A bicyclist notes that the pedal sprocket has a radius of rp = 9.5 cm while the wheel sprocket has a radius of rw = 6.5 cm. The two sprockets are connected by a chain which rotates without slipping. The bicycle wheel has a radius R = 65 cm. When pedaling the cyclist notes that the pedal rotates at one revolution every t = 1.1 s. When pedaling, the wheel sprocket and the wheel move at the same angular speed.

Answer:

In an elastic collision, the momentum is conserved and the mechanical energy is conserved too.

Explanation:

There are two types of collisions:

- Elastic collision: in an elastic collision, the total momentum before and after the collision is conserved; also, the total mechanical energy before and after the collision is conserved.

- Inelastic collision: in an inelastic collision, the total momentum before and after the colllision is conserved, while the total mechanical energy is not conserved (in fact, part of the energy is converted into other forms of energy such that thermal energy, due to the presence of frictional forces)

Providing a technical understanding of the results from the aspects of physics. Through the use of relevant formulae and principles, it's been deduced under the right conditions and assuming no externalities, the rock could reach the top and the change in speed for the upward and downwards thrown rocks would theoretically be the same.

The subject of the question is related to the concepts of kinematics and energy in Physics.

(a) To determine if the rock can reach the top of the castle wall, we need to calculate the maximum possible height. By taking into account the initial speed and height of the rock, we can find out the greatest height it can reach. Using the formula for time-independent vertical motion: Δy = v₀t + 0.5gt² , where Δy is the maximum height, v₀ is the initial velocity (8.60m/s), 'g' is the acceleration due to gravity (≈9.80m/s²), and 't' is time.

(b) In order to calculate the speed of the rock at the top of the wall, we first need to determine if the rock reaches the top using the formula above. If the rock reaches the top, we can use energy considerations (similar to the 15.0 m/s rock thrown from the 20.0 m bridge) to determine the speed.

(c) When calculating the change in speed for a rock thrown straight down from the top of the wall, when the initial speed is 8.60 m/s, we can use similar calculations with respective sign conventions and constraints.

(d) The change in speed for both the upward and the downward-moving rock would theoretically be the same, assuming no other external forces (like air resistance or wind). This is primarily because the law of conservation of energy states that energy cannot be created or destroyed – only transformed.

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Answer:

B) 4/5

Explanation:

The magnitude of the electric force between the two spheres is given by

[tex]F=k\frac{q_1 q_2}{r^2}[/tex]

where

k is the Coulombs' constant

q1 and q2 are the charges on the two spheres

r is the distance between the two spheres

Initially, we have

[tex]q_1 = 5.0\mu C=5.0\cdot 10^{-6}C\\q_2 = 1.0 \mu C=1.0 \cdot 10^{-6}C\\r = L[/tex]

So the force is

[tex]F_1=k\frac{(5.0\cdot 10^{-6}C)(1.0\cdot 10^{-6}C)}{L^2}=(5.0 \cdot 10^{-12} C^2)\frac{k}{L^2}[/tex]

Later, the two spheres are brought together so they are in contact: this means that the total charge will redistribute equally on the two spheres (because they are identical).

The total charge is

[tex]Q=q_1 + q_2 = +4.0 \mu C=4.0\cdot 10^{-6}C[/tex]

So each sphere will have a charge of

[tex]q=\frac{Q}{2}=2.0\cdot 10^{-6} C[/tex]

So, the new force will be

[tex]F_2=k\frac{(2.0\cdot 10^{-6}C)(120\cdot 10^{-6}C)}{L^2}=(4.0 \cdot 10^{-12} C^2)\frac{k}{L^2}[/tex]

And so the ratio of the two forces is

[tex]\frac{F_2}{F_1}=\frac{4.0\cdot 10^{-12} C}{5.0\cdot 10^{-12} C}=\frac{4}{5}[/tex]

After two identical conducting spheres carrying different charges come into contact and separate, their total charge is distributed evenly. Using Coulomb's Law, the ratio of the forces after and before contact is 4/5. The answer is B) 4/5.

When two identical conducting spheres come into contact, their total charge is redistributed evenly between them. In this case, we have one sphere with a charge of +5.0 μC and another with –1.0 μC, totaling +4.0 μC for both spheres. After contact and redistribution, each sphere will have half of the total charge, which is +2.0 μC per sphere.

To find the ratio of the magnitudes of the electric forces before and after contact, we use Coulomb's Law, which states that the electric force between two charges is proportional to the product of the charges and inversely proportional to the square of the distance between their centers:F = k * |q1 * q2| / L2

Where F is the force, k is Coulomb's constant, q1 and q2 are the charges, and L is the separation distance. Before contact, the force is: Fbefore = k * |(+5.0 μC) * (–1.0 μC)| / L2 = k * 5.0 μC / L2

After contact, the force is: Fafter = k * |(+2.0 μC) * (+2.0 μC)| / L2 = k * 4.0 μC / L2

The ratio of Fafter to Fbefore is therefore (4.0/5.0 μC), which simplifies to 4/5. The answer to the question is option B) 4/5.

1. [tex]70.5\cdot 10^{-6} F[/tex]

The relationship between capacitance, charge and voltage across a capacitor is:

[tex]Q=CV[/tex]

where

Q is the charge

C is the capacitance

V is the voltage

In this problem,

[tex]C=47\mu F=47\cdot 10^{-6}F[/tex] is the capacitance

V = 1.5 V

Substituting, we find the charge on the capacitor, that is eventually transferred to the plant:

[tex]Q=(47\cdot 10^{-6}F)(1.5 V)=70.5\cdot 10^{-6} F[/tex]

2. 428.6 V/m

The electric field between the electrodes is given by

[tex]E=\frac{V}{d}[/tex]

where

V = 1.5 V is the potential difference across the electrodes

d = 3.5 mm = 0.0035 m is the distance between the electrodes

Substituting into the equation, we find

[tex]E=\frac{1.5 V}{0.0035 m}=428.6 V/m[/tex]

The charge transferred to the plant is 70.5 μC, and the electric field between the electrodes is approximately 428.57 V/m.

To determine how much charge was transferred to the plant, we can use the formula for the charge stored in a capacitor: q = C * V, where C is the capacitance and V is the voltage.

Given a capacitance C of 47 μF (which is 47 x 10⁻⁶ F) and a voltage V of 1.5 V:

q = 47 * 10⁻⁶ * 1.5

Thus, the charge q is:

q = 70.5  * 10⁻⁶ C or 70.5 μC

To find the electric field between the electrodes, use the formula: E = V / d, where V is the voltage and d is the distance between the electrodes.

Given V is 1.5 V and d is 3.5 mm (which is 3.5 x 10⁻³ m):

E = 1.5 / 3.5 * 10⁻³

Thus, the electric field E is: E = 428.57 V/m

(a) 3.5 Hz

The angular frequency in a spring-mass system is given by

[tex]\omega=\sqrt{\frac{k}{m}}[/tex]

where

k is the spring constant

m is the mass

Here in this problem we have

k = 160 N/m

m = 0.340 kg

So the angular frequency is

[tex]\omega=\sqrt{\frac{160 N/m}{0.340 kg}}=21.7 rad/s[/tex]

And the frequency of the motion instead is given by:

[tex]f=\frac{\omega}{2\pi}=\frac{21.7 rad/s}{2\pi}=3.5 Hz[/tex]

(b) 0.021 m

The block is oscillating up and down together with the upper end of the spring. The block will lose contact with the spring when the direction of motion of the spring changes: this occurs when the spring is at maximum displacement, so at

x = A

where A is the amplitude of the motion.

The maximum displacement is given by Hook's law:

[tex]F=kA[/tex]

where

F is the force applied initially to the spring, so it is equal to the weight of the block:

[tex]F=mg=(0.340 kg)(9.81 m/s^2)=3.34 N[/tex]

k = 160 N/m is the spring constant

Solving for A, we find

[tex]A=\frac{F}{k}=\frac{3.34 N}{160 N/m}=0.021 m[/tex]

a. The frequency (in Hz) of the motion is equal to 3.45 Hertz.

b. The amplitude at which the block will lose contact with the spring is 0.021 meters.

Given the following data:

a. To find the frequency (in Hz) of the motion:

Since the spring initiates simple harmonic motion, we would determine its angular frequency.

Mathematically, angular frequency of a spring is given by the formula:

[tex]\omega = \sqrt{\frac{k}{m} }[/tex]

Where:

Substituting the given parameters into the formula, we have;

[tex]\omega = \sqrt{\frac{160}{0.340} }\\\\\omega = \sqrt{470.59}\\\\\omega = 21.69 \;rad/s[/tex]

Now, we can find the frequency of the motion by using the formula:

[tex]F = \frac{\omega}{2\pi} \\\\F = \frac{21.69}{2 \times 3.142} \\\\F = \frac{21.69}{6.284}[/tex]

Frequency, F = 3.45 Hz

b. To determine the amplitude at which the block will lose contact with the spring:

[tex]Force = kA\\\\mg = kA\\\\A = \frac{mg}{k}[/tex]

Where:

Substituting the parameters into the formula, we have;

[tex]A = \frac{0.340 \times 9.8}{160} \\\\A = \frac{3.332}{160}[/tex]

Amplitude, A = 0.021 meters

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Answer:

33 m/s

Explanation:

By analyzing the vertical motion, we can find what is the time of flight of the projectile. The vertical position is

[tex]y(t) = h + v_{0y}t - \frac{1}{2}gt^2[/tex]

where

h = 20 m is the initial height

[tex]v_{0y} = 26 m/s[/tex] is the initial vertical velocity

[tex]g=9.8 m/s^2[/tex] is the acceleration due to gravity

By putting y(t)=0, we find the time t at which the projectile hits the ground:

[tex]0=20 + 26 t - 4.9t^2[/tex]

which has 2 solutions:

t = -0.7 s

t = 6.0 s

We discard the negative solution since it has no physical meaning. So, we know that the projectile hits the ground 6.0 s later after the launch.

The vertical velocity is given by

[tex]v_y (t)= v_{0y} -gt[/tex]

So we can find the vertical velocity when the projectile reaches point Q, by substituting t=6.0 s into this equation:

[tex]v_y = 26 m/s - (9.8 m/s^2)(6.0 s)=-32.8 m/s \sim -33 m/s[/tex]

and the negative sign means the direction is downward.

Answer:

2130 m³, 3.11 °C, 1.25×10⁷ J

Explanation:

No heat is exchanged, so this is an adiabatic process.  For an ideal gas, this means:

PV^((f+2)/f) = constant,

where P is pressure, V is volume, and f is degrees of freedom.

For a monatomic gas, f=3.  For a diatomic gas, f=5.  Since helium is monatomic, f=3.

Therefore:

PV^(5/3) = PV^(5/3)

(1.00 atm) (2.00×10³ m³)^(5/3) = (0.900 atm) V^(5/3)

V = 2130 m³

For an ideal gas in an adiabatic process, we can also say:

VT^(f/2) = constant

Therefore:

(2.00×10³ m³) (15.0 + 273.15 K)^(3/2) = (2130 m³) T^(3/2)

T = 276.26 K

T = 3.11 °C

Finally, the change in internal energy is:

ΔU = (f/2) nRΔT

We need to find the number of moles, n, using ideal gas law:

PV = nRT

n = PV/(RT)

n = (1.00 atm) (2.00×10³ m³) / ((8.21×10⁻⁵ atm m³ / mol / K) (15.0 + 273.15 K))

n = 84,500 mol

So the change in internal energy is:

ΔU = (3/2) (84,500 mol) (8.314 J/mol/K) (15.0 - 3.11) K

ΔU = 1.25×10⁷ J

Answer:

(a) There will be no water in the bucket by the time the bucket reaches the top of the well.

(b) The work done in this process will be approximately 1.98 × 10³ J.

Explanation:

How long will it take for the bucket to reach the top of the well?

[tex]\displaystyle t = \frac{s}{v} = \rm \frac{40.8}{0.8} = 51.0\;s[/tex].

How much water will leak out during that [tex]51.0[/tex] seconds?

[tex]\rm 51.0\;s \times 0.12\;kg\cdot s^{-1} = 6.12\;kg > 6\;kg[/tex].

That's more than all the water in the bucket. In other words, all [tex]\rm 6\;kg[/tex] of water in the bucket will have leaked out by the time the bucket reaches the top of the well. There will be no water in the bucket by the time the bucket reaches the top of the well.

How long will it take for all water to leak out of the bucket?

[tex]\displaystyle \rm \frac{6\; kg}{0.12\;kg \cdot s^{-1}} = 50\;s[/tex].

In other words,

Express the mass [tex]m[/tex] of the bucket about time [tex]t[/tex] as a piecewise function:

[tex]\displaystyle m(t) = \left\{\begin{aligned} &6 - 0.12\;t,&&\;0\le t < 50\\& 2,&&\; 50\le t <51\end{aligned}[/tex].

Gravity on the bucket:

[tex]W(t) = m(t)\cdot g[/tex].

However, the bucket is moving at a constant velocity. There's no acceleration. By Newton's Second Law, the net force will be zero. Forces on the bucket are balanced. As a result, the size of the upward force shall be equal to that of gravity.

[tex]\displaystyle F(t) = W(t) = m(t)\cdot g[/tex].

The speed of the bucket [tex]v[/tex] is constant. Thus the power [tex]P[/tex] that pulls the bucket upward at time [tex]t[/tex] will be:

[tex]P(t) = F(t)\cdot v = m(t)\cdot v\cdot g[/tex].

Express work as a definite integral of power with respect to time:

[tex]\displaystyle \begin{aligned}W &= \int_{t_0}^{t_1}{P(t)\cdot dt} = \int_{t_0}^{t_1}{m(t)\cdot g \cdot v\cdot dt}\end{aligned}[/tex].

Both [tex]g[/tex] and [tex]v[/tex] here are constants. Factor them out:

[tex]\displaystyle \begin{aligned}W &= \int_{t_0}^{t_1}{m(t)\cdot g \cdot v\cdot dt} = v\cdot g\cdot \int_{t_0}^{t_1}{m(t)\cdot dt} \end{aligned}[/tex].

Integrate the piecewise function [tex]m(t)[/tex] piece-by-piece:

[tex]\displaystyle \begin{aligned}W &= v\cdot g\cdot \int_{t_0}^{t_1}{m(t)\cdot dt}\\ &=0.8\times 9.8 \left [\int_{0}^{50}(8-0.12\;t)\cdot dt + \int_{50}^{51}2\cdot dt\right]\\ &=0.8\times 9.8 \left [\left(8\;t - \frac{0.12}{2}\;t^{2}\right)\bigg|^{50}_{0} + (2\;t)\bigg|^{51}_{50}\right] \\&=0.8\times 9.8 \left [\left(8\times 50-\frac{0.12}{2}\times 50^{2}\right)+ (51\times 2 - 50\times 2)\right]\\&=\rm 1975.68\;J \end{aligned}[/tex].

Hence the work done pulling the bucket to the top of the well is approximately [tex]\rm 1.98\times 10^{3}\;J[/tex].

Answer:

Q: remains the same

C: decreases

ΔV: increases

Explanation:

When the capacitor is disconnected from the battery, and the wire connected to the plates are not touching anything else, it means that the charge cannot flow out from the capacitor: so, the charge stored on the plates of the capacitor, Q, will not change, regardless of the distance between the plates.

The capacitance of a parallel plate is given by

[tex]C=\frac{\epsilon_0 A}{d}[/tex]

where A is the area of the plates and d the separation between the plates. As we see from the formula, C is inversely proportional to d: so, if the plates are pulled apart to a larger separation, it means that d increases, and so C decreases.

Finally, the voltage across the capacitor is given by

[tex]\Delta V=\frac{Q}{C}[/tex]

and since we said that Q does not change while C decreases, it means that [tex]\Delta V[/tex] increases, since [tex]\Delta V[/tex] is inversely proportional to C.

I believe it should be

Answer:

110 m

Explanation:

First of all, let's find the initial horizontal and vertical velocity of the projectile:

[tex]v_{x0}=v cos 30^{\circ}=(25 m/s)(cos 30^{\circ})=21.7 m/s[/tex]

[tex]v_{y0}=v sin 30^{\circ}=(25 m/s)(sin 30^{\circ})=12.5 m/s[/tex]

Now in order to find the time it takes for the projectile to reach the ground, we use the equation for the vertical position:

[tex]y(t)=h+v_{0y}t-\frac{1}{2}gt^2[/tex]

where

h = 65 m is the initial height

t is the time

g = 9.8 m/s^2 is the acceleration due to gravity

The time t at which the projectile reaches the ground is the time t at which y(t)=0, so we have:

[tex]0=65+12.5 t - 4.9t^2[/tex]

which has 2 solutions:

t = -2.58 s

t = 5.13 s

We discard the 1st solution since its negative: so the projectile reaches the ground after t=5.13 s.

Now we know that the projectile travels horizontally with constant speed

[tex]v_x = 21.7 m/s[/tex]

So, the horizontal distance covered (x) is

[tex]x=v_x t = (21.7 m/s)(5.13 s)=111.3 m[/tex]

So the closest option is

110 m

Answer:

9.60 m/s

Explanation:

The escape speed of an object from the surface of a planet/asteroid is given by:

[tex]v=\sqrt{\frac{2GM}{R}}[/tex]

where

G is the gravitational constant

M is the mass of the planet/asteroid

R is the radius of the planet/asteroid

In this problem we have

[tex]\rho = 2.02\cdot 10^6 g/m^3[/tex] is the density of the asteroid

[tex]V=3.09\cdot 10^{12}m^3[/tex] is the volume

So the mass of the asteroid is

[tex]M=\rho V=(2.02\cdot 10^6 g/m^3)(3.09\cdot 10^{12} m^3)=6.24\cdot 10^{18} g=6.24\cdot 10^{15} kg[/tex]

The asteroid is approximately spherical, so its volume can be written as

[tex]V=\frac{4}{3}\pi R^3[/tex]

where R is the radius. Solving for R,

[tex]R=\sqrt[3]{\frac{3V}{4\pi}}=\sqrt[3]{\frac{3(3.09\cdot 10^{12} m^3)}{4\pi}}=9036 m[/tex]

Substituting M and R inside the formula of the escape speed, we find:

[tex]v=\sqrt{\frac{2(6.67\cdot 10^{-11})(6.24\cdot 10^{15})}{(9036)}}=9.60 m/s[/tex]

Explanation:

When a swimmer is underwater and a light pasess from air to water, there is a change in the medium and its index of refraction, hence the light is refracted. This means it changes its direction.

Nevertheless, in this process the refracted ray of light does not change its frequency [tex]f[/tex], because frequency is:

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

Where [tex]T[/tex] is the period of the wave and this remains unchanged, hence the frequency, as well.

So, as the frequency does not change and the color of light depends on frequency, the color of the light remains the same.

Answer:

322 m

Explanation:

y = y₀ + v₀ t + ½ gt²

If we take down to be positive, then:

y = 0 + (5.10) (7.60) + ½ (9.8) (7.60)²

y = 322 m

The skyscraper is 322 m tall.

Answer:

A) 0.50 mV

Explanation:

In this problem, we can think the wings of the bird as a metal rod moving across a magnetic field. So, and emf will be induced into the wings of the bird, according to the formula:

[tex]\epsilon = BvL sin \theta[/tex]

where

[tex]B=5\cdot 10^{-5} T[/tex] is the strength of the magnetic field

v = 13 m/s is the speed of the bird

L = 1.2 m is the wingspan of the bird

[tex]\theta=40^{\circ}[/tex] is the angle between the direction of motion and the direction of the magnetic field

Substituting numbers into the formula, we find

[tex]\epsilon = (5.0\cdot 10^{-5} T)(13 m/s)(1.2 m) sin 40^{\circ}=0.00050 V = 0.50 mV[/tex]

Answer:

3.61 m/s²

Explanation:

Given:

v = 12 m/s

x = 7 m

x₀ = 0 m

t = 6 s

Find:

a

x = x₀ + vt - ½ at²

7 m = 0 m + (12 m/s) (6 s) - ½ a (6 s)²

a = 3.61 m/s²

The first part involves calculating the angle for the first minimum in the diffraction pattern of a sound wave and we get approximately 1.05°. For the second part, we calculate that the width of a hypothetical doorway for yellow light would need to be around 30.9 micrometers to match this diffraction angle.

To answer the student’s question, we need to determine the angle for the first minimum in the diffraction pattern for sound waves passing through a doorway. The formula for the angle of the first minimum is given by:

sin(θ) = λ / a

where λ is the wavelength and 'a' is the width of the doorway.

Part (a)

Part (b)

When yellow light (wavelength = 569 nm or 569 × 10-9 m) passes through a hypothetical doorway, and the first dark fringe is at the same angle:

Thus, the width of the hypothetical doorway for yellow light would need to be approximately 30.9 micrometers.

Answer:

25

Explanation:

Half life equation is:

A = A₀ (½)^(t / T)

where A is the final amount, A₀ is the initial amount, t is time, and T is the half life.

Given that A₀ = 100, t = 5, and T = 2.5:

A = 100 (½)^(5 / 2.5)

A = 100 (½)^2

A = 100 (¼)

A = 25

There will be 25 atoms left.

There’s 25 atoms left

Final answer:

A star with twice the mass of the Sun would have a nuclear fusion rate that is significantly more than twice the rate of the Sun. This occurs because the fusion rate is highly sensitive to core temperature and density, which increases more than linearly with mass. Additionally, the lifetime of such a star is inversely proportional to the square of its mass, resulting in a much shorter lifespan.

Explanation:

A star with twice the mass of the Sun would have a rate of nuclear fusion that is more than twice the rate of fusion in the Sun. This is because the rate of nuclear fusion increases with both the mass and the core temperature of the star. Since a star's core temperature and its density increase with greater mass, the rate of nuclear fusion increases exponentially, not linearly. The relationship between the temperature and the nuclear reaction rate is to the power of four. Therefore, a star with twice the mass of the Sun would have a considerably higher core temperature, leading to a significantly increased reaction rate, well over twice that of the Sun's.

To put this into perspective using the proportional relationship of mass (M), luminosity (L), and lifetime (T) of a star; for a star with twice the mass of the Sun, we use the equation T = 10¹⁰ y where M is the mass relative to the Sun, and L is the luminosity relative to the Sun. Considering that the luminosity increases dramatically with mass, the rate of fuel consumption would be much higher. Hence, while a massive star has more fuel, its higher fusion rate due to increased core temperature leads to a much shorter lifetime than less massive stars like our Sun.

Furthermore, we understand that the lifetime of a star is inversely proportional to its mass squared, as demonstrated by the worked example where the lifetime of a star with twice the Sun's mass is a quarter of the Sun's lifetime.

The photoelectric effect is a phenomenon that consists of the emission of electrons by certain metals when a beam of light impacts on its surface.

For this phenomenon to occur, certain conditions must be met, such as when the photon collides with the electron, in order to "pull it" from the metal, the photon must have a minimum energy equal to the ionization energy of the atom, so that the electron can leave the influence of the nucleus.  

This is achieved with the adequate intensity of the incident radiation, which is related to the number of photons that impact the metal.

This means:

Increasing the intensity of monochromatic light incident on a metal surface causes an increase in the rate of electron ejection due to the larger number of photons arriving on the surface per unit time. However, the kinetic energy of the ejected electrons doesn't change with changing light intensity.

The phenomenon described here is called the photoelectric effect, which occurs when monochromatic light is incident on a metal surface causing the ejection of electrons, also known as photoelectrons.

When the intensity of the light increases, the rate of electron ejection also increases. This is because the increased intensity of light means a larger number of photons are arriving on the surface per unit time, thus more electrons can gain energy from the photons and be ejected.

The kinetic energy of the ejected electrons, however, does not change with changing light intensity. The energy of an ejected electron equals to the energy of a single photon (which depends only on the light's frequency, not its intensity) minus the binding energy of the electron. This means, even though there are more electrons ejected per unit time due to increased intensity, they have the same kinetic energy as before.

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Answer:

The atoms are isotopes of each other

Explanation:

- Two atoms are said to be isotopes of each other if they have same atomic number Z (which corresponds to the number of protons) but different mass number A (which corresponds to the sum of protons and neutrons in the nucleus).

For atom A, we have:

Z = 10 (10 protons)

A = 10+12 = 22 (10 protons + 12 neutrons)

For atom B, we have:

Z = 10 (10 protons)

A = 10+10 = 20 (10 protons + 10 neutrons)

The two atoms have same atomic number Z but different mass number A, so they are isotopes of each other.

Atom A and Atom B are isotopes of the same element because they have an equal number of protons (10 each), but differ in the number of neutrons (12 in Atom A and 10 in Atom B).

The atoms identified as A and B are isotopes of each other. Isotopes are variations of a chemical element, which means they have the same number of protons (and thus belong to the same element) but differ in the number of neutrons. In this case, both atoms A and B share the same number of protons (10) which identifies the element, but differ in the number of neutrons (12 in atom A and 10 in atom B).

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Answer:

[tex]0.496 kg m^2[/tex]

Explanation:

The torque exerted is given by

[tex]\tau = Fd[/tex]

where

[tex]F=2.00 \cdot 10^3 N[/tex] is the force applied

d = 3.10 cm = 0.031 m is the length of the lever arm

Substituting,

[tex]\tau=(2.00\cdot 10^3 N)(0.031 m)=62 Nm[/tex]

The equivalent of Newton's second law for rotational motion is:

[tex]\tau = I \alpha[/tex]

where

[tex]\tau = 62 Nm[/tex] is the net torque

I is the moment of inertia

[tex]\alpha = 125 rad/s^2[/tex] is the angular acceleration

Solving the equation for I, we find

[tex]I=\frac{\tau}{\alpha}=\frac{62 Nm}{125 rad/s^2}=0.496 kg m^2[/tex]

Answer:

0.169

Explanation:

There are three forces acting on the crate along the horizontal direction:

- The pushing force of the first worker, F1 = 450 N forward

- The pushing force of the second worker, F2 = 330 N forward

- The frictional force [tex]F_f[/tex] acting backward

The crate slides with constant speed, so its acceleration is zero: a = 0. This means that we can write Newton's second law as

[tex]\sum F = ma = 0\\F_1 + F_2 - F_f = 0[/tex]

The frictional force can be rewritten as

[tex]F_f = \mu mg[/tex]

where

[tex]\mu[/tex] is the coefficient of kinetic friction

m = 470 kg is the mass of the crate

g = 9.8 m/s^2 is the acceleration due to gravity

Substituting everything into the previous equation, we find:

[tex]F_1 + F_2 - \mu mg = 0\\\mu = \frac{F_1 + F_2}{mg}=\frac{450 N+330 N}{(470 kg)(9.8 m/s^2)}=0.169[/tex]

The coefficient of kinetic friction for the crate on this particular floor surface, given that the total force propelling the crate by the workers is balanced by the frictional force, is approximately 0.169.

In this problem, two workers are sliding a 470 kg crate across the floor. One pushes with a force of 450 N, and the other pulls with a force of 330 N, with both forces applied horizontally. Given that the crate slides at a constant speed, we can infer that the total force propelling the crate (450 N + 330 N) is balanced by the frictional force.

Since the crate moves at a constant pace, the force of friction equals the total force exerted by the workers, 780 N (450 N + 330 N). The frictional force is generally given as Ff = μkN, where μk is the coefficient of kinetic friction, and N is the normal force. For a crate on a horizontal surface, the normal force equals the weight of the crate, which is mass (m) times gravity (g), or 470 kg * 9.8 m/s², or approximately 4606 N.

So we can set up the equation as follows: 780 N = μk * 4606 N. Solving for μk gives us μk = 780 N / 4606 N = 0.169. Therefore, the coefficient of kinetic friction for the crate on this particular floor surface is approximately 0.169.

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Infrared radiation from young stars can pass through the heavy dust clouds surrounding them, allowing astronomers here on Earth to study the earliest stages of star formation, before a star begins to emit visible light, the wavelength is 2.325 x 10¹ um.

The wavelength can be calculated by the information given:

- Frequency f = 25.9 THz = [tex]\(25.9 \times 10^{12}\)[/tex] Hz

- Speed of light c = [tex]\(3.00 \times 10^8\)[/tex] m/s

We'll use the formula [tex]\(\lambda = \frac{c}{f}\)[/tex] to calculate the wavelength ([tex]\(\lambda\)[/tex]).

Substitute the values:

[tex]\[\lambda = \dfrac{3.00 \times 10^8 \, \text{m/s}}{25.9 \times 10^{12} \, \text{Hz}}.\][/tex]

Calculate the value of [tex]\(\lambda\)[/tex]:

[tex]\[\lambda = 1.157 \times 10^{-5} \, \text{m}.\][/tex]

Now, convert the wavelength to micrometers:

[tex]\[\lambda = 1.157 \times 10^{-5} \, \text{m} \times \dfrac{10^6 \, \mu m}{1 \, \text{m}}.\][/tex]

Calculate the value in micrometers:

[tex]\[\lambda \approx 2.325 \, \mu m.\][/tex]

Thus, the wavelength is 2.325 x 10¹ um or 2.325μm.

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The wavelength of the infrared radiation emitted from young stars with a frequency of 25.9 THz can be calculated using the formula relating the speed of light, wavelength, and frequency (c = λv). By rearranging the formula to λ = c/v and substituting the values, we find that the wavelength is approximately 11.6 micrometers.

To calculate the wavelength of the infrared radiation, we must use the formula for the relation between the speed of light, wavelength, and frequency. This formula is c = λv, where c is the speed of light, λ (lambda) is the wavelength, and v is the frequency.

The speed of light is a constant and is approximately 3.00 x 108 m/s. The frequency provided is 25.9 THz or 25.9 x 1012 Hz.

To find the wavelength, we rearrange the formula to λ = c/v. We substitute the given values to get λ = (3.00 x 108 m/s) / (25.9 x 1012 Hz). After performing the calculation, the wavelength comes out to approximately 1.16 x 10-5 meters, or 11.6 micrometers when rounded to three significant figures.

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If the line on the graph is horizontal, the car is at the same position no matter what time you look at it.  That means that the car is sitting motionless in one place, and not moving.  The car's speed, velocity, and acceleration are all zero, although its resale value may be decreasing.

Answer:

E - B - D - A - C

Explanation:

The magnitude of the emf induced in the loop of wire is given by Faraday-Newmann-Lenz

[tex]\epsilon=\frac{\Delta \Phi_B}{\Delta t}[/tex] (1)

where

[tex]\Delta \Phi_B[/tex] is the variation of magnetic flux

[tex]\Delta t[/tex] is the time interval

Rewriting the flux as product between magnetic field strength (B) and area enclosed by the coil (A):

[tex]\Phi_B = BA[/tex]

and since the area of the coil does not change, the variation of flux can be rewritten as

[tex]\Delta \Phi_B = \Delta B A[/tex]

So (1) becomes

[tex]\epsilon=\frac{\Delta B}{\Delta t}A[/tex]

Which means that the induced emf is proportional to the rate of change of the magnetic field, [tex]\frac{\Delta B}{\Delta t}[/tex]. So we just need to calculate this quantity for each scenario, and rank them from greatest to latest.

We have:

A) [tex]\frac{\Delta B}{\Delta t}=\frac{1 T - 0T}{6 s}=0.167 T/s[/tex]

B) [tex]\frac{\Delta B}{\Delta t}=\frac{4 T - 1T}{2 s}=1.500 T/s[/tex]

C) [tex]\frac{\Delta B}{\Delta t}=\frac{4 T - 4T}{60 s}=0 T/s[/tex]

D) [tex]\frac{\Delta B}{\Delta t}=\frac{3 T - 4T}{4 s}=-0.250 T/s[/tex]

E) [tex]\frac{\Delta B}{\Delta t}=\frac{0 T - 3T}{1 s}=-3.000 T/s[/tex]

So, from greatest to least magnitude, we have:

E - B - D - A - C

The plane of a loop of wire is perpendicular to a magnetic field. Rank, from greatest to least, the magnitudes of the loop's induced emf for each situation will be E - B - D - A-C.

The number of magnetic flux lines on a unit area passing perpendicular to the given line direction is known as induced magnetic field strength .it is denoted by B.

The magnitude of the  induced emf in the loop of wire is;

[tex]\rm \epsilon = \frac{\triangle \phi }{ \triangle t} \\\\[/tex]

The megnetic flux is given by;

[tex]\phi_B= \triangle BA[/tex]

[tex]\rm \epsilon = \frac{ \triangle BA }{ \triangle t} \\\\[/tex]

The above expression shows that the induced emf is proportional to the rate of change of the magnetic field,

[tex]\rm \frac{ \triangle B }{ \triangle t} = \frac{ 1T-0T }{ 6} =0.167\ T/sec[/tex]

[tex]\rm \frac{ \triangle B }{ \triangle t} = \frac{ 4T-1T }{ 2} =1.500\ T/sec[/tex]

[tex]\rm \frac{ \triangle B }{ \triangle t} = \frac{ 4T-4T }{ 60} =0\ T/sec[/tex]

[tex]\rm \frac{ \triangle B }{ \triangle t} = \frac{ 3T-4T }{ 4} =-0.25 \ T/sec[/tex]

[tex]\rm \frac{ \triangle B }{ \triangle t} = \frac{ 0T-3T }{ 1} =-3 \ T/sec[/tex]

From the above, it is observed that Rank, from greatest to least, the magnitudes of the loop's induced emf for each situation will be E - B - D - A-C.

Hence the order will be E - B - D - A-C.

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(a) [tex]2.68\cdot 10^{-6} W/m^2[/tex]

The intensity of an electromagnetic wave is given by

[tex]I=\frac{P}{A}[/tex]

where

P is the power

A is the area of the surface considered

For the waves in the problem,

[tex]P=182 kW = 1.82\cdot 10^5 W[/tex] is the power

The area is a hemisphere of radius

[tex]r=104 km=1.04\cdot 10^5 m[/tex]

so

[tex]A=2\pi r^2=2\pi (1.04\cdot 10^5 m)^2=6.8\cdot 10^{10} m^2[/tex]

So, the intensity is

[tex]I=\frac{1.82\cdot 10^5 W}{6.8\cdot 10^{10}m^2}=2.68\cdot 10^{-6} W/m^2[/tex]

(b) [tex]5.9\cdot 10^{-7} W[/tex]

In this case, the area of the reflection is

[tex]A=0.22 m^2[/tex]

So, if we use the intensity of the wave that we found previously, we can calculate the power of the aircraft's reflection using the same formula:

[tex]P=IA=(2.68\cdot 10^{-6} W/m^2)(0.22 m^2)=5.9\cdot 10^{-7} W[/tex]

(c) [tex]8.7\cdot 10^{-18} W/m^2[/tex]

We said that the power of the waves reflected by the aircraft is

[tex]P=5.9\cdot 10^{-7} W[/tex]

If we assume that the reflected waves also propagate over a hemisphere of radius

[tex]r=104 km=1.04\cdot 10^5 m[/tex]

which has an area of

[tex]A=2\pi r^2=2\pi (1.04\cdot 10^5 m)^2=6.8\cdot 10^{10} m^2[/tex]

Then the intensity of the reflected waves at the radar site will be

[tex]I=\frac{P}{A}=\frac{5.9\cdot 10^{-7} W}{6.8\cdot 10^{10} m^2}=8.7\cdot 10^{-18} W/m^2[/tex]

(d) [tex]8.1\cdot 10^{-8} V/m[/tex]

The intensity of a wave is related to the maximum value of the electric field by

[tex]I=\frac{1}{2}c\epsilon_0 E_0^2[/tex]

where

c is the speed of light

[tex]\epsilon_0[/tex] is the vacuum permittivity

[tex]E_0[/tex] is the maximum value of the electric field vector

Solving the equation for [tex]E_0[/tex],

[tex]E_0=\sqrt{\frac{2I}{c\epsilon_0}}=\sqrt{\frac{2(8.7\cdot 10^{-18} W/m^2)}{(3\cdot 10^8 m/s)(8.85\cdot 10^{-12} F/m)}}=8.1\cdot 10^{-8} V/m[/tex]

(e) [tex]1.9\cdot 10^{-16} T[/tex]

The maximum value of the magnetic field vector is given by

[tex]B_0 = \frac{E_0}{c}[/tex]

Substituting the values,

[tex]B_0 = \frac{(8.1\cdot 10^{-8} V/m)}{3\cdot 10^8 m/s}=2.7\cdot 10^{-16} T[/tex]

And the rms value of the magnetic field is given by

[tex]B_{rms} = \frac{B_0}{\sqrt{2}}=\frac{2.7\cdot 10^{-16} T}{\sqrt{2}}=1.9\cdot 10^{-16} T[/tex]

The vacuum experiences a voltage drop of 114.28 V after accounting for the 5.72 V drop due to the resistance of the extension cord.

To calculate the voltage drop across the vacuum, we can use Ohm's law, which states that Voltage (V) = Current (I) times Resistance (R). Given that the total resistance of the wires in the extension cord is 0.44Ω and the current is limited to 13 A, we first find the voltage drop across the extension cord itself:

V = I times R = 13 A times 0.44 Ω = 5.72 V.

Since the outlet provides 120 V and the voltage drop across the cord is 5.72 V, the voltage drop across the vacuum is:

120 V - 5.72 V = 114.28 V.

This voltage drop across the vacuum is how much voltage is available for the vacuum to operate with.

It is important to note that the higher the resistance of the cord or the greater the current, the larger the voltage drop will be, leading to a decrease in the appliance's performance.

The answer would be a seizure because the child showed signs of seizure such as shaking drooling and urinating on himself

Final answer:

Rosa's son likely experienced a seizure, as indicated by his muscle tension, involuntary movements, and postictal fatigue. These symptoms align with common seizure characteristics rather than a stroke, anxiety, or a metallic taste.

Explanation:

Based on the symptoms described by Rosa of her son, it is most likely that her son experienced a seizure. The sudden onset of muscle tenseness, involuntary movements, drooling, grunting, convulsions, and subsequent loss of bladder control, followed by extreme fatigue, are all characteristic signs of a seizure. A seizure is a burst of uncontrolled electrical activity between brain cells that causes temporary abnormalities in muscle tone or movements, sensations, behavior, or consciousness.

These symptoms do not align with those of a stroke, which are typically more localized to one side of the body and can include speech difficulties, facial drooping, and weakness, nor do they match the symptoms of feeling anxious or experiencing a metallic taste, which are not typically associated with loss of consciousness or convulsive behavior.

Answer:

434 Hz

Explanation:

According to the Doppler effect, when a source of a wave is moving towards an observer at rest, then the observer will observe an apparent frequency which is higher than the original frequency of the source.

In this situation, Tina is driving towards Rita. Tina is the source of the sound wave (the horn), while RIta is the observer. Since the original frequency of the sound is 400 Hz, Rita will hear a sound with a frequency higher than this value.

The only choice which is higher than 400 Hz is 434 Hz, so this is the frequency that Rita will hear.

Answer:b

Explanation:test