A particle with a charge of 34.6 $\mu C$ moves with a speed of 68.4 m/s in the positive $x$ direction. The magnetic field in this region of space has a component of 0.466 T in the positive $y$ direction, and a component of 0.876 T in the positive $z$ direction. What is the magnitude of the magnetic force on the particle?

The x component of the change in momentum of cart A is -0.20 kg·m/s, while for cart B, it is +0.20 kg·m/s. The sum of these changes in momentum is 0 kg·m/s, showing conservation of momentum in the system.

The student has provided information about a collision between two carts, which involves concepts of momentum and conservation of momentum from mechanics in physics.

Part A: Change in Momentum of Cart A

The x component of the change in momentum of cart A can be calculated using the formula Δp = m(v_final - v_initial), where m is mass and v is velocity. Here, Δp = 1.0 kg (0.50 m/s - 0.70 m/s) = -0.20 kg·m/s. The negative sign indicates that the momentum decreased.

Part B: Change in Momentum of Cart B

Similarly, for cart B, Δp = 0.10 kg (1.6 m/s - (-0.40 m/s)) = 0.20 kg·m/s. The positive sign signifies an increase in momentum.

Part C: Sum of Changes in Momentum

The total change in momentum for both carts is the sum of their individual momentum changes, which is -0.20 kg·m/s + 0.20 kg·m/s = 0 kg·m/s. This means that the total momentum of the system is conserved.

Answer:

b. 0.25cm

Explanation:

You can solve this question by using the formula for the position of the fringes:

[tex]y=\frac{m\lambda D}{d}[/tex]

m: order of the fringes

lambda: wavelength 500nm

D: distance to the screen 5 m

d: separation of the slits 1mm=1*10^{-3}m

With the formula you can calculate the separation of two adjacent slits:

[tex]\Delta y=\frac{(m+1)(\lambda D)}{d}-\frac{m\lambda D }{d}=\frac{\lambda D}{d}\\\\\Delta y=\frac{(500*10^{-9}nm)(5m)}{1*10^{-3}m}=2.5*10^{-3}m=0.25cm[/tex]

hence, the aswer is 0.25cm

Answer:

Statement 3 is correct.

Heisenberg's uncertainty principle explains that the measurement of an observable quantity in the quantum domain inherently changes the value of that quantity

Explanation:

Classical mechanics is the study of motion of big, relatable bodies that we come in contact with in our day to day lives.

Quantum mechanics refers to this same study, but for particles on a subatomic level.

Obviously, Classical mechanics' theories and principles were first discovered and they worked for their intended uses (still work!). But when studies on particles on a sub-atomic level intensified, it became impractical to apply those theories and principles to these sub-atomic particles that displayed wave-particle duality nature properly.

Heisenberg's Uncertainty principle came in a time that explanations and justifications were needed to adapt these theories to sub-atomic particles.

The principle explains properly that it is impossible to measure the position and velocity (momentum) of a sub-atomic particle in exact terms and at the same time.

Mathematically, it is presented as

Δx.Δp ≥ ℏ

Where ℏ= adjusted Planck's constant.

ℏ= (h/2π)

And Δx and Δp are the uncertainties in measuring the position and momentum of sub-atomic particles.

The major reason for this is the wave-particle duality of sub-atomic particles. They exist as waves and particles at the same time that a complete knowledge of their position mean that a complete ignorance of their velocity and vice versa.

Taking the statements one at a time

Statement 1

Quantum Mechanics studies sub-atomic particles which are mostly always in motion. So, this is false.

Statement 2

It is impossible to calculate with accuracy both the position and momentum of particles in quantum mechanics not classical mechanics. As stated above, the reason for the uncertainty is the wave-particle duality of sub-atomic particles which the particle in classical mechanics do not exhibit obviously enough.

Statement 3

Any attempt to measure precisely the velocity of a subatomic particle, will knock it about in an unpredictable way, so that a simultaneous measurement of its position has no validity.

An essential feature of quantum mechanics is that it is generally impossible, even in principle, to measure a system without disturbing it. This is basically the uncertainty principle rephrased. This is the only true statement.

Hope this Helps!!!

Answer:

a) 1.38°

b) 7.53*10^11 m/s/s

c) 6.52*10^-9m

Explanation:

a) to find the angle you can use the dot product between two vectors:

[tex]\vec{v}\cdot\vec{B}=vBcos\theta\\\\\theta=cos^{1}(\frac{\vec{v}\cdot\vec{B}}{vB})[/tex]

v: velocity of the electron

B: magnetic field

By calculating the norm of the vectors and the dot product and by replacing you obtain:

[tex]B=\sqrt{(20)^2+(50)^2+(30)^2}=61.64mT\\\\v=\sqrt{(40)^2+(30)^2+(50)^2}=70.71m/s\\\\\vec{v}\cdot\vec{B}=[(20)(40)+(50)(30)-(30)(50)]mTm/s=800mTm/s\\\\\theta=cos^{-1}(\frac{800*10^{-3}Tm/s}{(70.71m/s)(61.64*10^{-3}T)})=cos^{-1}(0.183)=1.38\°[/tex]

the angle between v and B vectors is 1.38°

b) the change in the speed of the electron can be calculated by the change in the momentum in the following way:

[tex]\frac{dp}{dt}=F_e=qvBsin\theta\\\\\frac{dp}{dt}=(1.6*10^{-19}C)(70.71m/s)(61.64*10^{-3}T)(sin(1.38\°))=6.85*10^{-19}N[/tex]

due to the mass of the electron is a constant you have:

[tex]\frac{dp}{dt}=\frac{mdv}{dt}=6.85*10^{-19}N\\\\\frac{dv}{dt}=\frac{6.85*10^{-19}N}{9.1*10^{-31}kg}=7.53*10^{11}(m/s)/s[/tex]

the change in the speed is 7.53*10^{11}m/s/s

c) the radius of the helical path is given by:

[tex]r=\frac{m_ev}{qB}=\frac{(9.1*10^{-31}kg)(70.71m/s)}{(1.6*10^{-19}C)(61.64*10^{-3}T)}=6.52*10^{-9}m[/tex]

the radius is 6.52*10^{-9}m

To solve the problem we will apply the concepts related to the Intensity as a function of the power and the area, as well as the electric field as a function of the current, the speed of light and the permeability in free space, as shown below.

The intensity of the wave at the receiver is

[tex]I = \frac{P_{avg}}{A}[/tex]

[tex]I = \frac{P_{avg}}{4\pi r^2}[/tex]

[tex]I = \frac{3.4*10^3}{4\pi(4*1609.34)^2} \rightarrow 1mile = 1609.3m[/tex]

[tex]I = 6.529*10^{-6}W/m^2[/tex]

The amplitude of electric field at the receiver is

[tex]I = \frac{E_{max}^2}{2\mu_0 c}[/tex]

[tex]E_{max}= \sqrt{2I\mu_0 c}[/tex]

The amplitude of induced emf by this signal between the ends of the receiving antenna is

[tex]\epsilon_{max} = E_{max} d[/tex]

[tex]\epsilon_{max} = \sqrt{2I \mu_0 cd}[/tex]

Here,

I = Current

[tex]\mu_0[/tex] = Permeability at free space

c = Light speed

d = Distance

Replacing,

[tex]\epsilon_{max} = \sqrt{2(6.529*10^{-6})(4\pi*10^{-7})(3*10^{8})(60.0*10^{-2})}[/tex]

[tex]\epsilon_{max} = 0.05434V[/tex]

Thus, the amplitude of induced emf by this signal between the ends of the receiving antenna is 0.0543V

Answer:

No

Explanation:

The frequency of oscillation of spring mass system is independent of its amplitude.

The frequency of oscillation will not change because it is not a function of amplitude.

In a real spring-mass system, the spring has a non-negligible mass m. Since not all of the spring's length moves at the same velocity v as the suspended mass  M,  

To determine the frequency of oscillation, the effective mass of the spring is defined as the mass that needs to be added to  M to correctly predict the behaviour of the system.

For vertical springs, however, we need to remember that gravity stretches or compresses the spring beyond its natural length to the equilibrium position. After we find the displaced position

Thus the frequency of oscillation will not change because it is not a function of amplitude.

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The image is missing, so i have attached it;

Answer:

A) V_rel = [-(2.711)i - (0.2588)j] m/s

B) a_rel = (0.8637i + 0.0642j) m/s²

Explanation:

We are given;

the cruise ship velocity; V_b = 1 m/s

Angular velocity; ω = 1 deg/s = 1° × π/180 rad = 0.01745 rad/s

Angular acceleration;α = -0.5 deg/s² = 0.5 x π/180 rad = -0.008727 rad/s²

Now, let's write Velocity (V_a) at A in terms of the velocity at B(V_b) with r_ba being the position vector from B to A and relative velocity (V_rel)

Thus,

V_a = V_b + (ω•r_ba) + V_rel

Now, V_a = 0. Thus;

0 = V_b + (ω•r_ba) + V_rel

V_rel = -V_b - (ω•r_ba)

From the image and plugging in relevant values, we have;

V_rel = -1[(cos15)i + (sin15)j] - (0.01745k * -100j)

V_rel = - (cos15)i - (sin15)j - 1.745i

Note that; k x j = - i

V_rel = [-(2.711)i - (0.2588)j] m/s

B) Let's write the acceleration at A with respect to B in terms of a_b.

Thus,

a_a = a_b + (α*r_ba) + (ω(ω•r_ba)) + (2ω*v_rel) + a_rel

a_a and a_b = 0.

Thus;

0 = (α*r_ba) + (ω(ω•r_ba)) + (2ω*v_rel) + a_rel

a_rel = - (α*r_ba) - (ω(ω•r_ba)) - (2ω*v_rel)

Plugging in the relevant values with their respective position vectors, we have;

a_rel = - (-0.008727k * -100j) - (0.01745k(0.01745k * -100j)) - (2*0.01745k * [-(2.711)i - (0.2588)j])

a_rel = 0.8727i - (0.01745² x 100)j + 0.0946j - 0.009i

Note that; k x j = - i and k x i = j

Thus,simplifying further ;

a_rel = 0.8637i + 0.0642j m/s²

Final answer:

From the ship's frame of reference, person A has a velocity of -1 m/s (opposite to the ship's motion). The acceleration observed would be the negative ship's angular deceleration converted to linear acceleration, needing more data for calculation.

Explanation:

The problem presents a rotational kinematics and relative motion scenario common in physics. Person A is stationary on the dock while the ship moves with velocity vB = 1 m/s and has an angular velocity of ω = 1 deg/s, decreasing at 0.5 deg/s2. From the ship's reference frame, the velocity of person A will appear as the opposite of the ship's velocity, which is -1 m/s. However, since person A is stationary, A's acceleration as observed from the ship would be the opposite of the ship's angular deceleration translated into linear acceleration at the radius person A is perceived to be from the ship's center of rotation, which requires further information to calculate.

Answer: 2000 J.

Explanation: Since work is force*displacement, we just have to multiply the force by the distance: w = f*d = 400 N*5.0 m = 2000 J.

Answer:

Using larger pieces of solids

Using larger pieces of solid the dissolving rate of a solid in water can be decreased. Therefore, the correct option is option C.

A solution is indeed a specific kind of homogenous combination made up of two or even more components that is used in chemistry. A solute is a material that has been dissolved in a solvent, which is the other substance in the combination.

The solvent particles will pull the solute particles apart surround them if the attractive forces here between solute and solvent particles are stronger than the attractive forces keeping the solute particles together. Using larger pieces of solid the dissolving rate of a solid in water can be decreased.

Therefore, the correct option is option C.

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Your question is incomplete but most probably your full question was,  

Which of the following decreases the dissolving rate of a solid in water?

A. raising the temperature

B. stirring constantly

C. using larger pieces of solid

D. crushing the solid

Answer:

by sweating

Explanation:

Answer:

1.7*10^{12}Ucm^-1

Explanation:

The answer to this question is obtained by using the following formula:

[tex]\sigma=nq\mu_e[/tex]

sigma: conductivity

q: charge of the electron = 1.61019*10^{-19}C

mu_e: electron mobility = 8104 m^2/Vs

n: free electron concentration = 1.31029/m^3

By replacing you get:

[tex]\sigma=(1.31*10^{29}/m^3)(1.61*10^{-19}C)(8104 m2/Vs)=1.709*10^{14}\Omega^{-1}m^{-1} \\\\1.709*10^{14}\Omega^{-1} (1*10^{2}cm})^{-1}=1.7*10^{12}\Omega^{-1}cm^{-1}[/tex]

the result obained is not 5.9mU.cm. This is because temperature effects has not taken into account.

Answer:

(D) The speed of the flow at the second point is 2.5 m/s

Explanation:

Given;

at upstream;

the width of the channel, w = 12 m

the depth of water, d = 6.0 m

the speed of the flow, v = 2.5 m/s

at downstream;

the width of the channel, w = 9 m

the depth of water, d = 8.0 m

the speed of the flow, v = ?

Volumetric flow rate for an Ideal incompressible water is given as;

Q = Av

where;

A is the area of the channel of flow

v is velocity of flow

For a constant volumetric flow rate;

A₁v₁ = A₂v₂

A₁ = area of rectangle = L x d = 12 x 6 = 72 m²

A₂ = area of rectangle = L x d = 9 x 8 = 72 m²

(72 x 2.5) = 72v₂

v₂ = 2.5 m/s

Therefore, the speed of the flow at the second point is 2.5 m/s

Answer:

The angular velocity of A equals that of B.

Explanation:

Since both coins are on the same turn table that is rotating with a given angular velocity about a particular axis, then the angular velocity of coin A will be equal to the angular velocity of coin B about that same axis.

Answer:

The tension that must be applied to this string = 477 N

Explanation:

y(x,t)= 0.0321m sin (2.05x-524t + pi/4)

Comparing this to the general wave equation

y(x,t) = A sin (kx - wt + Φ)

where

A = amplitude of the wave = 0.0321 m

k = 2.05 /m

w = 524 /s

Φ = phase angle = pi/4

Velocity of a wave is given by

v = (w/k) = (524/2.05) = 255.61 m/s

Tension in the string is then related to the velocity of wave produced and the linear density through

v = √(T/μ)

v = velocity = 255.61 m/s

T = ?

μ = 0.0073 kg/m

v² = (T/μ)

T = v²μ = (255.61² × 0.0073) = 476.96 N

T = 477 N

Hope this Helps!!!

Answer:

He can return to the spacecraft by sacrificing some of the tools employing the principle of conservation of momentum.

Explanation:

By carefully evaluating his direction back to the ship, the astronaut can throw some of his tools in the opposite direction to that. On throwing those tools of a certain mass, they travel at a certain velocity giving him velocity in the form of recoil in the opposite direction of the velocity of the tools. This is same as a gun and bullet recoil momentum conservation. It is also the principle on which the operational principles of their maneuvering unit is designed.

An astronaut stranded far from their spacecraft can return by using the principle of Newton's third law of motion. By throwing tools in the opposite direction of the spacecraft, the astronaut can create a reaction force that propels them back to the spacecraft.

In this scenario, the astronaut working with many tools some distance away from their spacecraft can use the concept of Newton's third law of motion, also known as action-reaction principle, to return to the spacecraft. According to this law, for every action, there is an equal and opposite reaction. So, the astronaut can return to the spacecraft by sacrificing some of the tools that they are carrying, and throwing the tools in the opposite direction of the spacecraft. When the tools are thrown away, the reaction force will propel the astronaut towards the spacecraft. This is a effective method of maneuvering in space because in the vacuum of space, even small forces can have a significant impact due to the absence of air resistance or friction. This way, the astronaut can cleverly convert a threat into an opportunity and solve their problem with minimal risks.

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Answer:

The direction is due south

Explanation:

From the question we are told that

     The energy of the electron is [tex]E = 19.0keV = 19.0 *10^3 eV[/tex]

      The earths magnetic field is [tex]B = 42.3 \muT = 42.3 *10^{-6} T[/tex]

Generally the force on the electron is perpendicular to the velocity of the elecrton and the magnetic field and this is mathematically reresented as

          [tex]\= F = q (\= v * \=B)[/tex]

On the first uploaded image is an  illustration of the movement of the electron

    Looking at the diagram  we can see that in terms of direction  the magnetic force  is

             [tex]\= F =q(\=v * \= B)= -( -\r i * - \r k)[/tex]

                [tex]= -(- (\r i * \r k))[/tex]

generally  i cross k = -j

      so the equation above becomes

             [tex]\= F = -(-(- \r j))[/tex]

                [tex]= - \r j[/tex]

This show that the direction is towards the south  

Answer:

Frequencies are 0.86Hz

Explanation:

Given v=0.74m/s

d= 0.43m

Lambda/2=0.43m

Thus lambda= 0.86m

And F= v/lambda

0.74/0.86= 0.86Hz

Answer:

The obsrved  frquencies are [tex]f= n (0.86) Hz[/tex] n = 1,2,3,...,n.

Explanation:

   From the question we are told that

        The speed of the wave is v = 0.740 m/s

         The distance from the post is [tex]d = 43.0cm = \frac{43}{10} = 0.43m[/tex]

Generally frequency is mathematically represented as

           [tex]f = \frac{v}{\lambda }[/tex]

so for the first frequency which the the fundamental frequency(first harmonic frequency)  the clothesline(string) would form only one loop and hence the length between the  vertical post and throcky hands is mathematically represented as

        [tex]L = \frac{\lambda}{2}[/tex]

=>    [tex]\lambda = 2L[/tex]

    So

             [tex]f_f =f_1= \frac{v}{2L}[/tex]

       Substituting values

              [tex]f_f = f_1 = \frac{0.740}{2* 0.43}[/tex]

                  [tex]= 0.860 Hz[/tex]

For the second  harmonic frequency  i.e is when the clothesline(string) forms two loops the length is mathematically represented as

        [tex]L = \lambda[/tex]

So the second harmonic frequency is            

           [tex]f_2 = \frac{v}{L}[/tex]

        [tex]f_2 = 2 * \frac{v}{2L}[/tex]

                [tex]f_2 =\frac{0.740}{0.430}[/tex]

                    [tex]= 1.72Hz[/tex]

For the third harmonic frequency i.e  when the clothesline(string) forms three loops the length  is mathematically represented as

                  [tex]L = 3 * \frac{\lambda }{2}[/tex]

So the wavelength is

               [tex]\lambda = \frac{2L}{3}[/tex]

And the third harmonic frequency is mathematically evaluated as

           [tex]f_3 = \frac{v}{\frac{2L}{3} }[/tex]

               [tex]= 3 * \frac{v}{2L}[/tex]

               [tex]f_3=2.58Hz[/tex]

Looking at the above calculation we can conclude that the harmonic frequency of a vibrating string(clothesline) can be mathematically represented as an integer multiple of the fundamental frequency

  i.e

          [tex]f = n f_f[/tex]

         [tex]f = n \frac{v}{2L}[/tex]

           [tex]f= n (0.86) Hz[/tex]

Where n denotes integer values  i.e  n = 1,2,3,....,n.

Note : The length that exist between two nodes which are successive is equivalent to half of the wavelength so when one loop is form the number of nodes would be 2 and on anti-node

Answer:

Explanation:

Range= U²sin2theta/g

= 102²* sin (2*42)/9.8

= 1054.74m

Yes she will be abable to jump

The distance from the edge will be

(1054.74- 420)m

= 634.74m

Answer:

357 mJ

Explanation:

Parameters given:

Number of turns, N = 113

Radius, r = 2.71 cm = 0.0271 m

Resistance connected to coil, R = 10.3 ohms

Time interval, dt = 0.153 s

Change in magnetic field, dB = 0 - 0.441 T = - 0.441 T

First, we need to find the induced EMF in the coil. It is given as:

V = - (N * A * dB)/dt

A = area of coil = pi * r² = 3.142 * 0.0271² = 0.0023 m²

Therefore:

V = - (113 * 0.0023 * - 0.441) / 0.153

V = 0.75 V

Electrical energy dissipated in the resistor is given as:

E = V² / (R * t)

Where t is the time (0.153 secs)

E = (0.75²) / (10.3 * 0.153)

E = 0.357 J = 357 mJ

The energy dissipated in the resistor is 357 mJ

Answer:

3.74 %

Explanation:

Given,

Mass of the fired projectile, m = 0.1 Kg

Mass of the stationary target, M = 2.57 Kg

Speed of the particle after collision

Using conservation of momentum

m v = (m + M) V

0.1 x v = (0.1 + 2.57) V

V = 0.0374 v

Initial KE = [tex]\dfrac{1}{2}mv^2 = \dfrac{1}{2}\times 0.1\times v^2[/tex]

Final KE = [tex]\dfrac{1}{2} (M + m) V^2 = \dfrac{1}{2}\times 2.67\times (0.0374 v)^2[/tex]

Now,

the percent of the projectile's KE carried out by target

  [tex]=\dfrac{\dfrac{1}{2}\times 2.67\times (0.0374 v)^2}{ \dfrac{1}{2}\times 0.1\times v^2}\times 100[/tex]

 [tex]= 3.74\ \%[/tex]

Final answer:

The weight of the pendulum bob on Planet X remains 2.0 kg, the same as on Earth, because the mass of the pendulum bob does not affect the period of a simple pendulum. The difference in periods indicates a change in gravitational strength, not mass.

Explanation:

The question revolves around understanding how the period of oscillation of a simple pendulum changes with gravity on different planets. Since the mass of the pendulum bob does not affect the period of a simple pendulum, which depends only on the length of the pendulum and the gravitational acceleration (g), the weight of the pendulum bob on Planet X would still be 2.0 kg, the same as on Earth. However, the difference in periods between Earth and Planet X indicates a difference in gravitational acceleration, implying that g on Planet X is weaker than on Earth. The formula for the period (T) of a simple pendulum is T = 2π√(l/g), where l is the length of the pendulum and g is the gravitational acceleration. Since the mass of the pendulum bob does not factor into this equation, the weight of the pendulum bob on Planet X remains the same, but its apparent weight will change according to the planet's gravitational pull.

Answer:

a) x = 0.144 m

b) W = 0.15 J

c) E = 0.14 J

d) The block will rise 0.07m after it is released

Explanation:

a) The elastic force equals the gravitational force

F = kx = mg

x = 0.07, m = 0.1 kg, g = 9.81 m/s²

0.07k = 0.1 * 9.8

k = (0.1*9.8)/0.07

k = 14 N/m

When the force, F = 3N

F = kx

3 = 14x

x = 3/14

x = 0.214 m

The position of the block = 0.214 - 0.07 = 0.144m

B) Determine the work you did stretching the spring.

Energy stored in the spring when x = 0.07

E = 0.5 kx²

E = 0.5 * 14 * 0.07²

E = 0.0343 J

Energy stored in the spring when x = 0.214

E = 0.5 kx²

E = 0.5 * 14 * 0.214²

E = 0.32 J

Potential energy lost due to gravity = mgh

PE = 0.1 * 9.81 * 0.144

PE = 0.141 J

So to calculate the work done:

0.0343 + W = 0.32 - 0.141

W = 0.15 J

c) Energy in the spring

E = 0.32 - 0.0343 - 0.15

E = 0.1357 = 0.14 J

d)

[tex]1/2 *k *0.214^{2} = 1/2 kx^{2} + mg(0.214+x)\\0.32 = 7x^{2} + 0.1*9.8(0.214+x)\\[/tex]

Solving for x, x = 0.07 m

The block will rise 0.07m after it is released

this is the sample Answer:    Spring tides occur when the moon is full or new. Earth, the moon, and the Sun are in a line. The moon’s gravity and the Sun’s gravity pull Earth’s crust and ocean water. This causes tides to be higher than normal. At neap tide, the moon and the Sun are at right angles to each other. This happens during the first and third quarters of the lunar cycle. At neap tide, the Sun’s gravity and the moon’s gravity are balanced. High tides are lower; low tides are higher.

Explanation:

just did the assament

Answer:

Spring tides occur when the moon is full or new. Earth, the moon, and the Sun are in a line. The moon’s gravity and the Sun’s gravity pull Earth’s crust and ocean water. This causes tides to be higher than normal.  At neap tide, the moon and the Sun are at right angles to each other. This happens during the first and third quarters of the lunar cycle. At neap tide, the Sun’s gravity and the moon’s gravity are balanced. High tides are lower; low tides are higher.

Explanation:

Just did the quiz.

Complete question is:

Two uniform solid spheres have the same mass of 1.65 kg, but one has a radius of 0.206 m and the other has a radius of 0.804 m. Each can rotate about an axis through its center. (a) What is the magnitude τ of the torque required to bring the smaller sphere from rest to an angular speed of 367 rad/s in 14.5 s? (b) What is the magnitude F of the force that must be applied tangentially at the sphere’s equator to give that torque? What are the corresponding values of (c) τ and (d) F for the larger sphere?

Answer:

A) τ = 0.709 N.m

B) F = 3.44 N

C) τ = 10.8 N.m

D) F = 13.43N

Explanation:

We are given;

Mass if each sphere = 1.65kg

Radius of the first sphere; r1 = 0.206m

Radius of second sphere; r2 = 0.804m

A) initial angular speed of smaller sphere; ω_i = 0 rad/s

Final angular speed of smaller sphere; ω_f = 367 rad/s

Time;t = 14.5 s

The constant angular acceleration is calculated from;

ω_f = ω_i + αt

367 = 0 + α(14.5)

Thus,

α = 367/14.5 = 25.31 rad/s²

The torque is given by the formula;

τ = Iα

Where τ is torque ; I is moment of inertia given as (2/5)Mr²

α is angular acceleration

Thus;

τ = (2/5)(1.65)(0.206)² x 25.31

τ = 0.709 N.m

B) The magnitude of the force that must be applied to give the torque τ is gotten from the formula;

τ = F•r•sin90°

0.709 = F x 0.206 x 1

F = 0.709/0.206

F = 3.44 N

C) Now for the larger sphere, we'll repeat the same procedure in a above. Thus;

The torque is given by the formula;

τ = Iα

Where τ is torque ; I is moment of inertia given as (2/5)Mr²

α is angular acceleration

Thus;

τ = (2/5)(1.65)(0.804)² x 25.31

τ = 10.8 N.m

D) Now for the larger sphere, we'll repeat the same procedure in b above. Thus, τ is gotten from the formula;

τ = F•r•sin90°

10.8 = F x 0.804 x 1

F = 10.8/0.804

F = 13.43N

The electric force between charges can be determined using Coulomb's law. Positive-positive and negative-negative combinations have repulsive forces, while positive-negative combinations have attractive forces. Neutral charges do not exert any force.

The electric force between two charges can be determined using Coulomb's law, which states that the force is directly proportional to the product of the charges and inversely proportional to the square of the distance between them. Using this information, we can rank the six combinations of electric charges based on the electric force acting on q1:

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Answer:

(a) Current is 2831.93 A

(b) [tex]8.40A/m^2[/tex]

(c) [tex]\rho =15.52\times 10^{-9}ohm-m[/tex]

Explanation:

Length of wire l = 3.22 m

Diameter of wire d = 7.32 mm = 0.00732 m

Cross sectional area of wire

[tex]A=\pi r^2=3.14\times 0.00366^2=4.20\times 10^{-5}m^2[/tex]

Resistance [tex]R=11.9mohm=11.9\times 10^{-3}ohm[/tex]

Potential difference V = 33.7 volt

(A) current is equal to

[tex]i=\frac{V}{R}=\frac{33.7}{11.9\times 10^{-3}}=2831.93A[/tex]

(B) Current density is equal to

[tex]J=\frac{i}{A}[/tex]

[tex]J=\frac{2831.93}{4.20\times 10^{-5}}=8.40A/m^2[/tex]

(c) Resistance is equal to

[tex]R=\frac{\rho l}{A}[/tex]

[tex]11.9\times 10^{-3}=\frac{\rho \times 3.22}{4.20\times 10^{-5}}[/tex]

[tex]\rho =15.52\times 10^{-9}ohm-m[/tex]

Answer:

three halves of a wavelength

Explanation:because a

path difference between waves at minimum is (2n+1)*wavelength /2 therefore at second minimum it is for n=1=1.5 times a wavelength. or three halves a wavelength

The path difference in the distance traveled by the wave is three halves of a wavelength. Therefore, option (B) is correct.

Interference can be defined as a phenomenon that takes place in every place. It is a phenomenon in which two waves superpose to create the resultant wave of the higher, lower, or same amplitude.

There are two kinds of Interference which are constructive interference and destructive interference. In constructive interference, the crest of one wave falls on the crest of another wave, and the amplitude increases. In destructive interference, the crest of one wave falls on the trough of another wave, and the amplitude decreases.

For the minima, the path difference is given by (2n -1)/λ.

Here the value of n is given, n = 2

Path difference, = (2×2 - 1)/λ = (3/2)λ

Therefore, the path difference in the distance is (3/2)λ.

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Answer:

The maximun distance is  [tex]z_1 = z_2 = 0.0138m[/tex]

Explanation:

    From the question we are told that

       The wavelength are  [tex]\lambda _ 1 = 540nm (green) = 540 *10^{-9}m[/tex]

                                           [tex]\lambda_2 = 450nm(blue) = 450 *10^{-9}m[/tex]

        The distance of seperation of the two slit is [tex]d = 0.180mm = 0.180 *10^{-3}m[/tex]

        The distance from the screen is [tex]D = 1.53m[/tex]

Generally the distance of the bright fringe to the center of the screen is mathematically represented as

           [tex]z = \frac{m \lambda D}{d}[/tex]

   Where m is  the order of the fringe

For the first wavelength  we have

        [tex]z_1 = \frac{m_1 (549 *10^{-9} * (1.53))}{0.180*10^{-3}}[/tex]

             [tex]z_1=0.00459m_1 m[/tex]

                 [tex]z_1= 4.6*10^{-3}m_1 m ----(1)[/tex]

For the second  wavelength  we have              

        [tex]z_2 = m_2 \frac{450*10^{-9} * 1.53 }{0.180*10^{-3}}[/tex]

        [tex]z_2 = 0.003825m_2[/tex]

        [tex]z_2 = 3.825 *10^{-3} m_2 m[/tex]  ----(2)

From the question we are told that the two sides coincides with one another so

            [tex]zy_1 =z_2[/tex]

         [tex]4.6*10^{-3}m_1 m = 3.825 *10^{-3} m_2 m[/tex]

          [tex]\frac{m_1}{m_2} = \frac{3.825 *10^{-3}}{4.6*10^{-3}}[/tex]

Hence for this equation to be solved

       [tex]m_1 = 3[/tex]

and  [tex]m_2 = 4[/tex]

Substituting this into the  equation

                      [tex]z_1 = z_2 = 3 * 4.6*10^{-3} = 4* 3.825*10^{-3}[/tex]

      Hence [tex]z_1 = z_2 = 0.0138m[/tex]

The minimum distance from the center of the screen where green and blue bright fringes coincide is calculated using principles of double-slit interference. Applying these principles and trigonometry, we find the minimum distance from the center of the screen to this point.

To find the minimum distance from the center of the screen to a point where a bright fringe of the green light coincides with a bright fringe of the blue light, we can use the formula for double slit interference:

d sin θ = mλ

where d is the separation of the slits, θ is the angle from the central bright fringe, m is the order of fringe, and λ is the wavelength of light.

For the green and blue lights to interfere constructively on the screen for the first time, their path length difference must be equal to their respective wavelengths. Therefore, the order of fringe for the green light will be different from the blue light. The minimum distance can be found when the fringe order for the green light (m1) is 1 and for the blue light (m2) is, by proportion of the wavelengths, rounded to the nearest whole number. Solving the equation for each colour and setting them equal will give the minimum distance.

Finally, the distance from the center to the fringe can be calculated using the trigonometric relationship:

L tan θ, where L is the distance from the slits to the screen.

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(a) [tex]\(a_c \approx 39.8 \, \text{m/s}^2\)[/tex]

(b) [tex]\(r \approx 11.6 \, \text{m}\)[/tex]

(c) [tex]\(v_2 \approx 28.4 \, \text{m/s}\)[/tex]

(a) calculation of the centripetal acceleration [tex](\(a_c\))[/tex],

[tex]\[ a_c = \frac{g}{\sin(\theta_1)} \][/tex]

Given [tex]\(g \approx 9.8 \, \text{m/s}^2\) and \(\theta_1 = 15.0°\)[/tex], we find:

[tex]\[ a_c = \frac{9.8 \, \text{m/s}^2}{\sin(15.0°)} \][/tex]

Calculating this gives [tex]\(a_c \approx 39.8 \, \text{m/s}^2\).[/tex]

(b) The radius ((r)) of the curve can be found using the formula:

[tex]\[ r = \frac{v^2}{a_c} \][/tex]

Substituting [tex]\(v = 21.5 \, \text{m/s}\) and \(a_c \approx 39.8 \, \text{m/s}^2\),[/tex]we get:

[tex]\[ r = \frac{(21.5 \, \text{m/s})^2}{39.8 \, \text{m/s}^2} \][/tex]

This calculation yields [tex]\(r \approx 11.6 \, \text{m}\).[/tex]

(c) For a new deflection angle [tex]\(\theta_2 = 7.00°\)[/tex], we find the new centripetal acceleration [tex](\(a_{c2}\))[/tex] using:

[tex]\[ a_{c2} = \frac{g}{\sin(\theta_2)} \][/tex]

Substituting [tex]\(g \approx 9.8 \, \text{m/s}^2\) and \(\theta_2 = 7.00°\)[/tex], we get:

[tex]\[ a_{c2} = \frac{9.8 \, \text{m/s}^2}{\sin(7.00°)} \][/tex]

Calculating this gives [tex]\(a_{c2} \approx 84.7 \, \text{m/s}^2\).[/tex]

Then, using [tex]\(a_{c2} = \frac{v_2^2}{r}\)[/tex], we find the new speed [tex](\(v_2\)):[/tex]

[tex]\[ v_2 = \sqrt{a_{c2} \cdot r} \][/tex]

Substituting [tex]\(a_{c2} \approx 84.7 \, \text{m/s}^2\) and \(r \approx 11.6 \, \text{m}\), we get \(v_2 \approx 28.4 \, \text{m/s}\).[/tex]

The moment of inertia of the solid cylinder can be found by calculating the torque and the angular acceleration of the cylinder, and then relating these quantities using the equation torque equals moment of inertia times angular acceleration.

The moment of inertia of the solid cylinder can be found using the relationship between torque acting on the cylinder and its angular acceleration, both of which can be inferred from the given information. The torque τ on the cylinder is given by the product of the force applied and the radius of the cylinder, τ = Fr. Since this force is causing the cylinder to undergo rotational motion, it is also causing an angular acceleration α, which can be calculated from the slope of plot relating angular displacement θ and time t squared, as α is directly proportional to slope of θ vs t² plot.

By relating these variables using the equation τ = Iα, where I is the moment of inertia, we can solve for I as: I = τ/α = Fr/α. By substituting given values, we can compute specific value for moment of inertia.

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