A typical stellar spectrum (a plot of intensity versus wavelength) includes a number of deep indentations in which the intensity abruptly falls and then rises. These deep indentations are called ____ lines.

The compound (NH4)2O is known as Ammonium Oxide, consisting of two ammonium ions and one oxide ion. It's produced via an acid-base reaction, with the ammonium ion acting as a weak acid and the oxide ion as a strong base. Such compounds have broad applications.

The compound (NH4)2O is known as Ammonium Oxide. It consists of two ammonium ions (NH4+) and one oxide ion (O2-). In terms of acid-base reactions, the ammonium ion is considered a weak acid due to its ability to donate a proton to water, while the oxide ion as a strong base accepts protons from water.

The formation of Ammonium Oxide involves the transfer of H+ ions from water molecules to ammonia molecules, which then react with the oxide anions to create the final compound. Ammonium compounds, including Ammonium Oxide, have applications in areas like agriculture and commodity chemical synthesizing.

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Answer:

226.70

Explanation:

Answer: $226.70 on edg

Explanation:

Answer:

Explanation:

Constant pressure molar heat capacity Cp = 29.125 J /K.mol

If Cv be constant volume molar heat capacity

Cp - Cv = R

Cv = Cp - R

= 29.125 - 8.314 J

= 20.811 J

change in internal energy = n x Cv x Δ T

n is number of moles , Cv is molar heat capacity at constant volume ,  Δ T is change in temperature

Putting the values

= 20 x 20.811 x 15

= 6243.3 J.

Answer:

The charge on the outer surface of the block = -5.00 nC

The charge on the surface of the cavity (on the inner surface of the block) = -3.00 nC

Explanation:

The point charge within the cavity will induce a charge equal in magnitude and opposite in sign on the inside cavities of the copper block.

Charge of the point charge = 3.00 nC

Charge induced on the inner surface of the Copper block's cavity = -3.00 nC

Since the charge on a conductor should usually be neutral, the charge on the inner surface causes a charge equal in magnitude and also opposite in sign on the outer surface of the block; that is, 3.00 nC.

But this block already has an excess charge of -8.00 nC (which resides on the surface because excess charge for conductors reside on the surface of the conductors)

So, net charge on the outer surface of the Copper block = -8.00 + 3.00 = -5.00 nC.

Hope this Helps!!!

Answer:

The sun's intensity for a planet located at a distance 5 R from the Sun is 4 W/m²

Explanation:

The intensity of Sun located at a distance of R away is [tex]100\ W/m^2[/tex].

We need to find the sun's intensity for a planet located at a distance 5 R from the Sun. Intensity is given by :

[tex]I\propto \dfrac{1}{r^2}[/tex]

So,

[tex]\dfrac{I_1}{I_2}=(\dfrac{r_2}{r_1})^2[/tex]

Here, I₁ = 100 W/m² and r₁ = R and r₂ = 5R

[tex]I_2=\dfrac{I_1r_1^2}{r_2^2}[/tex]

[tex]I_2=\dfrac{100(R^2)}{(5R)^2}\\\\I_2=\dfrac{100}{25}\\\\I_2=4\ W/m^2[/tex]

So, the sun's intensity for a planet located at a distance 5 R from the Sun is 4 W/m².

Answer:

a. Smallest photon energy = 0.04 eV

b. Next larger photon energy = 0.08 eV

c. Largest photon energy = 0.12 eV

Explanation:

Since the spacing between the levels is 0.04 even

The smallest photon energy, E= 0.04 eV

The next larger photon energy = 2E = 2×0.04 = 0.08 eV

Largest photon energy = 3E = 3×0.04 = 0.12

The relationships for the atomic transitions allowed to find all the transitions in the four-level system are:

Atomic Transitions are the energy deference between two specific atomic levels.

        [tex]\Delta E = E_f - E_i[/tex]  

They indicate that we have 4 equally spaced states with an energy difference of 0.04 eV between each one.

In the attachment we can see a diagram of the system with an arrow indicating the possible transitions.

From level n = 2 to level n = 1 the energy is E₂₁ = 0.04 eV.

from level n = 3 to n = 1 the energy is E₃₁ = 0.08 eV.

all other transitions in the table.

Initial state   final state    Energy (eV)

    4                   1               0.12

    3                   1               0.08

    2                   1               0.04

    4                  2              0.08

     3                 2              0.04

     4                3               0.04

These are all the possible transitions, we can see that some energies have several possible states, these currents that have several possibilities are called degenerate.

the energies are:

the minimum is:   E = 0.04 eV.

the following is:    E = 0.08 eV.

the maximum  is E: = 0.12 eV.

In conclusion using the relationships for the atomic transitions we can find all the transitions in the four-level system are:

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Answer:

100 newtons

Explanation:

Recall force is the product of mass and acceleration from Newton's 2nd law given base units kgms^-2 which is equivalent to a newton( N)

NOTE: The diagram is attached to this solution

Answer:

The acceleration of point A = 14.64 ft/s²

Explanation:

By proper analysis of the diagram, acceleration of point A will be: (Check the free body diagram attached)

[tex]a_{A} = \bar{a} + \frac{\alpha L}{2}[/tex]

Weight, W = mg

g = 32.2 ft/s²

m = W/g

[tex]p = m \bar{a}\\p = w \bar{a} /g[/tex]

[tex]\bar{a} = pg/w\\\bar{a} = 0.25g/2.2\\\bar{a} =3.66[/tex]

[tex]\frac{pL}{2} = I \alpha[/tex]

but [tex]I = \frac{wL^{2} }{12g}[/tex]

[tex]\frac{pL}{2} = \frac{\alpha wL^{2} }{12g}\\\alpha = \frac{6 g p}{wL}\\\alpha = \frac{6*g*0.25}{2.2L} \\\alpha = 21.96/L[/tex]

[tex]a_{A} = 3.66 + \frac{(21.96/L ) * L}{2}\\a_{A} = 3.66 + 10.98\\a_{A} = 14. 64 ft/s^{2}[/tex]

To solve this problem we will apply the concepts related to continuity and later to Bernoulli's principle. With the continuity equation we will relate the diameters of the two measurements to find the speed. Later with the speed we will proceed to replace it in the Bernoulli equations to find the pressure.

By continuity equation

[tex]A_1 V_1 = A_2 V_2[/tex]

[tex](\frac{\pi D^2_1}{4})V_1 = (\frac{\pi D_2^2}{4})V_2[/tex]

[tex]D_1^2V_1 = D_2^2V_2[/tex]

With the relation of diameters we have

[tex]D_1^2V_1 = (\frac{2D_1}{3})^2V_2[/tex]

[tex]D_1V_1 = (\frac{4}{9})D_1^2V_2[/tex]

[tex]V_1 = \frac{4}{9}V_2[/tex]

Replacing the value of the Volume

[tex]V_1 = \frac{4}{9} (18)[/tex]

[tex]V_1 = 8m/s[/tex]

By Bernoulli's equation

[tex]P_1 + \frac{\rho V_1^2}{2} = P_2 + \frac{\rho V_2^2}{2}[/tex]

[tex]P_1 + \frac{(1000)(8)^2}{2} = 50662.5+\frac{(1000)(18)^2}{2}[/tex]

[tex]P_1 = 180662.5Pa (\frac{1atm}{101325Pa})[/tex]

[tex]P_1 = 1.8atm[/tex]

Therefore the water pressure in the wide section is 1.8atm

Answer:

Explanation:

charge on the capacitor = capacitance x potential

= 1.588 x 3.4

= 5.4 C  

Energy of capacitor  = 1 / 2 C V ² , C is capacitance , V is potential

=  .5 x 3.4 x 1.588²

= 4.29  J

If I be maximum current

energy of inductor = 1/2 L I² , L is inductance of inductor .

energy of inductance = Energy of capacitor

1/2 L I² = 4.29

I² = 107.25

I = 10.35 A

Time period of oscillation

T = 2π √ LC

=2π √ .08 X 3.4

= 3.275 s

current in the inductor will be maximum in T / 4 time

= 3.275 / 4

= .819 s.

Total energy of the system

= initial energy of the capacitor

=  4.29  J

Answer:

The angular velocity is

5.64rad/s

Explanation:

This problem bothers on curvilinear motion

The angular velocity is defined as the rate of change of angular displacement it is expressed in rad/s

We know that the velocity v is given as

v= ωr

Where ω is the angular velocity

r is 300mm to meter = 0.3m

the radius of the circle

described by the level

v=1.64m/s

Making ω subject of the formula and solving we have

ω=v/r

ω=1.64/0.3

ω=5.46 rad/s

To solve this problem we will apply the concepts related to Reyleigh's criteria. Here the resolution of the eye is defined as 1.22 times the wavelength over the diameter of the eye. Mathematically this is,

[tex]\theta = \frac{1.22 \lambda }{D}[/tex]

Here,

D is diameter of the eye

[tex]D = \frac{1.22 (539nm)}{5.11 mm}[/tex]

[tex]D= 1.287*10^{-4}m[/tex]

The angle that relates the distance between the lights and the distance to the lamp is given by,

[tex]Sin\theta = \frac{d}{L}[/tex]

For small angle, [tex]sin\theta = \theta[/tex]

[tex]sin \theta = \frac{d}{L}[/tex]

Here,

d = Distance between lights

L = Distance from eye to lamp

For small angle [tex]sin \theta = \theta[/tex]

Therefore,

[tex]L = \frac{d}{sin\theta}[/tex]

[tex]L = \frac{0.691m}{1.287*10^{-4}}[/tex]

[tex]L = 5367m[/tex]

Therefore the distance is 5.367km.

Explanation:

Given:

Distance between the transmitter and receiver = 160 km

Distance between Earth and Sun (D) = 150000000 km

Distance between Earth and Moon (D') = 380000 km

Distance between Earth and space ship (D") = 360000000 km

Distance between Earth and Supernova (d) = 9300 LY

We know that,

Speed of Light = 300000 km/sec

Lets us solve each problem now:

a) We know that the radio waves travle with speed of light. So the time(T) taken by the signal from transmitter to receiving antenna will be,

[tex]Time = \frac{Distance}{Speed}[/tex]

[tex]T = \frac{160}{300000}[/tex]

T = 0.53 millisecond

b) Time taken by sunlight to reach Earth is,

[tex]T_{1} = \frac{150000000}{300000} seconds[/tex]

T₁ = 500 seconds = 08 min 20 seconds

Time taken by light from Moon to reach Earth will be,

[tex]T_{2} = \frac{380000}{300000} seconds[/tex]

T₂ = 1.26 seconds

Let us assume that in the given situation Earth and Moon are at the same distance from the Sun. This means that Sun light will take the same time to reach Moon as it will take to reach Earth. So Sun light reaches the Moon in 500 seconds. After that it will be reflected towards Earth and will take 1.26 seconds more to reach Earth.

Thus the light left the Sun 501.26 seconds earlier.

c) Time taken by the light from space ship to reach Earth will be,

[tex]T = \frac{360000000}{300000} seconds[/tex]

T = 1200 seconds.

Thus round trip time will be = 2T = 2400 seconds

d) Lightyear is a unit of distance and is equal to the distance travelled by light in a year. If a supernova is at a distance of 9300 LY it means that light has taken 9300 years to reach Earth from that supernova. It means that the light we see today was actually generated from the supernova 9300 years ago.

It is evident that the explosion actually occurred 9300 years back.

We have calculated the times light and radio signals take to travel given distances at the speed of light; these times depend directly on the distances. For the observed supernova, we use the reverse calculation, determining the time light has traveled given the distance in light-years.

(a) The radio signal is essentially light, so it travels at the speed of light, which is about 300,000 kilometers per second (3 × 10⁸ m/s). To find the time it takes to travel 160 km, we simply divide the distance by the speed: 160 km / 300000 km/s = 0.00053 seconds, or about 0.53 milliseconds.

(b) The light we see from the Moon has indeed traveled from the Sun, bounced off the Moon, and then hit our eyes. Therefore, it has traveled a distance of the Earth–Sun distance plus the Earth–Moon distance. Adding these distances, the light has traveled a total of 1.5 × 10⁸ km + 3.8 × 10⁵ km = 1.50038 × 10⁸ km. Dividing this distance by the speed of light gives the time this light has traveled: 1.50038 × 10⁸ km / 300000 km/s = 500.13 seconds, or about 8 minutes and 20 seconds.

(c) The round-trip travel time of light between Earth and a spaceship would be twice the time it would take light to make a one-way trip. The one-way trip time is calculated as the distance divided by the speed of light, which is 3.6 × 10⁸ km / 300000 km/s = 1200 seconds. Therefore, the round-trip travel time would be 2400 seconds or 40 minutes.

(d) A light-year is the distance that light travels in one year, so if a supernova is observed to be 9300 light-years away, this means the light from the supernova has been traveling for 9300 years before reaching Earth. Therefore, the supernova actually happened 9300 years ago.

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Answer:

mass of ball 1=m1

mass of ball 2=m2

velocity of ball=r1w1

velocity of ball 2=r2w2

Total angular momentum=m1*v1+m2*v2

but

v1=r1*w1

v2=r2*w2

Substitute values in above equation

Total angular momentum of the system=m1*r1*w1+m2*r2*w2

The total angular momentum of the system at point B  will be [tex]\rm L=m_1 r_1\omega_1 +m_2 r_2 \omega_2[/tex].

The rotating counterpart of linear momentum is angular momentum also known as moment of momentum or rotational momentum.

The given data in the problem is;

m₁ is the mass of ball 1

m₂ mass of ball 2=m2

v₁ is the velocity of ball=r₁ω₁

v₂ is the velocity of ball 2=r₂ω₂

The total angular momentum of a system at point B  is given as;

[tex]\rm V_{total}= r_1\omega_1 + r_2 \omega_2 \\\\ \rm L=m_1 r_1\omega_1 +m_2 r_2 \omega_2[/tex]

Hence the total angular momentum of the system at point B  will be [tex]\rm L=m_1 r_1\omega_1 +m_2 r_2 \omega_2[/tex].

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Answer:

No

Explanation:

Because the people put in charge of defining SI units said so

Answer:

a) proportion of latent heat involved in work against the interatomic attraction = 0.794

b)Depth of the well in Joules = 23 * 10^-24 J

ii) In eV, E = 0.000144 eV

III) in Kelvin, E = 1.67 K

C) Check the explanation section for C

Explanation:

a) Latent heat, Q = 21.8 kJ/kg

Vapor density, Vd = 19 kg/m^3

Liquid density, Ld = 125 kg/ m^3

Pressure, P = 1 atm = 1 * 10^5 Pa

Volume change from liquid to vapor = (1/Vd) - (1/ Ld)

Volume change = (1/19) - (1/125)

Volume change = 0.045 m^3

Work done in converting from liquid to vapor, W = P * (Volume change)

W = 1 *0.045 * 10^5

W = 4.5 kJ

Let the proportion of latent heat involved in work against the interatomic attraction be Pr

Pr = (Q - W)/Q

Pr = (21.8 - 4.5)/21.8

Pr = 0.794

b) To calculate the depth of the potential well :

I) In joules

n(L-W) = 0.5 z Na E

z = 10

Where E = depth of the well

4(21.8-4.5) = 0.5 * 10 * 6.02 * 10^23 * E

E = 23 * 10^-24 J

ii) In eV

E = ( 23 * 10^-24)/(1.6 * 10^-19)

E = 0.000144 eV

III) In Kelvin

E = ( 23 * 10^-24)/(1.38 * 10^-23)

E = 1.67 K

C) Helium turns to a gas at that low temperature because of the large workdone (4.5 kJ) against the interatomic attraction.

Final answer:

a. About 83% of the latent heat is involved in work against the interatomic attraction. b. The depth of the potential well is approximately 4.62 x 10^-23 J, 2.88 x 10^14 eV, and 33.6 K. c. Helium turns into a gas at low temperatures due to its weak interatomic attraction.

Explanation:

a. To calculate the proportion of latent heat involved in work against interatomic attraction, we need to first calculate the work done using the formula W = P(V2 - V1), where P is the pressure and V2 and V1 are the volumes of the vapor and liquid respectively. The difference in volume is V2 - V1 = 1 - 19 = -18 m^3. Since the work done is negative (work is done against the interatomic attraction), the proportion of latent heat involved in work is given by the ratio |W|/Q, where Q is the latent heat of vaporization. Therefore, the proportion is |(-1 atm)(-18 m^3)/(21.8 kJ/kg)| = 0.8292, or about 83%.

b. The depth e of the potential well can be estimated using the formula e = kT/2, where k is Boltzmann's constant and T is the temperature. The average number of nearest neighbors z is 10, and the atomic number of helium is 4. Therefore, the depth e can be calculated as e = (4 * (1.38 x 10^-23 J/K) * 4.2 K)/(2 * 10) = 4.62 x 10^-23 J. This is equivalent to approximately 2.88 x 10^14 eV and 33.6 K.

c. Helium turns into a gas at such low temperatures because its interatomic attraction is weak. The low mass and low atomic number of helium result in weak intermolecular forces, making it easier for helium atoms to overcome the attractive forces and transition from a liquid to a gas state at low temperatures.

Answer:

[tex]\alpha=214.8 rad/s^2[/tex]

Explanation:

We are given that

[tex]F_1=137 N[/tex]

[tex]F_2=43 N[/tex]

Net force=F=[tex]F_1-F_2=137-43=94 N[/tex]

Mass,m=1.21 kg

Radius,r=0.723 m

We have to find the magnitude of its angular acceleration.

Moment of inertia ,[tex]I=\frac{1}{2}mr^2[/tex]

Substitute the values

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

[tex]F_{net}\times r=\frac{1}{2}mr^2\alpha[/tex]

[tex]\alpha=\frac{2F_{net}}{mr}[/tex]

[tex]\alpha=\frac{2\times 94}{1.21\times 0.723}[/tex]

[tex]\alpha=214.8 rad/s^2[/tex]

Answer:

(a) E=λ/(2\pi e0 r)

(b) E = 0

Explanation:

(a) We can use the Gaussian's Law to calculate the electric field at any distance r from the axis. By using a cylindrical Gaussian surface we have:

[tex]\int \vec{E}\cdot d\vec{r}=\frac{\lambda}{\epsilon_o}[/tex]

where  λ is the total charge per unit length inside the Gaussian surface. In this case we have that the Electric field vector is perpendicular to the r vector. Hence:

[tex]E\int dr=E2\pi r=\frac{\lambda}{\epsilon_o}\\\\E=\frac{\lambda}{2\pi r \epsilon_o}[/tex]

(b) outside of the outer cylinder there is no net charge inside the Gaussian surface, because charge of the inner radius cancel out with the inner surface of the cylindrical conductor.

Hence, we  have that E is zero.

hope this helps!!

Answer:

1a. E(r) = lambda/ 2πrEo

1b. Electric field outside the outside cylinder = lambda/ 2πrEo

Explanation:

Answer:

The gravitational acceleration on the surface of Planet-X is 1.5 [tex]ms^{-2}[/tex]

Explanation:

Firstly, we are to list out the parameters given:

Mass (m) = 35.5 g, Length of string (L) = 133 cm = 1.33 m, t = 70.7 seconds for 12 oscillations, T = 70.7 ÷ 12 = 5.89 seconds

The formula for calculating the period of a simple pendulum (assuming the angle of deflection is lesser than 15º) is given by:

[tex]T=2\pi\sqrt{\frac{L}{g}}\\[/tex]  

We want to calculate for the gravitational acceleration (g), hence, we have to make g the subject of the formula

[tex]g=4\pi^{2}\frac{L}{T^{2}}\\[/tex]

Substitute the parameters into the equation, we have:

g = [tex]4\pi^{2}[/tex] * 1.33 ÷ [tex]5.89^{2}[/tex] = 1.51

g = 1.5 [tex]ms^{-2}[/tex]

The gravitational acceleration on the surface of Planet-X is 1.5 [tex]ms^{-2}[/tex]

Answer:

the gravitational acceleration of the Xplanet is 1.344m/s^2

Explanation:

You can use the formula for the calculation of the frequency of a pendulum, in order to find an expression for the gravitational constant:

[tex]f=\frac{1}{2\pi}\sqrt{\frac{g}{l}}\\\\g=4\pi^2 f^2l[/tex]

Where you can notice that mass ob the object does not influence of the gravitatiolan acceleration. By the information of the question, you have the values of f and l. By replacing these values (with units of meter and seconds) you obtain:

[tex]f=\frac{12}{70.7}=0.16s^{-1}\\\\g=4\pi^2(0.16s^{-1})^2(1.33m)=1.344\frac{m}{s^2}[/tex]

Hence, the gravitational acceleration of the Xplante is 1.344m/s^2

Answer:

Average velocity = 1.835 m/s

Explanation:

Detailed explanation and calculation is shown in the image below

The average velocity in the 0.3 m diameter pipe. The result is 1.833 m/s.

To find the average velocity in the 0.3 m diameter pipe, we'll use the principle of continuity for incompressible fluid flow. The flow rate (Q) must be the same at all points in the system.

First, we calculate the flow rates in the two initial pipes:

For the 0.15 m diameter pipe: Q1 = A₁ v₁ = π (0.075)² 2 m/s = π × 0.005625 m² × 2 m/s = 0.01125π m³/s

For the 0.2 m diameter pipe: Q2 = A2 v2 = π (0.1)² 3 m/s = π × 0.01 m² × 3 m/s = 0.03π m³/s

The combined flow rate entering the 0.3 m diameter pipe is:

[tex]Q_t = Q_1 + Q_2[/tex] = 0.01125π m³/s + 0.03π m³/s = 0.04125π m³/s

Next, we find the area of the 0.3 m diameter pipe:

A₃ = π (0.15)² = π 0.0225 m²

The average velocity in the 0.3 m diameter pipe is then:

v₃ = Qtotal / A₃ = (0.04125π m³/s) / (π 0.0225 m²) ≈ 1.833 m/s

Thus, the average velocity in the 0.3 m diameter pipe is 1.833 m/s.

- **Frequency after gravel falls off at maximum displacement:**

[tex]\[ f' \approx 0.800 \text{ cycles/s} \][/tex]

- **Amplitude after gravel falls off at maximum displacement:**

[tex]\[ A' = 0.4 \text{ m} \][/tex]

- **Frequency after gravel falls off at maximum speed:**

[tex]\[ f' \approx 0.800 \text{ cycles/s} \][/tex]

- **Amplitude after gravel falls off at maximum speed:**

[tex]\[ A'' \approx 0.399 \text{ m} \][/tex]

Step 1

To analyze the subsequent simple harmonic motion (SHM) of the beam after the gravel falls off, we need to address the changes in the system's mass and how these changes affect the frequency and amplitude of the oscillations. Let's break down each part of the problem.

Initial System Details

- **Mass of the beam, [tex]\( m_{\text{beam}} \)[/tex]:** 225 kg

- **Mass of the sack of gravel, [tex]\( m_{\text{gravel}} \)[/tex]:** 175 kg

- **Total initial mass, [tex]\( m_{\text{total}} \):** \( 225 \text{ kg} + 175 \text{ kg} = 400 \text{ kg} \)[/tex]

- **Amplitude, A:** 40.0 cm = 0.4 m

- **Frequency, f:** 0.600 cycles/s

Step 2

The angular frequency [tex](\(\omega\))[/tex] is related to the frequency by:

[tex]\[ \omega = 2 \pi f \]\[ \omega = 2 \pi \times 0.600 \text{ s}^{-1} = 1.2 \pi \text{ s}^{-1} \][/tex]

Step 3

Spring Constant and Natural Frequency

For a system undergoing SHM, the angular frequency is given by:

[tex]\[ \omega = \sqrt{\frac{k_{\text{eff}}}{m}} \][/tex]

Where [tex]\( k_{\text{eff}} \)[/tex] is the effective spring constant of the system, and m is the mass. Rearranging for [tex]\( k_{\text{eff}} \)[/tex]:

[tex]\[ k_{\text{eff}} = \omega^2 m_{\text{total}} \]\[ k_{\text{eff}} = (1.2 \pi)^2 \times 400 \text{ kg} \]\[ k_{\text{eff}} = (1.44 \pi^2) \times 400 \text{ kg} \]\[ k_{\text{eff}} = 1.44 \times 9.8696 \times 400 \text{ kg} \]\[ k_{\text{eff}} \approx 5680 \text{ N/m} \][/tex]

Step 4

1. Frequency of Subsequent SHM after Gravel Falls Off at Maximum Upward Displacement

When the gravel falls off, the total mass reduces to the mass of the beam:

[tex]\[ m_{\text{beam}} = 225 \text{ kg} \][/tex]

The new angular frequency [tex](\(\omega'\))[/tex] is given by:

[tex]\[ \omega' = \sqrt{\frac{k_{\text{eff}}}{m_{\text{beam}}}} \]\[ \omega' = \sqrt{\frac{5680 \text{ N/m}}{225 \text{ kg}}} \]\[ \omega' \approx \sqrt{25.2444 \text{ s}^{-2}} \]\[ \omega' \approx 5.024 \text{ s}^{-1} \][/tex]

The new frequency [tex]\( f' \)[/tex] is:

[tex]\[ f' = \frac{\omega'}{2 \pi} \]\[ f' \approx \frac{5.024}{2 \pi} \]\[ f' \approx 0.800 \text{ cycles/s} \][/tex]

Step 5

2. Amplitude of Subsequent SHM after Gravel Falls Off at Maximum Upward Displacement

When the gravel falls off at the maximum upward displacement, the energy is conserved. The amplitude remains the same because the position where the gravel falls off doesn't change the energy stored in the system at that instant.

So, the amplitude of the subsequent SHM is still:

[tex]\[ A' = 0.4 \text{ m} \][/tex]

Step 6

3. Frequency of Subsequent SHM after Gravel Falls Off at Maximum Speed

The frequency of SHM depends on the system's mass and the effective spring constant. When the gravel falls off at maximum speed, the frequency calculation remains the same as the first part since the only factor affecting frequency is the mass change.

Thus, the frequency remains:

[tex]\[ f' \approx 0.800 \text{ cycles/s} \][/tex]

Step 7

4. Amplitude of Subsequent SHM after Gravel Falls Off at Maximum Speed

At maximum speed, the kinetic energy is at its maximum. When the gravel falls off, the kinetic energy initially stored in the combined system transfers entirely to the beam. The initial total kinetic energy is:

[tex]\[ KE = \frac{1}{2} m_{\text{total}} \omega^2 A^2 \][/tex]

After the gravel falls off, the new amplitude [tex]\( A'' \)[/tex] can be found using:

[tex]\[ KE = \frac{1}{2} m_{\text{beam}} \omega'^2 A''^2 \][/tex]

Since the kinetic energy is conserved:

[tex]\[ \frac{1}{2} m_{\text{total}} \omega^2 A^2 = \frac{1}{2} m_{\text{beam}} \omega'^2 A''^2 \]\[ m_{\text{total}} \omega^2 A^2 = m_{\text{beam}} \omega'^2 A''^2 \][/tex]

Solve for [tex]\( A'' \)[/tex]:

[tex]\[ A''^2 = \frac{m_{\text{total}} \omega^2 A^2}{m_{\text{beam}} \omega'^2} \]\[ A'' = \sqrt{\frac{m_{\text{total}} \omega^2 A^2}{m_{\text{beam}} \omega'^2}} \]\[ A'' = \sqrt{\frac{400 \times (1.2 \pi)^2 \times 0.4^2}{225 \times (5.024)^2}} \][/tex]

Substitute the values:

[tex]\[ A'' = \sqrt{\frac{400 \times 1.44 \pi^2 \times 0.16}{225 \times 25.2444}} \]\[ A'' = \sqrt{\frac{400 \times 1.44 \times 9.8696 \times 0.16}{225 \times 25.2444}} \]\[ A'' = \sqrt{\frac{900.9792}{5670.99}} \]\[ A'' \approx \sqrt{0.1589} \]\[ A'' \approx 0.399 \text{ m} \][/tex]

Thus, the new amplitude is approximately [tex]\( 0.399 \text{ m} \).[/tex]

Answer:

Explanation:

Hooke's Law is a principle of physics that states that the that the force needed to extend or compress a spring by some distance is proportional to that distance. ... In addition to governing the behavior of springs, Hooke's Law also applies in many other situations where an elastic body is deformed

Answer:

Yeah ,The extension of the spring is directly proportional to the force applied.

The time it would take for the swimmer to swim 50.0m would increase in lane 1, where there is a current flowing in the same direction of the swimmers. In lane 8, where there is a current flowing in the opposite direction, the time would decrease.

In lane 1, where there is a 1.2 cm/s current flowing in the direction of the swimmers, the time it would take for the swimmer to swim 50.0 m would increase. This is because the current would push the swimmer backwards, making it harder for them to reach the finish line.

In lane 8, where there is a 1.2 cm/s current flowing in the opposite direction of the swimmers, the time it would take for the swimmer to swim 50.0 m would decrease. This is because the current would push the swimmer forward, helping them reach the finish line faster.

Answer:

Time = 77.63 s

Distance = 3673.3 ft

Explanation:

Using equation of motion

v = u + at'

50 = 6 * t'

t' = 50 / 6

t' = 8.33 s

v² = u² + 2a(s - s•)

50² = 0² + 2 * 6 * (s - 0)

2500 = 12 * s

s' = 2500 / 12

s' = 208.3 ft

At t' = 8.33 the distance traveled by the car is

s'' = v• * t'

s'' = 30 * 8.33

s'' = 250 ft

Now, the distance between the motorcycle and car is

6000 - 208.33 - 250 = 5541.67

For motorcycle, when passing occurs,

s = v• * t, x = 50 * t''

For the car, when passing occurs,

s = v• * t, 5541.67 - x = 30 * t''

Solving both simultaneously, we have

5541.67 - [50 * t''] = 30 * t''

5541.67 = 30t''+ 50t''

5541.67 = 80t''

t''= 5541.67 / 80

t''= 69.3 s, substituting t'' = 69.3 back, we have

x = 50 * 69.3

x = 3465 ft

Therefore for motorcycle,

t = 69.3 + 8.33

t = 77.63 s

S = 3465 + 208.3

s = 3673.3 ft

Final Answer:

The total time [tex]\( t \)[/tex] for the motorcycle to pass the car is calculated to be [tex]\( 77.63 \)[/tex] seconds, and the distance traveled by the motorcycle when passing the car is approximately [tex]\( 3673.3 \)[/tex]feet.

Explanation:

The calculation begins by using the equation of motion ( v = u + at ), where (v ) represents final velocity, ( u ) is initial velocity, ( a ) is acceleration, and (t) is time. Substituting the given values, the time ( t' ) for the motorcycle to reach a speed of ( 50 ) ft/s with a constant acceleration of [tex]( 6\) ft/s\(^2\) )[/tex]is found to be approximately ( 8.33 ) seconds.

Next, the equation of motion [tex]\( v^2 = u^2 + 2a(s - s_0) \)[/tex] is used, where [tex]\( s \)[/tex] represents distance, [tex]\( s_0 \)[/tex] is initial distance, and other variables have the same meanings as before. Solving for [tex]\( s' \),[/tex] the distance traveled by the motorcycle during this time is approximately [tex]\( 208.3 \)[/tex] feet.

At [tex]\( t' = 8.33 \)[/tex] seconds, the distance traveled by the car is calculated to be [tex]\( 250 \)[/tex]feet.

The distance between the motorcycle and car when they pass each other is found to be approximately [tex]\( 5541.67 \)[/tex] feet.

To determine the time [tex]\( t'' \)[/tex] when the passing occurs, simultaneous equations for the motorcycle and car are set up using their respective distances. Solving these equations yields [tex]\( t'' = 69.3 \)[/tex] seconds. Substituting this value back, the distance traveled by the motorcycle when passing the car is approximately [tex]\( 3465 \)[/tex]feet.

Answer:

Maximum wavelength will be [tex]3.96\times 10^{-7}m[/tex]

Explanation:

It is given wavelength [tex]\lambda =242nm=242\times 10^{-9}m[/tex]

Speed of light [tex]c=3\times 10^8m/sec[/tex]

Plank's constant [tex]h=6.6\times 10^{-4}Js[/tex]

So energy is equal to

[tex]E=\frac{hc}{\lambda }=\frac{6.6\times 10^{-34}\times 3\times 10^8}{242\times 10^{-9}}=8.18\times 10^{-19}J[/tex]

Maximum kinetic energy is given

[tex]KE_{max}=1.99eV=1.99\times 1.6\times 10^{-19}=3.184\times 10^{-19}J[/tex]

Work function is equal to

[tex]w_0=E-KE_{max}=8.18\times 10^{-19}-3.184\times 10^{-19}=5\times 10^{-19}J[/tex]

[tex]\frac{hc}{\lambda _0}=5\times 10^{-19}[/tex]

[tex]\frac{6.6\times 10^{-34}\times 3\times 10^8}{\lambda _0}=5\times 10^{-19}[/tex]

[tex]\lambda _0=3.96\times 10^{-7}m[/tex]

Answer:

Explanation:

The pictures attached below shows the solution to the problem and i hope its explanatory enough. Thank you

Answer:

m * c1 * (9 - 6) = m * c2 * (19 - 9) → mass m cancels

c2 = c1 * 3 / 10 = 0.3*c1

Explanation:

However, for the second mix, there should be nothing from the first mix's answer except for 0.3c1. Essentially, the left side of the second mix equation should look like: m *0.3c1 * (31.1-19). Then, you can properly solve the equation.

Answer:

The current is  [tex]I =0.2mA[/tex]

Explanation:

From the question we are told that

   The first radius is [tex]R_1 = 5cm = \frac{5}{100} = 0.05cm[/tex]

    The number of turns is [tex]N = 17 \ turn/cm[/tex]

    The current rate is  [tex]\frac{dI}{dt} = 5 A/s[/tex]

    The second radius is  [tex]R_2 = 7cm = \frac{7}{100} = 0.07m[/tex]

     The resistance is [tex]r = 5 \Omega[/tex]

Generally the magnetic flux induced in the solenoid is mathematically represented as

      [tex]\O = B A[/tex]

 Where  is the magnetic field mathematically represented as

            [tex]B = N \mu_o I[/tex]

Where [tex]\mu_o[/tex] is the permeability of free space with a value of [tex]\mu_o = 4\pi *10^{-7} N/A^2[/tex]

     and A is the area mathematically represented as

             [tex]A = \pi (R_2 - R_1)^2[/tex]

So

         [tex]\O = N \mu I * \pi R^2[/tex]

            Substituting values

        [tex]\O = 17 * 4\pi *10^{-7} * \pi (7-5)^2I[/tex]

           [tex]\O = 2.68*10^{-4}I[/tex]

The induced emf is mathematically represented as

              [tex]\epsilon =- |\frac{d\O}{dt}|[/tex]

                  [tex]\epsilon = 2.68*10^{-4 } \frac{dI}{dt}[/tex]

substituting values

               [tex]\epsilon =2.68 *10^{-4} * 5[/tex]

                  [tex]=1.3 *10^{-3} V[/tex]

From Ohm law

      [tex]I = \frac{\epsilon }{r}[/tex]

Substituting values

     [tex]I = \frac{1.3*0^{-3}}{5}[/tex]

        [tex]I =0.2mA[/tex]

The question is incomplete! Complete question along with answer and step by step explanation is provided below.

Question:

A pair of narrow slits that are 1.8 mm apart is illuminated by a monochromatic coherent light source. A fringe pattern is observed on a screen 4.8 m from the slits. If there are 5.0 bright fringes/cm on the screen, what is the wavelength of the monochromatic light?

Given Information:

Distance from the double slits to the screen = D = 4.8 m

Double slit separation distance = d = 1.8 mm = 0.0018 m

Number of fringes = m = 5

Distance between fringes = y = 1 cm = 0.01 m

Required Information:

Wavelength of the monochromatic light = λ = ?

Answer:

Wavelength of the monochromatic light = λ = 7.5x10⁻⁷ m

Explanation:

The wavelength of the monochromatic light can be found using young's double slits formula,

λ = yd/mD

where d is the double slit separation distance, D is the distance from the double slits to the screen, y is the distance between bright fringes and m is number of fringes.

λ = 0.01*0.0018/5*4.8

λ = 0.00000075 m

λ = 7.5x10⁻⁷ m

Therefore, the wavelength of the monochromatic light is 7.5x10⁻⁷ m

Answer:

51.3 Degrees

The presence of person above the center of mass of ladder will make the ladder more likely to slip.

Explanation:

Explanation in the attachment.

51.3 Degrees, The presence of person above the centre of mass of ladder will make the ladder more likely to slip.

The middle of a uniform ladder is where the center of mass is located. A smooth wall signifies that there is no friction felt on the wall, whereas rough ground indicates that there is friction there.

How to use static equilibrium to determine the coefficient of friction between the bottom of the ladder and the ground is shown in the Ladder Problem from Static Equilibrium. The torque, the x-direction forces, and the y-direction forces are added together and set to zero.

It follows that the force exerted on the ladder as a result of the resultant moment of the forces must also equal zero due to a random point.

Thus, it is 51.3 Degrees.

For more information about uniform ladder, click here:

https://brainly.com/question/29768495

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