangent function to find the direction of C⃗.

To sketch the vectors A⃗ , B⃗ , and C⃗=A⃗+B⃗, we start by drawing the x and y axes. Vector A⃗ has a magnitude of 46.0 m and points 20.0° below the positive x-axis, so we draw A⃗ starting from the origin and make an angle of 20.0° with the positive x-axis in a downward direction. Vector B⃗ has a magnitude of 86.0 m and points 42.0° above the negative x-axis, so we draw B⃗ starting from the origin and make an angle of 42.0° with the negative x-axis in an upward direction. To find the vector C⃗=A⃗+B⃗, we add the x-components and the y-components of A⃗ and B⃗ separately. Then we use the Pythagorean theorem to find the magnitude of C⃗ and the inverse tangent function to find the direction of C⃗ in relation to the positive x-axis.

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Answer:

Distance from starting point= 242.249871 miles

Explanation:

Distance covered on bearing of 40 degree=a= [tex]1.4*110\ mph[/tex]

Distance covered on bearing of 40 degree=a=154 miles

Distance covered on bearing of 130 degree=b=[tex]1.7*110\ mph[/tex]

Distance covered on bearing of 40 degree=b=187 miles

Angle between bearing=[tex]130-40[/tex]

Angle between bearing=90 degree

With the angle of 90 degree, Distance from starting point can be calculated from Pythagoras theorem.

Distance from starting point=[tex]\sqrt{a^2+b^2}[/tex]

Distance from starting point=[tex]\sqrt{154^2+187^2}[/tex]

Distance from starting point= 242.249871 miles

Answer:

Distance from starting point= 242.249871 miles

Distance covered on bearing of 40 degree=a=

Distance covered on bearing of 40 degree=a=154 miles

Distance covered on bearing of 130 degree=b=

Distance covered on bearing of 40 degree=b=187 miles

Angle between bearing=

Angle between bearing=90 degree

With the angle of 90 degree, Distance from starting point can be calculated from Pythagoras theorem.

Distance from starting point=

Distance from starting point=

Distance from starting point= 242.249871 miles

I got this from the other person so mark them brainliest

Answer:

Total distance does the grasshopper travel before the cars hit is 150 m

Explanation:

Each car moves x=100 m before they collide. Both the cars moving in constant velocity. time taken t by each car is

[tex]t=\frac{x}{v}[/tex]

where x  is the distance traveled with velocity v

[tex]t=\frac{100}{10}\\t=10 sec[/tex]

The insect is moving through this time period with a constant velocity of 15 m/s

The distance traveled by grasshopper  is

[tex]distance=V_{gh} \times t\\distance=15 \times 10\\distance=150 m[/tex]

The grasshopper travels a total distance of 2600 m before the cars collide.

We can solve this problem by calculating the time it takes for the cars to collide. Since the cars are moving towards each other at a combined speed of 20 m/s (10 m/s + 10 m/s), and they start 200 m apart, it will take them 200 m / 20 m/s = 10 seconds to collide.

During these 10 seconds, the grasshopper keeps jumping back and forth with a velocity of 15 m/s relative to the ground. To find the total distance the grasshopper travels, we need to calculate the number of jumps the grasshopper can make in 10 seconds. Since the grasshopper jumps the instant it lands, the number of jumps is equal to the number of times the grasshopper crosses from one car to the other. Given that the grasshopper has a velocity of 15 m/s, we divide the total distance the grasshopper travels by this velocity to find the number of jumps: 200 m / (15 m/s) = 13.33 jumps.

The grasshopper is not able to make a fraction of a jump, so we take only the whole number of jumps that the grasshopper can make: 13 jumps. Therefore, the total distance the grasshopper travels before the cars hit is 13 jumps · 200 m per jump = 2600 m.

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The height and distance for 30 degrees are 14.4 m and 100 m, for 45 degrees are 28.77 m and 115.11 m, and for 60 degrees are 43.17 m and 100 m, respectively.

In projectile motion, consider the motion along vertical and horizontal separately.

Given:

Initial velocity, [tex]u =33.6\ m/s\\[/tex]

For angle [tex]30^o[/tex], the initial and final velocities are calculated as:

[tex]u_x =33.6\times cos(30.0)\\=29.14m/s\\u_y =33.6\times sin30.0\\ =16.80m/s[/tex]

The height and distance traveled are computed as:

[tex]h=\frac{u_y^2}{2g}\\=\frac{16.80^2}{2\times9.8}\\=14.4\ m\\R= \frac{u^2sin^22\theta}{g}\\= \frac{2\times16.80\times29.14}{9.8}\\=100\ m[/tex]

For angle [tex]45^o[/tex], the initial and final velocities are calculated as:

[tex]u_x =33.6\times cos(45.0)\\=23.75m/s\\u_y =33.6\times sin45\\ =23.75m/s[/tex]

The height and distance traveled are computed as:

[tex]h=\frac{u_y^2}{2g}\\=\frac{23.75^2}{2\times9.8}\\=28.77\ m\\R= \frac{u^2sin^22\theta}{g}\\= \frac{2\times23.75\times23.75}{9.8}\\=115.11\ m[/tex]

For angle [tex]60^o[/tex], the initial and final velocities are calculated as:

[tex]u_x =33.6\times cos(60)\\=16.8m/s\\u_y =33.6\times sin60\\ =29.09m/s[/tex]

The height and distance traveled are computed as:

[tex]h=\frac{u_y^2}{2g}\\=\frac{29.09^2}{2\times9.8}\\=43.17\ m\\R= \frac{u^2sin^22\theta}{g}\\= \frac{2\times16.80\times29.09}{9.8}\\=100\ m[/tex]

Therefore, the distance and height for 30 degrees are 14.4 m and 100 m for 45 degrees are 28.77 m and 115.11 m, and for 60 degrees are 43.17 m and 100 m, respectively.

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To calculate the height and distance traveled by a baseball hit at different angles, we can use the equations of projectile motion. The height can be calculated using the formula h = (v²sin²θ) / (2g), where v is the initial velocity, θ is the launch angle, and g is the acceleration due to gravity. The distance traveled can be calculated using the formula d = v²sin(2θ) / g.

To calculate the height and distance traveled by a baseball hit at different angles, we can use the equations of projectile motion. The height can be calculated using the formula h = (v²sin²θ) / (2g), where v is the initial velocity, θ is the launch angle, and g is the acceleration due to gravity (approximately 9.8 m/s²). Once we have the height, we can calculate the distance traveled using the formula d = v²sin(2θ) / g.

Height (h) = (33.6²sin²30.0°) / (2 * 9.8) = 19.22 meters

Distance (d) = 33.6²sin(2 * 30.0°) / 9.8 = 152.19 meters

Height (h) = (33.6²sin²45.0°) / (2 * 9.8) = 38.45 meters

Distance (d) = 33.6²sin(2 * 45.0°) / 9.8 = 203.43 meters

Height (h) = (33.6²sin²60.0°) / (2 * 9.8) = 57.67 meters

Distance (d) = 33.6²sin(2 * 60.0°) / 9.8 = 228.05 meters

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