The ice melts after 474.36 seconds or 7 minutes and 54 seconds and it takes 1242.88 seconds or 20 minutes and 43 seconds to raise the temperature from 0°C to 15°C.
Mass of ice, m = 0.525 kg
Temperature of ice, T1 = -15.1°C
Heat supplied to container, Q = 780 J/minute
Specific heat of ice, c = 2100 J/kg.K
Latent heat of ice, L = 334 x 10³ J/kg.
Part A:
We know that ice starts melting when its temperature reaches the melting point, which is 0°C. Therefore, the amount of heat required to raise the temperature of ice from -15.1°C to 0°C is given by:
Q1 = mcΔT1,
where
ΔT1 = 0 - (-15.1) = 15.1°C
Q1 = 0.525 x 2100 x 15.1
Q1 = 16,591.25 J
Therefore, time taken for ice to melt is given by:
Q1 + Q2 = mLt
Q2 = mLt - Q1
t = (mL - Q1)/Q2= [(0.525 x 334 x 10³) - 16,591.25] / 780
t = 474.36 seconds
Therefore, the ice melts after 474.36 seconds or 7 minutes and 54 seconds.
Part B:
The time taken for the ice to start melting is the time taken to raise the temperature from -15.1°C to 0°C, which we calculated above as 474.36 seconds. Therefore, the heating starts at this point.
Now, we need to calculate the time taken to raise the temperature of water from 0°C to 15°C, which is the temperature at which the temperature starts rising above 0°C.
The amount of heat required to do this is given by:
Q3 = mcΔT3,
where
ΔT3 = 15 - 0 = 15°C
Q3 = 0.525 x 2100 x 15
Q3 = 16,147.5 J
The time taken to raise the temperature by this amount is given by:
t = Q3/P,
where P is the power supplied.
P = 780 J/minute = 13 J/second
t = 16,147.5 / 13
t = 1242.88 seconds
Therefore, it takes 1242.88 seconds or 20 minutes and 43 seconds to raise the temperature from 0°C to 15°C.
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PLEASE HELPPP
Force: Adding vectors (find resultant force)
50N north plus 50N west Plus 50N north west
This same parcel of air is forced to rise until it reaches a
temperature of 75 degrees F. What is: the SSH?
6 gm/kg
8 gm/kg
14 gm/ kg
18 gm/kg
24 gm/kg
36 gm/kg
33%
58%
77%
100%
To find the saturation specific humidity (SSH) of a parcel of air, we need to consider its saturation mixing ratio at different temperatures.
Let's go through the calculations step by step.
Given:
Temperature at the Earth's surface = 85 degrees Fahrenheit
Temperature at height of condensation = 75 degrees Fahrenheit
We know that the saturation mixing ratio represents the maximum amount of water vapor the air can hold at a specific temperature. At 85 degrees Fahrenheit, the saturation mixing ratio is 14 grams of water vapor per kilogram of dry air.
To determine the saturation mixing ratio at 75 degrees Fahrenheit, we refer to the "Saturation Mixing Ratio vs. Temperature" chart or equation. Let's assume that at 75 degrees Fahrenheit, the saturation mixing ratio is 24 grams per kilogram of dry air.
The saturation specific humidity is the difference between the two mixing ratios. In this case, it is:
SSH = 24 grams/kg - 14 grams/kg = 10 grams/kg
The SSH is expressed as a percentage of the saturation mixing ratio at the height of condensation. Since the parcel of air has reached its saturation point at 75 degrees Fahrenheit, the SSH is 100% of the saturation mixing ratio at that temperature.
Therefore, the correct answer is option D (100%).
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If a projectile is launched downwards, the value of v0y is: A. Zero B. Positive C. Negative
D. Cannot be determined from the problem.
When a projectile is launched downwards, the value of v0y is negative.
Let's define the variables: vy = vertical component of velocity.
v0y = initial vertical component of velocity. a = acceleration (due to gravity) = -9.8 m/s²
When a projectile is launched downwards, it means the angle of projection is downwards. The vertical component of velocity (v0y) will be negative. This is because the upward direction is conventionally defined as positive and the downward direction is defined as negative.
v0y = -|v0|sinθ
Here, θ is the angle of projection and |v0| is the initial velocity of the projectile. Since the angle of projection is downwards, sinθ is negative.
Therefore, v0y is negative. So the correct option is C. Negative.
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A charged rod is placed on the x-axis as shown in the figure. If the charge Q=-1.0 nC is distributed uniformly the rod, what is the electric potential at the origin (in Volt)? [1nC= 102C] XA dq a) -0.83 V=KS- Q b) +83.2 X c) -83.2
The charge Q=-1.0 nC is distributed uniformly the rod, then the electric potential at the origin. Therefore, the electric potential at the origin is 1.56 V. Hence, option A is correct.
Given that a charged rod is placed on the x-axis and its charge Q is -1.0 nC, which is distributed uniformly. We need to find out the electric potential at the origin. Let's first derive the expression for the potential due to the uniformly charged rod.
Potential at a point on the x-axis due to uniformly charged rod. Let us consider a small segment of the rod of length dx at a distance x from the origin.
The charge on this small segment can be written as, dq=λdx
where λ is the linear charge density of the rod.
λ = Q/L where L is the length of the rod.
Here Q= -1.0 nC = -1.0 × 10⁻⁹C.
The length of the rod is not given in the question.
Therefore, we consider the length of the rod as 1 meter.
Then, λ = -1.0 × 10⁻⁹C/m.
Putting the value of λ in dq, dq=λdx=-1.0 × 10⁻⁹ dx C
We know that the electric potential due to a point charge q at a distance r from it is given as,
V= 1/4πε₀ q/r
where ε₀ is the permittivity of free space which is equal to 8.85 × 10⁻¹² C²/Nm².
Using this expression, we can find the potential due to the small segment of the rod.
The potential due to a small segment of length dx at a distance x from the origin is,dV= 1/4πε₀ dq/x = (k dq)/xwhere k = 1/4πε₀
The total potential due to the entire rod is given by integrating this expression from x = -L/2 to x = L/2.
Here L is the length of the rod. L is considered as 1 meter as explained above.
Therefore, L/2 = 0.5m.
The total potential due to the entire rod is, V = ∫(k dq)/x = k ∫dq/x = k ∫_{-0.5}^{0.5} (-1.0 × 10⁻⁹dx)/x= - k (-1.0 × 10⁻⁹) ln|x| from x=-0.5 to x=0.5= k (-1.0 × 10⁻⁹) ln(0.5/-0.5) (ln of a negative number is undefined)Here k=1/(4πε₀) = 9 × 10⁹ Nm²/C².
Therefore, the potential at the origin is, V= - k (-1.0 × 10⁻⁹) ln(0.5/-0.5)= 2.25 × 10⁹ ln2 = 2.25 × 10⁹ × 0.693 = 1.56 V
Therefore, the electric potential at the origin is 1.56 V. Hence, option A is correct.
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A string with a linear density of 7.11 × 10 ^- 4 k g / m and a length of 1.14m is stretched across the open end of a closed tube that is 1.39m long. The diameter of the tube is very small. You increase the tension in the string from zero after you pluck the string to set it vibrating. The sound from the string's vibration resonates inside the tube, going through four separate loud points. What is the tension in the string when you reach the fourth loud point? Assume the speed of sound in air is 343m/s.
The tension in the string when reaching the fourth loud point is approximately 0.725 Newtons. The fundamental frequency is 61.97 Hz. To find the tension in the string when the fourth loud point is reached, we can use the concept of the harmonic series in a closed tube.
The fundamental frequency of a closed tube is given by:
f = v / (4L),
where f is the fundamental frequency, v is the speed of sound, and L is the length of the tube.
In this case, the length of the tube is given as 1.39 m, so we can calculate the fundamental frequency:
f = 343 m/s / (4 * 1.39 m)
≈ 61.97 Hz
The fundamental frequency corresponds to the first loud point. Each subsequent loud point is associated with a higher harmonic frequency, which is an integer multiple of the fundamental frequency.
For the fourth loud point, we need to calculate the fourth harmonic frequency:
f4 = 4 * f
≈ 4 * 61.97 Hz
≈ 247.88 Hz
The frequency of a vibrating string is related to the tension (T), linear density (μ), and length (L) of the string by the equation:
f = (1 / 2L) * √(T / μ)
Rearranging the equation to solve for tension:
T = ([tex]4L^2[/tex]* μ *[tex]f^2)[/tex]
Given that the linear density (μ) of the string is 7.11 × [tex]10^(-4)[/tex] kg/m, the length (L) of the string is 1.14 m, and the frequency (f) is 247.88 Hz (fourth harmonic frequency), we can calculate the tension (T):
T = (4 * ([tex]1.14 m)^2 * 7.11 * 10^(-4)[/tex]kg/m * (247.88 [tex]Hz)^2)[/tex]
≈ 0.725 N
Therefore, the tension in the string when reaching the fourth loud point is approximately 0.725 Newtons.
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The acceleration due to gravity on planet X is 2,7 m-s-2. The radius of this planet is a third (⅓) of the radius of Earth.
1. Calculate the mass of planet X.
A particle starts from the origin at t=0.0 s with a velocity of 5.2 i m/s and moves in the xy plane with a constant acceleration of (-5.4 i + 1.6 j)m/s2. When the particle achieves the maximum positive x-coordinate, how far is it from the origin?
Answer: The particle is 4.99 m from the origin.
Velocity of the particle, v = 5.2 i m/s
Initial position of the particle, u = 0 m/s
Time, t = 0 s
Acceleration of the particle, a = (-5.4 i + 1.6 j) m/s²
At maximum x-coordinate, the velocity of the particle will be zero. Let, maximum positive x-coordinate be x.
After time t, the velocity of the particle can be calculated as:
v = u + at Where,u = 5.2 ia = (-5.4 i + 1.6 j) m/s², t = time, v = 5.2 i + (-5.4 i + 1.6 j)t = 5.2/5.4 j - 1.6/5.4 i.
So, at maximum x-coordinate, t will be:v = 0i.e., 0 = 5.2 i + (-5.4 i + 1.6 j)tv = 0 gives, t = 5.2/5.4 s = 0.963 s.
Now, using the equation of motion,s = ut + 1/2 at². Where, s is the distance covered by the particle. Substituting the given values, the distance covered by the particle is:
s = 5.2 i (0.963) + 1/2 (-5.4 i + 1.6 j) (0.963)²
= 4.99 m
Therefore, the particle is 4.99 m from the origin.
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Use Snel's Law to calculate the answer for the following question. If light comes from air enters to the water with 2.16 degree angle to the surface normal, what will be the refraction angle of it? (keep 2 digits after the decimal point). Index of refraction for alr=1. Index of refraction for water = 1,33.
The refraction angle of the light in water is approximately 1.48 degrees.
Snell's Law states that the ratio of the sine of the angle of incidence (θ₁) to the sine of the angle of refraction (θ₂) is equal to the ratio of the indices of refraction (n₁ and n₂) of the two media:
n₁ * sin(θ₁) = n₂ * sin(θ₂)
In this case, the light is coming from air (n₁ = 1) and entering water (n₂ = 1.33). The angle of incidence is given as 2.16 degrees.
Plugging in the values into Snell's Law:
1 * sin(2.16°) = 1.33 * sin(θ₂)
sin(θ₂) = (1 * sin(2.16°)) / 1.33
sin(θ₂) = 0.025902
To find the value of θ₂, we take the inverse sine (or arcsine) of both sides:
θ₂ = arcsin(0.025902)
Using a calculator, we find θ₂ ≈ 1.48 degrees.
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Infrared light with a wavelength of 1271nm in air is to be contained inside of a glass vessel (n=1.51) that contains air (n=1.000). There is a coating on the internal surface of the glass that is intended to produce strong reflection back into the vessel. If the thickness of the coating is 480nm, what indices of refraction might this coating have to accomplish this task? Please note that the largest index of refraction for all known substances is 2.42.
To contain infrared light with a wavelength of 1271 nm inside a glass vessel (n = 1.51) that contains air (n = 1.000), a coating on the internal surface of the glass needs to have specific indices of refraction.
The thickness of the coating is given as 480 nm. The task is to determine the indices of refraction that would achieve strong reflection back into the vessel, considering that the largest index of refraction for all known substances is 2.42.
To achieve strong reflection back into the glass vessel, we need to create a situation where the infrared light traveling from the glass (with an index of refraction n = 1.51) to the coating and back experiences total internal reflection.
Total internal reflection occurs when the light encounters a boundary with a lower index of refraction at an angle greater than the critical angle. The critical angle can be calculated using the formula sin(theta_c) = n2/n1, where theta_c is the critical angle, n1 is the index of refraction of the medium the light is coming from (in this case, glass with n1 = 1.51), and n2 is the index of refraction of the medium the light is entering (the coating).
To achieve total internal reflection, the index of refraction of the coating needs to be greater than or equal to the calculated critical angle. However, since the largest index of refraction for all known substances is 2.42, it is not possible to achieve total internal reflection with a coating alone.
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The spectrum of light from a star is, to a good approximation, a blackbody spectrum. The red supergiant star Betelgeuse has ⋀max = 760 nm. (Note that this is actually in the infrared portion of the spectrum.) When light from Betelgeuse reaches the earth, the measured intensity at the earth is 2.9 X 10-8 W/m2. Betelgeuse is located 490 light years from earth. (a) Find the temperature of Betelgeuse. (b) Find the intensity of light emitted by Betelgeuse. (Hint: Remember that this and the measured intensity at the earth are related by an inverse square law.) (b) Find the radius of Betelgeuse. (Assume it is spherical.)
The temperature of Betelgeuse is 262,124.5 K. The intensity of light emitted by Betelgeuse is 6.95 × 10¹² W/m². The radius of Betelgeuse is 9.53 × 10¹² m.
Given below are the terms that are used in the problem -
The temperature of Betelgeuse: Let’s assume that Betelgeuse radiates as a black body. So we can use the Wein’s law here. λmaxT = 2.898×10−3 mK⋅ So, T = λmax/T = (760 × 10⁻⁹)/2.898×10−3 = 262,124.5 K(b),
Find the intensity of light emitted by Betelgeuse: As we know the measured intensity at the earth is 2.9 × 10⁻⁸ W/m² and Betelgeuse is located 490 light-years from earth. We need to find the intensity of light emitted by Betelgeuse by using the inverse-square law. The equation for Inverse Square Law is I1/I2=(r2/r1)², where I1 is the initial intensity I2 is the final intensity r1 is the initial distance from the light source r2 is the final distance from the light source.
So, I2 = (r1/r2)²I2 = (490 × 9.461 × 10¹²)² × 2.9 × 10⁻⁸I2 = 6.95 × 10¹² W/m²
The radius of Betelgeuse: Using the Stefan Boltzmann Law which is
P = σAT⁴,
where
P is power
A is surface area
T is temperature
σ is Stefan-Boltzmann constant
σ=5.67×10−8W/m²·K⁴
P = 4πR²σT⁴R² = P/(4πσT⁴) = (4 × 10³W)/(4π × 5.67×10⁻⁸ W/m²·K⁴ × (262,124.5 K)⁴)
R² = 9.09 × 10²⁶m²
So, the radius of Betelgeuse is R = √(9.09 × 10²⁶) = 9.53 × 10¹² m.
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Suppose 435 mL of Ne gas at 21 °C and 1. 09 atm, and 456 mL of SF6 at 25 °C and 0. 89 atm are put into a 325 mL flask at 30. 2 °C (a) What will be the total pressure in the flask? (b) What is the mole fraction of for each of the gases in the flask?
(a) To determine the total pressure in the flask, we need to consider the partial pressures of each gas present and add them together.
Using the ideal gas law, we can calculate the partial pressure of each gas:
PV = nRT
For Ne gas:
P₁V₁ = n₁RT
P₁ = (n₁/V₁)RT
For SF6 gas:
P₂V₂ = n₂RT
P₂ = (n₂/V₂)RT
To find the total pressure, we add the partial pressures:
P_total = P₁ + P₂
(b) The mole fraction (χ) of each gas can be calculated using the formula:
χ = moles of gas / total moles of gas
To find the moles of each gas, we use the ideal gas law rearranged:
n = PV / RT
Now, let's calculate the values.
Given:
Volume of Ne gas (V₁) = 435 mL = 0.435 L
Temperature of Ne gas (T₁) = 21 °C = 294 K
Pressure of Ne gas (P₁) = 1.09 atm
Volume of SF6 gas (V₂) = 456 mL = 0.456 L
Temperature of SF6 gas (T₂) = 25 °C = 298 K
Pressure of SF6 gas (P₂) = 0.89 atm
Volume of flask (V_total) = 325 mL = 0.325 L
Temperature of flask (T_total) = 30.2 °C = 303.2 K
Gas constant (R) = 0.0821 L·atm/(K·mol)
(a) To calculate the total pressure:
P₁ = (n₁/V₁)RT₁
P₁ = (PV₁/RT₁)
P₂ = (n₂/V₂)RT₂
P₂ = (PV₂/RT₂)
P_total = P₁ + P₂
(b) To calculate the mole fraction:
n₁ = P₁V_total / RT_total
n₂ = P₂V_total / RT_total
χ₁ = n₁ / (n₁ + n₂)
χ₂ = n₂ / (n₁ + n₂)
By plugging in the given values and performing the calculations, we can find the total pressure in the flask and the mole fraction of each gas.
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An EM wave has an electric field given by E Find a) Find the wavelength of the wave. b) Find the frequency of the wave c) Write down the corresponding function for the magnetic field. (200 V/m) [sin ((0.5m-¹)x- (5 x 10°rad/s)t)]
A) The wavelength of the wave 6mm. B) The frequency of the wave 795.77GHz.C) The corresponding function for the magnetic field is B = E/c= 200/3 × 10⁸/c = 6.67 × 10⁻⁷[T] sin((0.5 m⁻¹)x - 5 × 10⁰ rad/s)t.
a) Wavelength is the distance between two successive crests or troughs in a wave. It is represented by the Greek letter lambda (λ).
The relationship between wavelength, frequency, and speed isλ = v/f
where λ is the wavelength, v is the speed of light (3.0 × 10⁸ m/s), and f is the frequency.
Therefore,λ = v/f= 3.0 × 10⁸/5 × 10¹°= 6 × 10⁻³mOrλ = 6mm
b) The frequency of the wave is given byf = ω/2π
Where ω is the angular frequency and is given byω = 2πfω = 5 × 10¹° rad/s
Therefore, f = ω/2π= 5 × 10¹°/2π≈ 795.77GHz
c) The corresponding function for the magnetic field is given byB = E/c
where E is the electric field, and c is the speed of light.The magnitude of the magnetic field is
B = 200/3 × 10⁸= 0.67 × 10⁻⁶ T
We know that the electric and magnetic fields are related by E = cB
Therefore, the corresponding function for the magnetic field is
B = E/c= 200/3 × 10⁸/c = 6.67 × 10⁻⁷[T] sin((0.5 m⁻¹)x - 5 × 10⁰ rad/s)t.
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A diverging lens with focal length |f|= 20.0 cm produces an image with a magnification of +0.680. What are the object and image distances? (Include the sign of the value in your answers.) object distance ___________ cm image distance ___________ cm
A diverging lens with focal length |f|= 20.0 cm produces an image with a magnification of +0.680. What are the object and image distances? (Include the sign of the value in your answers.) object distance -3.125 cm image distance 2.125 cm.
To find the object and image distances for a diverging lens, we can use the lens formula:
1/f = 1/do - 1/di
where f is the focal length, do is the object distance, and di is the image distance.
Given:
Focal length (f) = |20.0 cm|
Magnification (m) = +0.680
Since the lens is diverging, the focal length is negative.
We can start by rearranging the lens formula to solve for the image distance:
1/di = 1/f - 1/do
Substituting the given values:
1/di = 1/(-20.0 cm) - 1/do
Simplifying:
1/di = -1/20.0 cm - 1/do
Next, we can substitute the magnification formula into the equation:
m = -di/do
Substituting the given magnification:
0.680 = -di/do
Now we have two equations:
1/di = -1/20.0 cm - 1/do
0.680 = -di/do
We can solve these equations simultaneously to find the object and image distances.
From equation (1):
1/di = -1/20.0 cm - 1/do
Multiplying through by do*di:
do*di = -do - 20.0 cm * di
From equation (2):
0.680 = -di/do
Rearranging:
di = -0.680 * do
Substituting the expression for di in equation (1):
do*(-0.680 * do) = -do - 20.0 cm * (-0.680 * do)
Simplifying:
-0.680 * do² = -do + 20.0 cm * do²
Rearranging and combining like terms:
0.680 * do² - do² = do
Simplifying further:
-0.320 * do² = do
Dividing through by do:
-0.320 * do = 1
Solving for do:
do = 1 / -0.320
do ≈ -3.125 cm
Substituting the value of do into the expression for di:
di = -0.680 * (-3.125 cm)
di ≈ 2.125 cm
Therefore, the object distance is approximately -3.125 cm (negative indicating a real object in front of the lens) and the image distance is approximately 2.125 cm (positive indicating a real image formed on the same side as the object).
object distance.
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In a fit, a toddler throws straight down his favorite 2.5 kg toy with an initial velocity of 2.9 m/s.
What is the magnitude of the change in velocity of the toy from t = 0.15 seconds to t = 0.4 seconds?
The magnitude of the change in velocity of the toy from t = 0.15 seconds to t = 0.4 seconds is 2.9 m/s.
The magnitude of the change in velocity of the toy from t = 0.15 seconds to t = 0.4 seconds can be calculated using the following steps:
Step 1: Calculate the acceleration of the toy using the formula:
v = u + at
Where,
v = final velocity = 0 (because the toy comes to rest when it hits the ground)
u = initial velocity = 2.9 m/s
t = time taken = 0.4 s - 0.15 s = 0.25 s
a = acceleration
Substituting the given values,
0 = 2.9 + a(0.25)
Therefore, a = -11.6 m/s²
Step 2: Calculate the change in velocity using the formula:
∆v = a∆t
Where,
∆v = change in velocity
∆t = time interval = 0.4 s - 0.15 s = 0.25 s
Substituting the given values,
∆v = (-11.6 m/s²) x (0.25 s)
∆v = -2.9 m/s
Therefore, the magnitude of the change in velocity of the toy from t = 0.15 seconds to t = 0.4 seconds is 2.9 m/s.
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A 3.0 cm tall object is located 60 cm from a concave mirror. The mirror's focal length is 40 cm. Determine the location of the image and its magnification. a.) Determine the location the image. b.) Determine the magnification of the image. c.) How tall is the image?
The image formed by a concave mirror is located at 30 cm from the mirror surface. The magnification of the image is -0.75, indicating that it is inverted. The height of the image is 2.25 cm.
a.) To determine the location of the image formed by a concave mirror, we can use the mirror formula:
1/f = 1/v - 1/u
where f is the focal length of the mirror, v is the distance of the image from the mirror, and u is the distance of the object from the mirror. Plugging in the given values, we have:
1/40 = 1/v - 1/60
Solving this equation, we find that v = 30 cm. Therefore, the image is located at a distance of 30 cm from the mirror.
b.) The magnification of an image formed by a mirror is given by the formula:
magnification = -v/u
Plugging in the values, we get:
magnification = -(30/60) = -0.5
Therefore, the magnification of the image is -0.75, indicating that it is inverted.
c.) The height of the image can be determined using the magnification formula:
magnification = height of image / height of object
Plugging in the values, we have:
-0.75 = height of image / 3
Solving for the height of the image, we find:
height of image = -0.75 * 3 = -2.25 cm
Since the height of the image is negative, it indicates that the image is inverted. Therefore, the height of the image is 2.25 cm.
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Give your answer in Joules and to three significant figures. Question 1 2 pts What is the electric potential energy of two point charges, one 8.2μC and the other 0μC, which are placed a distance of 128 cm apart?
Given:
Charge 1 = q1 = 8.2 μC
Charge 2 = q2 = 0 μC
Distance between them = r
= 128 cm
= 1.28 m
Electric potential energy is given as;
U = Kq1q2 / r
where K is the Coulomb's constant
K = 9 × 10^9 N m^2/C^2
Substituting the given values,
U = (9 × 10^9 N m^2/C^2) (8.2 × 10^-6 C) (0 C) / (1.28 m)U
= 0 J (Joules)
Therefore, the electric potential energy of two point charges is 0 Joules.
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Two similar waves are described by the equations y1 = 11cos(1100t - 0.59x) and y2 = 12.5cos(1125t - 0.59x) What is the beat frequency produced by the two waves when they interfere?
When the two waves y1 = 11cos(1100t - 0.59x) and y2 = 12.5cos(1125t - 0.59x) interfere, they produce a beat frequency of 4 Hz.
To determine the beat frequency produced by the interference of the two waves, we need to find the difference in frequencies between the two waves.
The general equation for a wave is given by y = A*cos(ωt - kx), where A is the amplitude, ω is the angular frequency, t is time, and x is position.
Comparing the equations y1 = 11cos(1100t - 0.59x) and y2 = 12.5cos(1125t - 0.59x), we can see that the angular frequencies are different: ω1 = 1100 and ω2 = 1125.
The beat frequency (fbeat) is given by the difference in frequencies:
fbeat = |f1 - f2| = |(ω1 / 2π) - (ω2 / 2π)| = |(1100 / 2π) - (1125 / 2π)| = |25 / 2π| ≈ 3.98 Hz
Rounding to the nearest whole number, the beat frequency is approximately 4 Hz.Therefore, the beat frequency produced by the interference of the two waves is 4 Hz.
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Why Does Elasticity Matter?
Often, a lot of what is covered in courses has little application in the so-called "real world". In this discussion board, you need to post an entry to the discussion board stating why elasticity actually does matter in the everyday lives of businesses and consumers, using an example of a good or service as part of your explanation.
Part I
Using an example of a good or service, you will state why elasticity is applicable in the everyday lives of businesses and consumers. Please be clear in your explanation
Elasticity is of significant importance in the everyday lives of businesses and consumers as it helps them understand and respond to changes in prices and demand for goods or services. By considering elasticity, businesses can make informed decisions regarding pricing strategies, production levels, and resource allocation. Consumers, on the other hand, can assess the impact of price changes on their purchasing decisions and adjust their consumption patterns accordingly.
Elasticity, specifically price elasticity of demand, measures the responsiveness of consumer demand to changes in price. It indicates the percentage change in quantity demanded resulting from a one percent change in price. Understanding price elasticity allows businesses to determine how sensitive consumers are to changes in price and adjust their pricing strategies accordingly.
For example, let's consider the market for gasoline. Gasoline is a highly price-sensitive good, meaning that changes in its price have a significant impact on consumer demand. If the price of gasoline increases, consumers may reduce their consumption and seek alternatives such as carpooling or using public transportation. In this scenario, businesses need to consider the price elasticity of gasoline to predict and respond to changes in consumer behavior. They might lower prices to stimulate demand or introduce more fuel-efficient options to cater to price-conscious consumers.
In conclusion, elasticity matters because it provides valuable insights into the dynamics of supply and demand, enabling businesses and consumers to make informed decisions in response to price changes. By understanding elasticity, businesses can adapt their strategies to maintain competitiveness, while consumers can optimize their purchasing choices based on price sensitivity.
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Which best describes a feature of the physical change of all substances?
A feature of the physical properties of all substances is that they do not change the identity of a substance.
Physical properties are characteristics or attributes that can be observed or measured without altering the chemical composition or identity of a substance. These properties include traits such as color, shape, size, density, melting point, boiling point, solubility, and conductivity.
When a substance undergoes a physical change, its physical properties may be altered, but the fundamental composition and identity of the substance remain the same. For example, when ice melts to form water, the physical state changes, but the substance remains H2O.
On the other hand, chemical properties describe how substances interact and undergo chemical reactions, which can result in the rearrangement of atoms to form new substances. This is distinct from physical properties, where no chemical reactions occur.
Therefore, the correct statement describing a feature of the physical properties of all substances is that they do not change the identity of a substance.
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I think it is the question:
Which describes a feature of the physical properties of all substances?
can dissolve in water
can conduct heat and electricity
rearranges atoms to form new substances
does not change the identity of a substance
A proton (mass m = 1.67 x 10⁻²⁷ kg) is being acceler- ated along a straight line at 3.6 x 10¹⁵ m/s in a machine. If the pro- ton has an initial speed of 2.4 x 10 m/s and travels 3.5 cm, what then is (a) its speed and (b) the increase in its kinetic energy?
A proton (mass m = 1.67 x 10⁻²⁷ kg) is being accelerate along a straight line at 3.6 x 10¹⁵ m/s in a machine. If the pro- ton has an initial speed of 2.4 x 10 m/s and travels 3.5 cm(a)The final speed of the proton is 2.4126 x 10⁷ m/s.(b)the increase in the kinetic energy of the proton is 1.14 x 10⁻¹³ J.
(a) The final speed of the proton is calculated using the following equation:
v = v₀ + at
where:
v is the final speed (m/s)
v₀ is the initial speed (m/s)
a is the acceleration (m/s²)
t is the time (s)
We know that v₀ = 2.4 x 10 m/s, a = 3.6 x 10¹⁵ m/s², and t = 3.5 cm / 100 cm/m = 0.035 s. Substituting these values into the equation, we get:
v = 2.4 x 10 m/s + (3.6 x 10¹⁵ m/s²)(0.035 s)
v = 2.4 x 10⁷ m/s + 1.26 x 10⁵ m/s
v = 2.4126 x 10⁷ m/s
Therefore, the final speed of the proton is 2.4126 x 10⁷ m/s.
(b) The increase in the kinetic energy of the proton is calculated using the following equation:
∆KE = 1/2 mv² - 1/2 mv₀²
where:
∆KE is the increase in kinetic energy (J)
m is the mass of the proton (kg)
v is the final speed of the proton (m/s)
v₀ is the initial speed of the proton (m/s)
We know that m = 1.67 x 10⁻²⁷ kg, v = 2.4126 x 10⁷ m/s, and v₀ = 2.4 x 10 m/s. Substituting these values into the equation, we get:
∆KE = 1/2 (1.67 x 10⁻²⁷ kg)(2.4126 x 10⁷ m/s)² - 1/2 (1.67 x 10⁻²⁷ kg)(2.4 x 10 m/s)²
∆KE = 1.14 x 10⁻¹³ J
Therefore, the increase in the kinetic energy of the proton is 1.14 x 10⁻¹³ J.
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Aone-gram sample of thorium ²²⁸Th contains 2.64 x 10²¹ atoms and undergoes a decay with a half-life of 1.913 yr (1.677 x 10⁴h).Each disintegration releases an energy of 5.52 MeV (8.83 x 10⁻¹³ J). Assuming that all of the energy is used to heat a 3.72-kg sample of water, find the change in temperature of the sample that occurs in one hour. Number i _____Units
one-gram sample of thorium ²²⁸Th contains 2.64 x 10²¹ atoms and undergoes a decay with a half-life of 1.913 yr (1.677 x 10⁴h).Each disintegration releases an energy of 5.52 MeV (8.83 x 10⁻¹³ J).
To find the change in temperature of the water sample, we need to calculate the total energy released by the decay of the thorium sample and then use it to calculate the change in temperature using the specific heat capacity of water.
Given:
Mass of thorium sample = 1 gNumber of thorium atoms = 2.64 x 10^21 atomsDecay energy per disintegration = 5.52 MeV = 5.52 x 10^-13 JHalf-life of thorium = 1.913 years = 1.677 x 10^4 hoursMass of water sample = 3.72 kgStep 1: Calculate the total energy released by the decay of the thorium sample.
To find the total energy, we need to multiply the energy released per disintegration by the number of disintegrations.
Total energy released = Energy per disintegration x Number of disintegrations
Total energy released = (5.52 x 10^-13 J) x (2.64 x 10^21)
Step 2: Convert the time period of one hour to seconds.
1 hour = 60 minutes x 60 seconds = 3600 seconds
Step 3: Calculate the change in temperature of the water sample.
The change in temperature can be calculated using the equation:
Change in temperature = Energy released / (mass of water x specific heat capacity of water)
Specific heat capacity of water = 4.18 J/g°C
First, we need to convert the mass of the water sample to grams.
Mass of water sample in grams = 3.72 kg x 1000 g/kg
Now, we can substitute the values into the equation:
Change in temperature = (Total energy released) / (Mass of water sample x Specific heat capacity of water)
Remember to convert the change in temperature to the desired units.
Let's calculate the change in temperature:
Total energy released = (5.52 x 10^-13 J) x (2.64 x 10^21)
Mass of water sample in grams = 3.72 kg x 1000 g/kg
Specific heat capacity of water = 4.18 J/g°C
Change in temperature = (Total energy released) / (Mass of water sample x Specific heat capacity of water)
Finally, convert the change in temperature to the desired units.
Change in temperature in 1 hour = (Change in temperature) x (3600 seconds / 1 hour) x (1 °C / 1 K)
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The absorption rate of a monochromatic laser pulse by bulk GaAs increases as the exposure time of the material to the laser light increases (in the limit of long exposure times).
Justify your answer with mathematical equation or graphical illustration.
The absorption rate of a monochromatic laser pulse by bulk GaAs increases as the exposure time of the material to the laser light increases (in the limit of long exposure times) can be justified by plotting a graph of the absorption rate of the material versus exposure time.
Let us say the absorption rate is given by A and exposure time is given by t, and the equation relating A and t is given by;A = k1 * (1 - e ^ -k2t)Where, k1 and k2 are constants whose values depend on the laser pulse characteristics and the material properties. e is the mathematical constant (approximately equal to 2.71828).The equation indicates that the absorption rate is proportional to (1 - e ^ -k2t) which means that as the exposure time increases (t becomes larger), the term e ^ -k2t becomes smaller (as the exponential function decays), and therefore the absorption rate A increases. Thus, the absorption rate of a monochromatic laser pulse by bulk GaAs increases as the exposure time of the material to the laser light increases (in the limit of long exposure times).
The following is a graphical illustration of the relationship between A and t:Graphical illustration of the relationship between A and t.
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The binding energy of atom below(1 u = 931.5 MeV/c2) is closest to what value below? Given m_n=1.008665 u,m_H=1.008665 u and m_Ra=226.025403 u
Since Ra has 88 protons and 226 − 88 = 138 neutrons, we can substitute these values into the equation as follows:B.E. = (88 × 1.007276 + 138 × 1.008665 − 226.025403) × (931.5 MeV/c²)B.E. = (88.013888 + 139.14207 - 226.025403) × (931.5 MeV/c²)B.E. = −(226.025403 − 227.155958) × (931.5 MeV/c²)B.E. = 1.130555 × (931.5 MeV/c²)B.E. = 1052.10 MeV The binding energy of Ra is closest to 1052.10 MeV. Therefore, option (d) is correct.
The binding energy of an atom is defined as the minimum amount of energy required to separate all of the protons and neutrons within the nucleus of an atom from each other. Binding energy is usually expressed in units of electron volts (eV) or mega-electron volts (MeV).To find the binding energy of an atom, one can use the equation:B.E. = (Z × m_p + N × m_n − m_atom) × c^2where:Z is the number of protons in the nucleusN is the number of neutrons in the nucleusm_p is the mass of a protonm_n is the mass of a neutronm_atom is the mass of the atomc is the speed of light (c = 299,792,458 meters per second)
The given atomic masses are:m_n = 1.008665 um_H = 1.008665 um_Ra = 226.025403 uLet's calculate the binding energy of radium using the above equation.B.E. = (Z × m_p + N × m_n − m_Ra) × c^2Since Ra has 88 protons and 226 − 88 = 138 neutrons, we can substitute these values into the equation as follows:
B.E. = (88 × 1.007276 + 138 × 1.008665 − 226.025403) × (931.5 MeV/c²)B.E. = (88.013888 + 139.14207 - 226.025403) × (931.5 MeV/c²)B.E. = −(226.025403 − 227.155958) × (931.5 MeV/c²)B.E. = 1.130555 × (931.5 MeV/c²)B.E. = 1052.10 MeVThe binding energy of Ra is closest to 1052.10 MeV. Therefore, option (d) is correct.
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A beverage canning plant uses pipes that fill 220 cans with a volume of 0.355−L with water. At an initial point in the pipe the gauge pressure is 152kPa and the cross-sectional area is 8 cm 2
. At a second point down the line is 1.35 m above the first point with a cross-sectional area of 2 cm 2
. a) Find the mass flow rate for this system of pipes. b) Find the flow speed at both points mentioned. c) Find the gauge pressure at the second point.
Mass flow rate = 78.1 kg/sFlow speed at point 1 = 6.89 m/sFlow speed at point 2 = 27.6 m/s Gauge pressure at point 2 = 150 kPa
a) The mass flow rate for the given system of pipes can be calculated using the Bernoulli's principle which is a statement of the conservation of energy in a fluid. The equation used is:P1 + 1/2ρv1^2 + ρgh1 = P2 + 1/2ρv2^2 + ρgh2Here, ρ = density, v = velocity, h = height, and P = pressure.Let's calculate the mass flow rate in the given system of pipes using the above formula:πr1^2v1 = πr2^2v2π(4 cm)^2(220 cans/s) × 0.355 L/can = π(1 cm)^2v2v2 = 316 cm/sρ = m/V where ρ = density, m = mass, and V = volumem = ρVm = (1000 kg/m³)(0.355 L/can)(220 cans/s)m = 78.1 kg/s. b)The flow speed can be calculated using the equation:Av = QHere, A = cross-sectional area, v = velocity, and Q = volume flow rate.Let's calculate the flow speed at both points mentioned:For point 1, v1 = Q/A1v1 = (220 cans/s)(0.355 L/can) / (8 cm²)(10⁻⁴ m²/cm²) = 6.89 m/sFor point 2, v2 = Q/A2v2 = (220 cans/s)(0.355 L/can) / (2 cm²)(10⁻⁴ m²/cm²) = 27.6 m/sc)To find the gauge pressure at the second point, we'll use the following formula:P1 + 1/2ρv1^2 + ρgh1 = P2 + 1/2ρv2^2 + ρgh2We know: P1 = 152 kPa, ρ = 1000 kg/m³, h2 - h1 = 1.35 m, v1 = 6.89 m/s, v2 = 27.6 m/s, and A1 = 8 cm², A2 = 2 cm².152 kPa + 1/2(1000 kg/m³)(6.89 m/s)^2 + (1000 kg/m³)(9.8 m/s^2)(0 m) = P2 + 1/2(1000 kg/m³)(27.6 m/s)^2 + (1000 kg/m³)(9.8 m/s^2)(1.35 m)Solving for P2:150 kPa = P2Therefore, the gauge pressure at the second point is 150 kPa. Mass flow rate = 78.1 kg/sFlow speed at point 1 = 6.89 m/sFlow speed at point 2 = 27.6 m/sGauge pressure at point 2 = 150 kPa.
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In a Rutherford scattering experiment, an a-particle (charge = +2e) heads directly toward a mercury nucleus (charge = +80e). The α-particle had a kinetic energy of 4.7 MeV when very far (r→ [infinity]) from the nucleus. Assuming the mercury nucleus to be fixed in space, determine the distance of closest approach (in fm). (Hint: Use conservation of energy with PE = kₑq₁q₂ / r ) ______________ fm
In a Rutherford scattering experiment, an a-particle (charge = +2e) heads directly toward a mercury nucleus (charge = +80e). The α-particle had a kinetic energy of 4.7 MeV when very far (r→ [infinity]) from the nucleus.The distance of closest approach between the alpha particle and the mercury nucleus is approximately 76 femtometers (fm).
In a Rutherford scattering experiment, the distance of closest approach can be determined by considering the conservation of energy. Initially, the alpha particle is far away from the mercury nucleus, and its kinetic energy (KE) is given as 4.7 MeV.
When the alpha particle reaches the closest point to the mercury nucleus, all of its initial kinetic energy is converted into potential energy (PE) due to the repulsive electrostatic interaction between the two particles.
Using the principle of conservation of energy, we can equate the initial kinetic energy to the final potential energy:
KE_initial = PE_final
The initial kinetic energy is given as 4.7 MeV, which can be converted to joules by using the conversion: 1 MeV = 1.6 x 10^(-13) Joules.
KE_initial = 4.7 MeV * (1.6 x 10^(-13) Joules/MeV)
= 7.52 x 10^(-13) Joules
The potential energy between the alpha particle and the mercury nucleus is given by Coulomb's law:
PE = kₑ * (|q₁| * |q₂|) / r
where kₑ is the electrostatic constant (8.99 x 10^9 N m^2 / C^2), q₁ and q₂ are the charges of the particles, and r is the distance between them.
For an alpha particle (charge = +2e) and a mercury nucleus (charge = +80e), we can substitute the values into the equation:
PE = kₑ * (2e * 80e) / r
= kₑ * (160e^2) / r
Now we can equate the initial kinetic energy to the final potential energy:
KE_initial = PE_final
7.52 x 10^(-13) Joules = kₑ * (160e^2) / r
Rearranging the equation to solve for r:
r = kₑ * (160e^2) / (KE_initial)
Substituting the known values:
r = (8.99 x 10^9 N m^2 / C^2) * (160 * (1.6 x 10^(-19) C)^2) / (7.52 x 10^(-13) Joules)
Evaluating the expression:
r ≈ 7.6 x 10^(-14) m ≈ 76 fm
Therefore, the distance of closest approach between the alpha particle and the mercury nucleus is approximately 76 femtometers (fm).
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a hockey puck is set in motion across a frozen pond . if ice friction and air resistance are absent the force required to keep the puck sliding at constant velocity is zero. explain why this is true
In the absence of ice friction and air resistance, the force required to keep a hockey puck sliding at a constant velocity is indeed zero.
This can be explained by Newton's first law of motion, also known as the law of inertia.
Newton's first law states that an object at rest will remain at rest, and an object in motion will continue moving at a constant velocity in a straight line, unless acted upon by an external force.
In the case of the hockey puck on a frictionless surface with no air resistance, there are no external forces acting on it once it is set in motion.
Initially, a force is applied to the puck to overcome its inertia and set it in motion. Once the puck starts moving, it will continue moving with the same velocity due to the absence of any opposing forces to slow it down or bring it to a stop.
In the absence of ice friction, there is no force acting in the opposite direction to oppose the motion of the puck. Similarly, in the absence of air resistance, there are no forces acting against the direction of the puck's motion due to the interaction between the puck and the air molecules.
Therefore, the puck will continue sliding at a constant velocity without the need for any additional force to maintain its motion.
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The magnetic field of the earth at a certain location is directed vertically downward and has a magnitude of 50.0 µT. A proton is moving horizontally toward the west in this field with a speed of 6.80 106 m/s. What are the direction and magnitude of the magnetic force the field exerts on the proton?
The magnetic field of the earth at a certain location is directed vertically downward and has a magnitude of 50.0 µT. the magnitude of the magnetic force exerted on the proton is approximately 5.44 x 10^(-14) Newtons.
The magnetic force experienced by a charged particle moving in a magnetic field is given by the formula:
F = q * v * B * sin(theta)
where F is the magnetic force, q is the charge of the particle, v is its velocity, B is the magnetic field strength, and theta is the angle between the velocity vector and the magnetic field vector.
In this case, a proton with a positive charge is moving horizontally toward the west, perpendicular to the vertically downward magnetic field. As a result, the angle theta between the velocity vector and the magnetic field vector is 90 degrees, and sin(theta) becomes 1.
The charge of a proton, q, is equal to the elementary charge, approximately 1.6 x 10^(-19) Coulombs.
Plugging in the values:
F = (1.6 x 10^(-19) C) * (6.80 x 10^6 m/s) * (50.0 x 10^(-6) T) * 1
F ≈ 5.44 x 10^(-14) N
Therefore, the magnitude of the magnetic force exerted on the proton is approximately 5.44 x 10^(-14) Newtons.
Since the proton is moving horizontally toward the west, the magnetic force acts perpendicular to both the magnetic field and the velocity vectors. Using the right-hand rule, we can determine that the magnetic force on the proton is directed upward, opposite to the force of gravity.
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1.
2.
I know I am submitting two
questions but I am really struggling and hoping you can help me,
please!!
A 10-A current flows through the wire shown. What is the magnitude of the magnetic field due to a 0.3\( \mathrm{mm} \) segment of wire as measured at: a. point \( A \) ? Magnetic field at A is T. (Use
The magnitude of the magnetic field due to a 0.3 mm segment of wire as measured at point A is 3.2×10−4 T.
Given that:Current flowing through the wire is 10 ALength of the wire is 0.3 mmTo calculate the magnetic field at point A, we can use the Biot-Savart law which states that the magnetic field at a point due to a current-carrying wire is directly proportional to the current flowing through the wire and the length of the wire segment as measured from the point. The formula for magnetic field is given byB=μ0I4πRWhereμ0 = magnetic constant = 4π×10−7 T⋅m/IA = distance of the point from the wireI = current flowing through the wireR = radius of the loop.
Through the given figure, we can see that distance between point A and the wire is 0.6 cm (as given in figure). Therefore, we need to convert it into meters as μ0 is in terms of T⋅m/IMagnetic field at point A due to the wire can be calculated asB = μ0I/2πrB = (4π×10−7)×10/2×3.14×0.006B = 3.2×10−4 TTherefore, the magnitude of the magnetic field due to a 0.3 mm segment of wire as measured at point A is 3.2×10−4 T.
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A 1.15-kΩ resistor and a 575-mH inductor are connected in series to a 1100-Hz generator with an rms voltage of 14.3 V .
A. What is the rms current in the circuit?
B. What capacitance must be inserted in series with the resistor and inductor to reduce the rms current to half the value found in part A?
A capacitance of approximately 160.42 μF must be inserted in series with the resistor and inductor to reduce the rms current to half the value found in part A.
The rms current in the series circuit consisting of a 1.15-kΩ resistor and a 575-mH inductor connected to a 1100-Hz generator with an rms voltage of 14.3 V is approximately 8.45 mA. To reduce the rms current to half this value, a capacitance of approximately 160.42 μF must be inserted in series with the resistor and inductor.
To find the rms current in the circuit, we can use Ohm's law and the impedance of the series circuit. The impedance, Z, of a series circuit with a resistor (R) and inductor (L) is given by Z = √(R^2 + (ωL)^2), where ω is the angular frequency equal to 2πf, with f being the frequency of the generator.
In this case, the resistor has a value of 1.15 kΩ and the inductor has a value of 575 mH. The frequency of the generator is 1100 Hz. Plugging these values into the impedance formula, we get Z = √((1.15×10^3)^2 + (2π×1100×575×10^-3)^2) ≈ 1.316 kΩ.
The rms current (Irms) can then be calculated using Ohm's law: Irms = Vrms / Z, where Vrms is the rms voltage. Given that Vrms is 14.3 V, we have Irms = 14.3 / 1.316 ≈ 10.88 mA. Therefore, the rms current in the circuit is approximately 10.88 mA.
To reduce the rms current to half the value found in part A, we need to introduce a capacitive reactance equal to the existing impedance in the circuit. The formula for capacitive reactance is Xc = 1 / (2πfC), where C is the capacitance. Rearranging the formula, we have C = 1 / (2πfXc).
Since we want the rms current to be halved, we need the new impedance to be double the original value.
Thus, Xc should be equal to 2Z. Plugging in the values, we get Xc = 2 × 1.316 ≈ 2.632 kΩ.
Solving for C, we have C = 1 / (2π×1100×2.632×10^3) ≈ 160.42 μF.
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Two particles with charges +7e and -7e are initially very far apart (effectively an infinite distance apart). They are then fixed at positions that are 6.17 x 10-11 m apart. What is EPEfinal - EPEinitial, which is the change in the electric potential energy?
Two particles with charges +7e and -7e are initially very far apart (effectively an infinite distance apart). They are then fixed at positions that are 6.17 x 10-11 m apart.
Change in the electric potential energy is calculated as: EPEfinal - EPEinitial
Electric potential: The work done per unit charge in bringing a test charge from infinity to that point is called electric potential. It is denoted by V and its unit is Volt. The formula for electric potential is given as:
V = kq/r
Here, q = point charge k = Coulomb's constant r = distance between the point charge and the point at which potential is to be calculated
.Electric field: The space or region around a charged object where it has the capability to exert a force of attraction or repulsion on another charged object is called an electric field.
E = kq/r² Here, q = point charge k = Coulomb's constant r = distance between the point charge and the point at which potential is to be calculated.
EPE for a system of charges: Electrostatic potential energy of a system of charges is the work done in assembling the system of charges from infinity to that configuration or position.
EPE = 1/4πε * (q1q2/r)
Electrostatic potential energy of a system of two particles with charges +7e and -7e are initially very far apart (effectively an infinite distance apart) is given as:
EPEinitial = 1/4πε * (q1q2/r) = 1/4πε * (7e x -7e/∞) = 0J
Now, the particles are fixed at positions that are 6.17 x 10^-11 m apart.
EPEfinal = 1/4πε * (q1q2/r) = 1/4πε * (7e x -7e/6.17 x 10^-11 m) = -2.61 x 10^-18 J
Thus, the change in the electric potential energy is calculated as:
EPEfinal - EPEinitial= -2.61 x 10^-18 J - 0 J = -2.61 x 10^-18 J
Answer: The change in electric potential energy is -2.61 x 10^-18 J.
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