An experimenter measures the frequency, f, of an electromagnetic wave Its wavelength in free space is a) c/f b) cf c) f/c d) independent of the frequency.

Answer:

124.3 J/m^3

Explanation:

The energy density between the plates of a parallel-plate capacitor is given by

[tex]u=\frac{1}{2}\epsilon_0 E^2[/tex]

where

ε0 = 8.85 × 10-12 C2/N · m2 is the vacuum permittivity

E is the electric field strength

In this problem,

E = 5.3 × 106 V/m

So the energy density is

[tex]u=\frac{1}{2}(8.85\cdot 10^{-12}F/m) (5.3\cdot 10^6 V/m)^2=124.3 J/m^3[/tex]

The energy density between the plates of a capacitor can be calculated using the formula U = 0.5 * ε0 * E². By substituting the given values for the electric field (E) and the permittivity of free space (ε0) into the formula, we can ascertain the energy density.

To find the energy density between the plates of the capacitor we can use the formula U = 0.5 * ε0 * E².

First, we need to find the electric field (E) which is given to us as 5.3 × 10^6 V/m. The permittivity of free space (ε0) is 8.85 × 10^-12 C^2/N * m^2.

Then we substitute the values into the formula to calculate the energy density:

U = 0.5 * ε0 * E² = 0.5 * 8.85 × 10^-12 C^2/N * m^2 * (5.3 × 10^6 V/m)²

So, the energy density between the plates of the capacitor is calculated by using the given values of the electric field and permittivity of free space.

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Answer:

Minimum voltage, V = 0.682 mV          

Explanation:

It is given that,

Current passing through the human heart, [tex]I=2.5\times 10^{-6}\ A[/tex]

A patient is undergoing open-heart surgery, and the patient’s heart has a constant resistance, R = 273 ohms

We have to find the minimum voltage across the heart that could pose a danger to the patient. It can be calculated using Ohm's law as :

V = IR

[tex]V=2.5\times 10^{-6}\ A\times 273\ \Omega[/tex]

V = 0.0006825 volts

or

V = 0.682 mV

Hence, the minimum voltage across the heart that could pose a danger to the patient is 0.682 mV    

Answer:

A helium filled balloon floats forwards in a accelerating car because of the pressure difference between the front and the back of the car. When the car is accelerating, the air moves relitive to the car and the consequence is that the pressure in the back is slightly higher than in the front; which results in net force in forward direction.

hit that heart please leave brainliest and let me know if want me to answer or explain it in a different way :)

The helium balloon tilts forward in a car that is accelerating because the air inside the car is thrust backwards, creating more air pressure at the back and causing the balloon to float towards the lower pressure at the front. This behavior is unlike a pendulum that tilts backward due to the force of gravity.

The tilting of the helium balloon in a car that is accelerating forward can be explained using concepts from physics, particularly related to Newton's laws, the concept of a pendulum in equilibrium, and the buoyant Archimedean force.  

When a car accelerates, everything inside the car, including the air, is thrust backwards. This creates a higher air pressure at the back of the car than at the front. The helium balloon will float towards the lower pressure, which is at the front of the car, so the balloon will appear to tilt forward. This contrasts with the backward tilt of a pendulum, as a pendulum is influenced primarily by the force of gravity, which acts downward.

In terms of calculating the angle of tilt, it would be necessary to know the buoyant force applied to the balloon (which depends on the pressure gradient in the air), the acceleration of the car, and the mass of the balloon. However, without numerical values for these variables, a specific angle of tilt cannot be determined in this context.

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Answer:

Magnetic force, [tex]F=1.12\times 10^{-13}\ N[/tex]

Explanation:

It is given that,

Velocity of proton, [tex]v=1.8\times 10^6\ m/s[/tex]

Angle between velocity and the magnetic field, θ = 53°

Magnetic field, B = 0.49 T

The mass of proton, [tex]m=1.672\times 10^{-27}\ kg[/tex]

The charge on proton, [tex]q=1.6\times 10^{-19}\ C[/tex]

The magnitude of magnetic force is given by :

[tex]F=qvB\ sin\theta[/tex]

[tex]F=1.6\times 10^{-19}\ C\times 1.8\times 10^6\ m/s\times 0.49\ Tsin(53)[/tex]

[tex]F=1.12\times 10^{-13}\ N[/tex]

So, the magnitude of the magnetic force on the proton is [tex]1.12\times 10^{-13}\ N[/tex]. Hence, this is the required solution.

Answer:

7.54 m/s²

Explanation:

uₓ(t) = (0.980 m/s³) t²

Acceleration is the derivative of velocity with respect to time.

aₓ(t) = 2 (0.980 m/s³) t

aₓ(t) = (1.96 m/s³) t

When uₓ = 14.5 m/s, the time is:

14.5 m/s = (0.980 m/s³) t²

t = 3.85 s

Plugging into acceleration equation:

aₓ = (1.96 m/s³) (3.85 s)

aₓ = 7.54 m/s²

This question is dealing with velocity, acceleration and time of motion.

Acceleration is; aₓ = 7.54 m/s²

We are told that the eastward component of the car's velocity is;

uₓ(t) = (0.980 m/s³) t²

Now, from calculus differentiation in maths, we know that with respect to time, the derivative of velocity is equal to the acceleration.

Thus;

aₓ(t) = du/dt = 2t(0.980 m/s³)  

aₓ(t) = 1.96t m/s³

We w ant to find the acceleration of the car when velocity is; uₓ = 14.5 m/s. Let us find the time first and then plug the value into the acceleration equation.

Thus;

14.5 m/s = (0.980 m/s³) t²

14.5/0.98 = t²

t = 3.85 s

Putting 3.85 for t in the acceleration equation to get;

aₓ = (1.96 m/s³) (3.85 s)

aₓ = 7.54 m/s²

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Answer:

V=-5304.6V

Explanation:

(I set the charge density unit to microcoulombs per metre cubed)

Answer:

In the picture.

Final answer:

To find the electric potential 5 m from the center of the uniformly charged sphere, the sphere is treated as a point charge resulting from its total charge due to the volume charge density. The potential is calculated using Coulomb's law for a point charge, yielding a value of -0.399 MV.

Explanation:

To calculate the electric potential a distance 5 m from the center of a uniformly charged solid sphere with radius R = 0.4 m and charge density [tex]\\rho = -11 \mu C/m^3\[/tex], we use the concept of electric potential due to a continuous charge distribution. Since the point where we need to find the potential is outside the sphere, we can treat the sphere as a point charge located at its center with total charge Q.

The total charge Q can be found by integrating the charge density over the volume of the sphere:

[tex]Q = \int \rho \, dV = \rho \frac{4}{3}\pi R^3[/tex]

Plugging the values in, we have:

[tex]Q = -11 \times 10^{-6} C/m^3 \times \frac{4}{3}\pi \times (0.4 m)^3\\Q = -2.21 \times 10^{-7} C[/tex]

Now, the electric potential V at a distance r from a point charge Q is given by:

[tex]V = \frac{kQ}{r}[/tex]

where k is Coulomb's constant, k = 8.99 \times 10^9 N m^2/C^2 and r is the distance from the center of the sphere, which is 5 m in this case. Thus:

[tex]V = \frac{8.99 \times 10^9 N m^2/C^2 \times (-2.21 \times 10^{-7} C)}{5 m}[/tex]

V = -0.399 MV

Answer: [tex]813.13(10)^{-7}F[/tex]

Explanation:

The answer is not among the given options. However, this is a good example of the relation between the energy stored in a capacitor [tex]W[/tex]and its capacitance [tex]C[/tex], which is given by the following equation:

[tex]W=\frac{1}{2}CV^{2}[/tex]   (1)

Where:

[tex]W=1275J[/tex]

[tex]V=5.6kV=5.6(10)^{3}V[/tex] is the voltage

[tex]C[/tex] is the capacitance in Farads, the value we want to find

Isolating [tex]C[/tex] from (1):

[tex]C=\frac{2W}{V^{2}}[/tex]   (2)

[tex]C=\frac{2(1275J)}{(5.6(10)^{3}V)^{2}}[/tex]   (3)

Finally:

[tex]C=0.000081313F=813.13(10)^{-7}F[/tex] This is the capacitance of the cardiac defibrillator

Explanation:

It is given that,

Radius of circular particle accelerator, r = 1 m

The distance covered by the particle is equal to the circumference of the circular path, d = 2πr

d = 2π × 1 m

(a) The speed of satellite is given by total distance divided by total time taken as :

[tex]speed=\dfrac{distance}{time}[/tex]

Let t is the period of the particle.

[tex]t=\dfrac{d}{s}[/tex]

d = distance covered

s = speed of particle

It is given that the charged particle is moving nearly with the speed of light

[tex]t=\dfrac{d}{c}[/tex]

[tex]t=\dfrac{2\pi\times 1\ m}{3\times 10^8\ m/s}[/tex]

[tex]t=2.09\times 10^{-8}\ s[/tex]

(b) On the circular path, the centripetal acceleration is given by :

[tex]a=\dfrac{c^2}{r}[/tex]

[tex]a=\dfrac{(3\times 10^8\ m/s)^2}{1\ m}[/tex]

[tex]a=9\times 10^{16}\ m/s^2[/tex]

Hence, this is the required solution.

Answer:

2000 W

Explanation:

First of all, we need to find the output voltage in the transformer, by using the transformer equation:

[tex]\frac{V_1}{N_1}=\frac{V_2}{N_2}[/tex]

where here we have

V1 = 200 V is the voltage in the primary coil

V2 is the voltage in the secondary coil

N1 = 250 is the number of turns in the primary coil

N2 = 500 is the number of turns in the secondary coil

Solving for V2,

[tex]V_2 = N_2 \frac{V_1}{N_1}=(500) \frac{200 V}{250}=400 V[/tex]

Now we can find the power output, which is given by

P = VI

where

V = 400 V is the output voltage

I = 5 A is the output current

Substituting,

P = (400 V)(5 A) = 2,000 W

The radius of the circle around which samples travel in the mentioned ultracentrifuge is approximately 4.18 cm. This was calculated using the centripetal acceleration and the rotational speed of the ultracentrifuge, demonstrating how principles of physics apply to scientific and medical practices.

An ultracentrifuge utilizes very high speeds and centripetal acceleration to separate minute biological components in a sample. Given that the ultracentrifuge mentioned spins at 120,000 rotations per minute (rpm) and the centripetal acceleration recorded is 6.6×10⁶ m/s², we need to determine the radius of the circle around which these samples travel. This can be formulated using the physics concept of uniform circular motion.

To solve this, we will use the formula for centripetal acceleration, which is a = ω²r, where 'a' is centripetal acceleration, 'ω' is angular velocity, and 'r' is the radius of the circle. First, we need to convert the rotational speed from rpm to radians per second: 1 rpm is equal to 2π rad/60 s, so 120,000 rpm equals 2π * 120,000 / 60 = 12,566 rad/s. Then, we substitute these values into the formula and solve for the radius, giving us r = a/ω² ≈ 0.0418 meters or 4.18 cm.

The samples would therefore travel around a circular path with a radius of approximately 4.18 cm. This is a great example of how the principles of physics are used in scientific and medical practices, like the operation of an ultracentrifuge.

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The radius of the circle around which the samples travel in the ultracentrifuge is approximately 13.2 millimeters.

Calculating the Radius of Circular Motion in an Ultracentrifuge

To determine the radius of the circle around which the samples travel in an ultracentrifuge, use the formula for centripetal acceleration: a = ω²r, where a is the centripetal acceleration, ω is the angular velocity in radians per second, and r is the radius.

First, convert the given rotational speed from revolutions per minute (rpm) to radians per second:

Given: 120,000 rpm

Convert rpm to revolutions per second: 120,000 rpm ÷ 60 seconds/min = 2,000 revolutions per second

Convert revolutions per second to radians per second (since there are 2π radians in one revolution): 2,000 rev/s × 2π radians/rev = 4,000π radians/second

Now that we have the angular velocity, we can use the centripetal acceleration formula. Rearrange the formula to solve for radius r:

r = a / ω²

Substitute the given values (where a = 6.6×106 m/s² and ω = 4,000π rad/s):

r = 6.6×106 m/s² / (4,000π rad/s)²

Calculate the radius:

Square the angular velocity: (4,000π rad/s)² = 16,000,000π² rad²/s²

Divide the acceleration by the squared angular velocity: r = 6.6×[tex]10^6[/tex] m/s² / 16,000,000π² rad²/s² = 0.131 / π² m

Simplify using π ≈ 3.14159: r ≈ 0.131 / (3.14159)² ≈ 0.0132 m or 13.2 mm

Thus, the radius of the circle around which the samples travel in the ultracentrifuge is approximately 13.2 millimeters.

The location of the coin's final image is at -6.00 cm from the diverging lens, and the magnification of the image is 0.50, indicating that the image is half the size of the object.

To find the location and magnification of the coin's final image, we need to use the lens equation in combination with the mirror equation. First, we will calculate the position of the coin's image formed by the converging lens:

So, the location of the coin's final image is at -6.00 cm from the diverging lens. To calculate the magnification, we can use the formula m = -di/do, where di is the image distance and do is the object distance. Substituting the values, we get m = -(-6.00 cm)/(-12.0 cm) = 0.50. Therefore, the magnification of the coin's final image is 0.50, indicating that the image is half the size of the object.

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Answer:

106.7 N

Explanation:

We can solve the problem by using the impulse theorem, which states that the product between the average force applied and the duration of the collision is equal to the change in momentum of the object:

[tex]F \Delta t = m (v-u)[/tex]

where

F is the average force

[tex]\Delta t[/tex] is the duration of the collision

m is the mass of the ball

v is the final velocity

u is the initial velocity

In this problem:

m = 0.200 kg

u = 20.0 m/s

v = -12.0 m/s

[tex]\Delta t = 60.0 ms = 0.06 s[/tex]

Solving for F,

[tex]F=\frac{m(v-u)}{\Delta t}=\frac{(0.200 kg) (-12.0 m/s-20.0 m/s)}{0.06 s}=-106.7 N[/tex]

And since we are interested in the magnitude only,

F = 106.7 N

The magnitude of the average force applied to the ball was about 107 N

[tex]\texttt{ }[/tex]

Newton's second law of motion states that the resultant force applied to an object is directly proportional to the mass and acceleration of the object.

[tex]\large {\boxed {F = ma }[/tex]

F = Force ( Newton )

m = Object's Mass ( kg )

a = Acceleration ( m )

Let us now tackle the problem !

[tex]\texttt{ }[/tex]

Given:

initial velocity of the ball = u = -20.0 m/s

final velocity of the ball = v = 12.0 m/s

contact time = t = 60.0 ms = 0.06 s

mass of the ball = m = 0.200 kg

Asked:

average force applied to the ball = F = ?

Solution:

We will use this following formula to solve this problem:

[tex]\Sigma F = ma[/tex]

[tex]F = m ( v - u ) \div t[/tex]

[tex]F = 0.200 ( 12 - (-20) ) \div 0.06[/tex]

[tex]F = 0.200 ( 32 ) \div 0.06[/tex]

[tex]F = 6.4 \div 0.06[/tex]

[tex]F = 106 \frac{2}{3} \texttt{ N}[/tex]

[tex]F \approx 107 \texttt{ N}[/tex]

[tex]\texttt{ }[/tex]

[tex]\texttt{ }[/tex]

Grade: High School

Subject: Physics

Chapter: Dynamics

[tex]\texttt{ }[/tex]

Keywords: Gravity , Unit , Magnitude , Attraction , Distance , Mass , Newton , Law , Gravitational , Constant

Answer:

Maximum height, h = 11.32 meters

Explanation:

It is given that,

The baseball is thrown directly upward at time, t = 0

Initial speed of the baseball, u = 14.9 m/s

Ignoring the resistance in this case and using a = g = 9.8 m/s²

We have to find the maximum height the ball reaches above where it leaves your hand. Let the maximum height is h. Using third equation of motion as :

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

At maximum height, v = 0

and a = -g = -9.8 m/s²

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

[tex]h=\dfrac{0-(14.9\ m/s)^2}{2\times -9.8\ m/s^2}[/tex]

h = 11.32 meters

Hence, the maximum height of the baseball is 11.32 meters.

Answer:

0.018 J

Explanation:

The work done to bring the charge from infinity to point P is equal to the change in electric potential energy of the charge - so it is given by

[tex]W = q \Delta V[/tex]

where

[tex]q=3.0 \mu C = 3.0 \cdot 10^{-6} C[/tex] is the magnitude of the charge

[tex]\Delta V = 6.0 kV = 6000 V[/tex] is the potential difference between point P and infinity

Substituting into the equation, we find

[tex]W=(3.0\cdot 10^{-6}C)(6000 V)=0.018 J[/tex]

The work required to move a 3.0 μC charge from infinity to point P with an electric potential of 6.0 kV is 0.018 Joules. This is calculated using the formula W = qV. Substituting the given values into the formula yields the answer.

The work required to move a charge in an electric potential is given by the formula:

W = qV

where W is work, q is the charge, and V is the electric potential. Here, the electric potential V at point P is 6.0 kV (or 6000 V), and the charge q is 3.0 μC (or 3.0 × 10⁻⁶ C).

Substitute the values into the formula:

W = (3.0 × 10⁻⁶ C) × (6000 V)

Which simplifies to:

W = 0.018 J

Therefore, the work required of an external agent to move the 3.0 μC charge from infinity to point P is 0.018 Joules.

Answer:

The potential energy change is 0.596 J.

Explanation:

Given that,

Potential difference =14.9 V

Charge q =0.0400 C

We need to calculate the change potential energy

The potential energy change is the product of the charge and potential difference.

Using formula of change potential energy

[tex]\Delta U=q\Delta V[/tex]

[tex]\Delta U=0.0400\times14.9[/tex]

[tex]\Delta U=0.596\ J[/tex]

Hence, The potential energy change is 0.596 J.

Answer:

0.596 J.

Explanation:

acellus

Answer:

(1) 2.05 x 10^4 N/C

(2) Downward

(3) upward, 9.8 m/s^2

(4) upward, 9.8 m/s^2

Explanation:

q = - 2.1 micro coulomb, m = 0.0044 kg, g = 9.8 m/s^2

(1) The electric force is given by F = - q x E

The magnitude of electric force is balanced by the weight of the charged particle

q x E = m x g

E = mg / q

[tex]E = \frac{0.0044 \times 9.8}{2.1 \times 10^{-6}}[/tex]

E = 2.05 x 10^4 N/C

(2) As the electric force is acting upward and the weight is downward so the elecric field is in downward direction.

(3) The charge is doubled,

then the electric field becomes half.

E = 2.05 x 10^4 / 2 = 1.025 x 10^4 N/C

The direction is same that is in downward direction.

Acceleration = Force / mass

a = mg / m = 9.8 m/s^2 upward

(4) The charge is doubled,

then the electric field becomes half.

E = 2.05 x 10^4 / 2 = 1.025 x 10^4 N/C

The direction is same that is in downward direction.

Acceleration = Force / mass

a = mg / m = 9.8 m/s^2 upward

The magnitude of the electric field and the direction of the electric filed acting on the object is,

The electric field is the field, which is surrounded by the electric charged. The electric field is the electric force per unit charge.

The mass of the object is 0.0044 kg, and the charge on the object is -2.1   μC.

As the electric field is the ratio of force (due to gravity in given case) to the charge given on it. Thus the magnitude of the electric field of 0.0044 kg object is,

[tex]E=\dfrac{0.0044\times9.8}{2.1\times10^{-6}}\\E=2.05\times10^{4}\rm N/C[/tex]

The electric force acting on the body is in the upward direction Thus, to balance this, the electric field acts on the body is in the downward direction.

(3) The electric charge on the object is doubled while its mass remains the same, then the direction and magnitude of its acceleration-

When the electric charge on the object is doubled while its mass remains the same, then the strength of the electric field is halved. Therefore,

[tex]E=\dfrac{2.05\times10^4}{2}\\E=1.025\times10^4\rm N/C[/tex]

The electric force acting on the body is in the upward direction Thus, to balance this, the electric field acts on the body is in the downward direction.

Hence, the magnitude of the electric field and the direction of the electric filed acting on the object is,

Learn more about electric field here;

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Answer: [tex]W_{n}=5.724 (10)^{13})N[/tex]

Explanation:

The weight [tex]W[/tex] of a body or object is given by the following formula:

[tex]W=m.g[/tex] (1)

From here we can find the mass of the body:

[tex]m=\frac{W}{g}=67.346 kg[/tex] (2)

Where [tex]m[/tex] is the mass of the body and [tex]g[/tex] is the acceleration due gravity in an especific place (in this case the earth).

In the case of a neutron star, the weight [tex]W_{n}[/tex] is:

[tex]W_{n}=m.g_{n}[/tex] (3)

Where [tex]g_{n}[/tex] is the acceleration due gravity in the neutron star.

Now, the acceleration due gravity (free-fall acceleration) [tex]g[/tex] of a body is given by the following formula:

[tex]g=\frac{GM}{r^{2}}[/tex] (4)

Where:

[tex]G=6.674(10)^{-11}\frac{m^{3}}{kgs^{2}}[/tex] is the gravitational constant

[tex]M[/tex] the mass of the body (the neutron star in this case)

[tex]r[/tex] is the distance from the center of mass of the body to its surface. Assuming the neutron star is a sphere with a diameter [tex]d=24km[/tex], its radius is [tex]r=\frac{d}{2}=12.5km=12500m [/tex]

Substituting (4) and (2) in (3):

[tex]W_{n}=m(\frac{GM}{r^{2}})[/tex] (5)

[tex]W_{n}=(67.346kg)(\frac{(6.674(10)^{-11}\frac{m^{3}}{kgs^{2}})(1.99(10)^{30}kg)}{(12500m)^{2}})[/tex] (6)

Finally:

[tex]W_{n}=5.724 (10)^{13})N[/tex]

If you weigh 660 N on Earth, you would weigh approximately[tex]\(1.133 \times 10^{-10}\)[/tex]N on the surface of a neutron star with the same mass as our sun and a diameter of 25.0 km.

To find the weight of an object on the surface of a neutron star, you can use the formula for gravitational force:

[tex]\[ F = \frac{{G \cdot M \cdot m}}{{r^2}} \][/tex]

where:

[tex]\( F \)[/tex] is the gravitational force,

[tex]\( G \)[/tex]  is the gravitational constant[tex](\(6.67 \times 10^{-11} \ \text{N} \cdot \text{m}^2/\text{kg}^2\))[/tex],

[tex]\( M \)\\[/tex] is the mass of the neutron star (in this case, the mass of the sun, [tex]\(1.99 \times 10^{30} \ \text{kg}\))[/tex],

[tex]\( m \)[/tex] is the mass of the object (your mass in this case),

[tex]\( r \)[/tex] is the distance from the center of the object to the center of mass of the object (the radius in this case).

The weight (W) of an object is given by[tex]\( W = m \cdot g \)[/tex], where (g ) is the acceleration due to gravity on the object's surface.

First, let's find the radius of the neutron star (r). The diameter (D) is given as 25.0 km, so the radius ( r ) is half of the diameter:

[tex]\[ r = \frac{D}{2} = \frac{25.0 \ \text{km}}{2} = 12.5 \ \text{km} \][/tex]

Now, convert the radius to meters (1 km = 1000 m):

[tex]\[ r = 12.5 \ \text{km} \times 1000 \ \text{m/km} = 1.25 \times 10^4 \ \text{m} \][/tex]

Now, substitute the values into the gravitational force formula:

[tex]\[ F = \frac{{G \cdot M \cdot m}}{{r^2}} \][/tex]

[tex]\[ F = \frac{{(6.67 \times 10^{-11} \ \text{N} \cdot \text{m}^2/\text{kg}^2) \cdot (1.99 \times 10^{30} \ \text{kg}) \cdot (m)}}{{(1.25 \times 10^4 \ \text{m})^2}} \][/tex]

Now, set this force equal to the weight on Earth:

[tex]\[ \frac{{G \cdot M \cdot m}}{{r^2}} = m \cdot g \][/tex]

Solve for (m):

[tex]\[ m = \frac{{r^2 \cdot g}}{{G \cdot M}} \][/tex]

Plug in the values:

[tex]\[ m = \frac{{(1.25 \times 10^4 \ \text{m})^2 \cdot (9.81 \ \text{m/s}^2)}}{{6.67 \times 10^{-11} \ \text{N} \cdot \text{m}^2/\text{kg}^2 \cdot 1.99 \times 10^{30} \ \text{kg}}} \][/tex]

Now, calculate \( m \), and then use \( W = m \cdot g \) to find the weight on the surface of the neutron star.

Let's calculate the mass (m) first:

[tex]\[ m = \frac{{(1.25 \times 10^4 \ \text{m})^2 \cdot (9.81 \ \text{m/s}^2)}}{{6.67 \times 10^{-11} \ \text{N} \cdot \text{m}^2/\text{kg}^2 \cdot 1.99 \times 10^{30} \ \text{kg}}} \][/tex]

[tex]\[ m = \frac{{1.5625 \times 10^8 \ \text{m}^2 \cdot 9.81 \ \text{m/s}^2}}{{1.32733 \times 10^{20} \ \text{N}}} \][/tex]

[tex]\[ m \approx \frac{{1.5331875 \times 10^9 \ \text{m}^2}}{{1.32733 \times 10^{20} \ \text{N}}} \][/tex]

[tex]\[ m \approx 1.155 \times 10^{-11} \ \text{kg} \][/tex]

Now, calculate the weight (W) on the surface of the neutron star:

[tex]\[ W = m \cdot g \][/tex]

[tex]\[ W \approx (1.155 \times 10^{-11} \ \text{kg}) \cdot (9.81 \ \text{m/s}^2) \][/tex]

[tex]\[ W \approx 1.133 \times 10^{-10} \ \text{N} \][/tex]

So, if you weigh 660 N on Earth, you would weigh approximately[tex]\(1.133 \times 10^{-10}\)[/tex]N on the surface of a neutron star with the same mass as our sun and a diameter of 25.0 km.

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Explanation:

Initial energy = final energy + work done by friction

PE = PE + KE + W

mgH = mgh + 1/2 mv² + W

(800)(9.8)(30) = (800)(9.8)(2) + 1/2 (800) v² + 25000

v = 22.1 m/s

Without friction:

PE = PE + KE

mgH = mgh + 1/2 mv²

(800)(9.8)(30) = (800)(9.8)(2) + 1/2 (800) v²

v = 23.4 m/s

Answer:

The rate of change of the momentum is 196.5 kg-m/s²

Explanation:

Given that,

Speed v = 29 m/s

Radius = 9 m

Momentum = 61 kg-m/s

We need to calculate the rate of change of the momentum

Using formula of momentum

[tex]F = \dfrac{\Delta p}{\Delta t}[/tex]

[tex]F=\dfrac{\Delta(mv)}{\Delta t}[/tex].....(I)

Using newtons second law

[tex]F = ma=m\dfrac{v^2}{r}[/tex]

[tex]F = \dfrac{mv(v)}{r}[/tex]....(II)

From equation (I) and (II)

[tex]\dfrac{\Delta p}{\Delta t}=\dfrac{61\times29}{9}[/tex]

[tex]\dfrac{\Delta p}{\Delta t}=196.5\ kg-m/s^2[/tex]

Hence, The rate of change of the momentum is 196.5 kg-m/s²

Answer:

The average acceleration is 8.06 m/s².

Explanation:

It is given that,

Initial speed of the jet, u = 120 mph = 176 ft/s

Final velocity of the jet, v = 30 mph = 44 ft/s

Distance, d = 1800 ft

We need to find the average acceleration required of the airplane during braking. It can be calculated using third law of motion as :

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

a = acceleration

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

[tex]a=\dfrac{(44\ ft/s)^2-(176\ ft/s)^2}{2\times 1800\ ft}[/tex]

[tex]a=-8.06\ ft/s^2[/tex]

So, the average acceleration required of the airplane during braking is -8.06 ft/s². Hence, this is the required solution.

Answer:

Explanation:

Formula

W = I * E

Givens

W = 150

E = 120

I = ?

Solution

150 = I * 120   Divide by 120

150/120 = I

5/4  = I

I = 1.25

Note: This is an edited note. You have to assume that 120 is the RMS voltage in order to go any further. That means that the peak voltage is √2 times the size of 120. The current has the same note applied to it. If the voltage is its rms value, then the current must (assuming the properties of the bulb do not change)

On the other hand, if the voltage is the peak value at 120 then 1.25 will be correct.

However I would go with the other answerer's post and multiply both values by  √2

This question is about as sneaky as they ever get.

First let's do the easy part:

Power = (voltage) x (current)

150 watts = (120 volts) x (current)

current = (150 watts) / (120 volts)

current = 1.25 Amperes but this is NOT the answer to the question.

The voltage at the outlet is a "sinusoidal" wave ... it wiggles up and down 60 times every second.  The number of "120 volts" is NOT the "peak" of the wave.  In fact , the highest it ever gets is  √2  greater than 120 volts.  And all of this applies to the current too.

The RMS current through the lamp is (150/120) = 1.25 Amperes .

The peak current through the lamp is  1.25·√2 = about 1.77 Amperes .

(a) [tex]t=\frac{v}{a_1}+\frac{v}{a_2}[/tex]

In the first part of the motion, the car accelerates at rate [tex]a_1[/tex], so the final velocity after a time t is:

[tex]v = u +a_1t[/tex]

Since it starts from rest,

u = 0

So the previous equation is

[tex]v= a_1 t[/tex]

So the time taken for this part of the motion is

[tex]t_1=\frac{v}{a_1}[/tex] (1)

In the second part of the motion, the car decelerates at rate [tex]a_2[/tex], until it reaches a final velocity of v2 = 0. The equation for the velocity is now

[tex]v_2 = v - a_2 t[/tex]

where v is the final velocity of the first part of the motion.

Re-arranging the equation,

[tex]t_2=\frac{v}{a_2}[/tex] (2)

So the total time taken for the trip is

[tex]t=\frac{v}{a_1}+\frac{v}{a_2}[/tex]

(b) [tex]d=\frac{v^2}{2a_1}+\frac{v^2}{2a_2}[/tex]

In the first part of the motion, the distance travelled by the car is

[tex]d_1 = u t_1 + \frac{1}{2}a_1 t_1^2[/tex]

Substituting u = 0 and [tex]t_1=\frac{v}{a_1}[/tex] (1), we find

[tex]d_1 = \frac{1}{2}a_1 \frac{v^2}{a_1^2} = \frac{v^2}{2a_1}[/tex]

In the second part of the motion, the distance travelled is

[tex]d_2 = v t_2 - \frac{1}{2}a_2 t_2^2[/tex]

Substituting [tex]t_2=\frac{v}{a_2}[/tex] (2), we find

[tex]d_1 = \frac{v^2}{a_2} - \frac{1}{2} \frac{v^2}{a_2} = \frac{v^2}{2a_2}[/tex]

So the total distance travelled is

[tex]d= d_1 +d_2 = \frac{v^2}{2a_1}+\frac{v^2}{2a_2}[/tex]

The total time elapsed from start to stop for the electric vehicle is the sum of the time taken to accelerate and decelerate, calculated as T = v / a1 + v / a2. The total distance moved is the sum of the distances during acceleration and deceleration given by S = 0.5 * a1 * (v / a1)^2 + 0.5 * a2 * (v / a2)^2.

The question inquires about the time elapsed and the distance traveled by an electric vehicle which accelerates from rest until it reaches a certain velocity, and then decelerates to a stop. To answer part (a), we need to calculate the time taken for both acceleration and deceleration phases. For acceleration, we use the formula t1 = v / a1, and for deceleration t2 = v / a2. The total time elapsed T is then the sum of t1 and t2.

For part (b), the total distance covered S is the sum of the distances covered during acceleration and deceleration. The distance covered during acceleration s1 can be found using the equation s1 = 0.5 * a1 * t1^2, and the distance covered during deceleration s2 can be found with s2 = 0.5 * a2 * t2^2.

Hence, for an electric vehicle that accelerates to a speed v at a rate a1 and then decelerates at a rate a2 to a stop:

Explanation:

For pendulum 1 :

Mass, m₁ = 0.1 kg

Length, l₁ = 5 m

For pendulum 2 :

Mass, m₂ = 0.9 kg

Length, l₂ = 1 m

The time period the simple pendulum is given by :

[tex]T=2\pi\sqrt{\dfrac{L}{g}}[/tex]..........(1)

And we know that frequency f is given as :

[tex]f=\dfrac{1}{T}[/tex]

[tex]f=\dfrac{1}{2\pi\sqrt{\dfrac{L}{g}}}[/tex]

From equation (1) it is clear that the time period and frequency depend on the length of the bob and acceleration due to gravity only. It is independent of its mass.

Answer:

Focal length, f = 0.43 meters

Explanation:

It is given that,

Power of the reading glasses, P = 2.3 D

We need to calculate the focal length of the reading glasses. The relationship between the power and the focal length inverse i.e.

[tex]P=\dfrac{1}{f}[/tex]

[tex]f=\dfrac{1}{P}[/tex]

[tex]f=\dfrac{1}{2.3\ D}[/tex]

f = 0.43 m

So, the focal length of the reading glasses found on the rack in a drugstore is 0.43 meters.

The focal length of 2.30 diopters reading glasses is approximately 0.435 meters or 43.5 centimeters.

The focal length of reading glasses, which is the distance over which they focus light, is inversely related to their power in diopters. In this case, the reading glasses have a power of 2.30 diopters (D). To calculate the focal length (f) in meters, use the formula f = 1/P, where P is the power in diopters. Therefore, for glasses with a power of 2.30 D, the focal length would be f = 1/2.30, which equals approximately 0.435m (or 43.5 cm).

Answer:

Let's begin by explaining that a primary color is one that can not be obtained by mixing any other color.

In this sense, red, green and blue are the primary colors of light (using the additive theory of color), but not the primary colors of the pigments.

For the case of pigments (using the subtractive color theory) the primary colors are cyan, magenta and yellow. This is because the pigments generally absorb more light than they reflect (they absorb certain wavelengths and reflect others). Therefore, the color that a given object seems to have depends on which parts of the visible electromagnetic spectrum are reflected and which parts are absorbed.

Hence, according to the subtractive theory, if we join the three primary colors of the pigments, we will obtain the black. Unlike the additive theory of light, in which if we join the three primary colors we will get white light.

Answer:

Both objects travel the same distance.

(c) is correct option

Explanation:

Given that,

Mass of first object = 4.0 kg

Speed of first object = 2.0 m/s

Mass of second object = 1.0 kg

Speed of second object = 4.0 m/s

We need to calculate the stopping distance

For first particle

Using equation of motion

[tex]v^2=u^2+2as[/tex]

Where, v = final velocity

u = initial velocity

s = distance

Put the value in the equation

[tex]0= u^2-2as_{1}[/tex]

[tex]s_{1}=\dfrac{u^2}{2a}[/tex]....(I)

Using newton law

[tex]a=\dfrac{F}{m}[/tex]

Now, put the value of a in equation (I)

[tex]s_{1}=\dfrac{8}{F}[/tex]

Now, For second object

Using equation of motion

[tex]v^2=u^2+2as[/tex]

Put the value in the equation

[tex]0= u^2-2as_{2}[/tex]

[tex]s_{2}=\dfrac{u^2}{2a}[/tex]....(I)

Using newton law

[tex]F = ma[/tex]

[tex]a=\dfrac{F}{m}[/tex]

Now, put the value of a in equation (I)

[tex]s_{2}=\dfrac{8}{F}[/tex]

Hence, Both objects travel the same distance.

The two objects traveled the same distance which is equal to [tex]\frac{8}{F}[/tex].

The given parameters;

The acceleration of each object is calculated as follows;

F = ma

[tex]a = \frac{F}{m} \\\\a_1 = \frac{F}{4} \\\\a_2 = \frac{F}{1} = F[/tex]

The distance traveled by each object is calculated as follows before coming to rest;

[tex]v^2 = u^2 - 2as\\\\when \ the \ objects \ come \ to \ rest , \ v = 0\\\\0 = u^2 - 2as\\\\2as = u^2\\\\s = \frac{u^2}{2a} \\\\s_1 = \frac{(2)^2}{2(F/4)} = \frac{(2)^2}{F/2} \\\\s_1 = \frac{2(2)^2}{F} \\\\s_1 = \frac{8}{F} \\\\s_2 = \frac{(4)^2}{2F} \\\\s_2 = \frac{8}{F}[/tex]

Thus, we can conclude that the both objects traveled the same distance.

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Answer:

Fringe width = 21 mm

Explanation:

Fringe width is given by the formula

[tex]\beta = \frac{\Lambda L}{d}[/tex]

here we know that

[tex]\Lambda = 564 nm[/tex]

L = 4.0 m

d = 0.108 mm

now from above formula we will have

[tex]\beta = \frac{(564 \times 10^{-9})(4.0 m)}{0.108\times 10^{-3}}[/tex]

[tex]\beta = 0.021 meter[/tex]

so fringe width on the wall will be 21 mm

Final answer:

In Young's double slit experiment with given parameters, the fringe separation between the fourth order and central fringe is calculated to be 83.6 mm.

Explanation:

The question involves calculating the fringe separation in Young's double slit experiment using a green laser with a wavelength of 564 nm, a slit separation of 0.108 mm, and a distance to the screen of 4.0 m. To find the separation between the fourth order and the central fringe, we use the formula for fringe separation in a double slit experiment, which is Δy = λL/d, where Δy is the fringe separation, λ is the wavelength of the light, L is the distance from the slits to the screen, and d is the separation between the slits. Plugging in the values, we get Δy = (564 × 10^-9 m)(4 m) / (0.108 × 10^-3 m) = 0.0209 m or 20.9 mm for the separation between each fringe. However, since we need the separation between the fourth order and the central fringe, we simply multiply by the order number, giving us 4 × 20.9 mm = 83.6 mm.

Answer:

The maximum speed of a particle of the string is 0.34 m/s

Explanation:

The equation for the vertical displacement y of the string is given by y :

[tex]y=1.8\times 10^{-3}cos[\pi(13x-60t)][/tex].............(1)

The general equation of transverse wave is given by :

[tex]y=A(kx-\omega t)[/tex].............(2)

On comparing equation (1) and (2) we get,

[tex]\omega=60\pi[/tex]

Speed of a particle of the string is maximum when displacement is equal to zero. Maximum speed is given by :

[tex]v_{max}=A\omega[/tex]

Where, A = amplitude of wave

[tex]\omega=60\pi[/tex]

So, [tex]v_{max}=1.8\times 10^{-3}\times 60\pi[/tex]

[tex]v_{max}=0.34\ m/s[/tex]

Hence, this is the required solution.

The maximum speed of any particle on the string can be determined by the product of the amplitude and the angular frequency of the wave. In this case, the maximum speed is found to be 0.108 m/s.

The equation given represents the vertical displacement of a transverse wave on a string. We're trying to find the maximum speed of a particle of the string. This refers to the highest speed at which any string particle will be moving as the wave passes by.

From the given wave equation, the particle on the string will be moving in a simple harmonic motion. The maximum speed would be at the equilibrium position with a value equal to the product of the amplitude (A) and the angular frequency (ω).

In your case, the given equation is: y = (1.8x10-3)cos[π(13x - 60t)]. In this equation, the angular frequency (ω) is equal to 60 and the amplitude (A) is equal to 1.8 x 10-3.

Therefore, the maximum speed (vmax) of any particle on the string would be given by: vmax = Aω = (1.8 x 10-3) * 60 = 0.108 m/s

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