The speed of sound in air is around 345 m/s. A tuning fork vibrates at 850 Hz above the open end of the sound resonance tube. What is the wavelength (in cm) of the sound waves in the tube? Never include units with a numerical answer.

Answer:

[tex]5.28\times 10^{-5}\ /^{\circ}C[/tex]

Explanation:

[tex]L_0[/tex] = Original length of rod

[tex]\alpha[/tex] = Coefficient of linear expansion = [tex]1.62\times 10^{-5}\ /^{\circ}C[/tex]

Initial temperature = 16°C

Final temperature = 260°C

Change in length of a Steel is given by

[tex]\Delta L=\alpha L_0\Delta T\\\Rightarrow \Delta L=11\times 10^{-6}\times 23.83\times (260-16)\\\Rightarrow \Delta L=0.06395972\ cm[/tex]

Change in material rod length will be

[tex]23.83-23.59+0.0639572=0.3039572\ cm[/tex]

The coefficient of thermal expansion is given by

[tex]\alpha=\frac{\Delta L}{L_0\Delta T}\\\Rightarrow \alpha=\frac{0.3039572}{23.59\times (260-16)}\\\Rightarrow \alpha=5.28\times 10^{-5}\ /^{\circ}C[/tex]

The coefficient of thermal expansion for the material is [tex]5.28\times 10^{-5}\ /^{\circ}C[/tex]

Answer with Explanation:

Mass of block=1.1 kg

Th force applied on block is given by

F(x)=[tex](2.4-x^2)\hat{i}N[/tex]

Initial position of the block=x=0

Initial velocity of block=[tex]v_i=0[/tex]

a.We have to find the kinetic energy of the block when it passes through x=2.0 m.

Initial kinetic energy=[tex]K_i=\frac{1}{2}mv^2_i=\frac{1}{2}(1.1)(0)=0[/tex]

Work energy theorem:

[tex]K_f-K_i=W[/tex]

Where [tex]K_f=[/tex]Final kinetic energy

[tex]K_i[/tex]=Initial kinetic energy

[tex]W=Total work done[/tex]

Substitute the values then we get

[tex]K_f-0=\int_{0}^{2}F(x)dx[/tex]

Because work done=[tex]Force\times displacement[/tex]

[tex]K_f=\int_{0}^{2}(2.4-x^2)dx[/tex]

[tex]K_f=[2.4x-\frac{x^3}{3}]^{2}_{0}[/tex]

[tex]K_f=2.4(2)-\frac{8}{3}=2.13 J[/tex]

Hence, the kinetic energy of the block as it passes thorough x=2 m=2.13 J

b.Kinetic energy =[tex]K=2.4x-\frac{x^3}{3}[/tex]

When the kinetic energy is maximum then [tex]\frac{dK}{dx}=0[/tex]

[tex]\frac{d(2.4x-\frac{x^3}{3})}{dx}=0[/tex]

[tex]2.4-x^2=0[/tex]

[tex]x^2=2.4[/tex]

[tex]x=\pm\sqrt{2.4}[/tex]

[tex]\frac{d^2K}{dx^2}=-2x[/tex]

Substitute x=[tex]\sqrt{2.4}[/tex]

[tex]\frac{d^2K}{dx^2}=-2\sqrt{2.4}<0[/tex]

Substitute x=[tex]-\sqrt{2.4}[/tex]

[tex]\frac{d^2K}{dx^2}=2\sqrt{2.4}>0[/tex]

Hence, the kinetic energy is maximum at x=[tex]\sqrt{2.4}[/tex]

Again by work energy theorem , the  maximum kinetic energy of the block between x=0 and x=2.0 m is given by

[tex]K_f-0=\int_{0}^{\sqrt{2.4}}(2.4-x^2)dx[/tex]

[tex]k_f=[2.4x-\frac{x^3}{3}]^{\sqrt{2.4}}_{0}[/tex]

[tex]K_f=2.4(\sqrt{2.4})-\frac{(\sqrt{2.4})^3}{3}=2.48 J[/tex]

Hence, the maximum energy of the block between x=0 and x=2 m=2.48 J

Answer:

(a) 498.4 Hz

(b) 442 Hz

Solution:

As per the question:

Length of the wire, L = 1.80 m

Weight of the bar, W = 531 N

The position of the copper wire from the left to the right hand end, x = 0.40 m

Length of each wire, l = 0.600 m

Radius of the circular cross-section, R = 0.250 mm = [tex].250\times 10^{- 3}\ m[/tex]

Now,

Applying the equilibrium condition at the left end for torque:

[tex]T_{Al}.0 + T_{C}(L - x) = W\frac{L}{2}[/tex]

[tex]T_{C}(1.80 - 0.40) = 531\times \frac{1.80}{2}[/tex]

[tex]T_{C} = 341.357\ Nm[/tex]

The weight of the wire balances the tension in both the wires collectively:

[tex]W = T_{Al} + T_{C}[/tex]

[tex]531 = T_{Al} + 341.357[/tex]

[tex]T_{Al} = 189.643\ Nm[/tex]

Now,

The fundamental frequency is given by:

[tex]f = \frac{1}{2L}\sqrt{\frac{T}{\mu}}[/tex]

where

[tex]\mu = A\rho = \pi R^{2}\rho[/tex]

(a) For the fundamental frequency of Aluminium:

[tex]f = \frac{1}{2L}\sqrt{\frac{T_{Al}}{\mu}}[/tex]

[tex]f = \frac{1}{2L}\sqrt{\frac{T_{Al}}{\pi R^{2}\rho_{Al}}}[/tex]

where

[tex]\rho_{l} = 2.70\times 10^{3}\ kg/m^{3}[/tex]

[tex]f = \frac{1}{2\times 0.600}\sqrt{\frac{189.643}{\pi 0.250\times 10^{- 3}^{2}\times 2.70\times 10^{3}}} = 498.4\ Hz[/tex]

(b)  For the fundamental frequency of Copper:

[tex]f = \frac{1}{2L}\sqrt{\frac{T_{C}}{\mu}}[/tex]

[tex]f = \frac{1}{2L}\sqrt{\frac{T_{C}}{\pi R^{2}\rho_{C}}}[/tex]

where

[tex]\rho_{C} = 8.90\times 10^{3}\ kg/m^{3}[/tex]

[tex]f = \frac{1}{2\times 0.600}\sqrt{\frac{341.357}{\pi 0.250\times 10^{- 3}^{2}\times 2.70\times 10^{3}}} = 442\ Hz[/tex]

Answer:

b. 25 N to the left.

Explanation:

Hi there!

The static friction force is calculated as follows:

Fr = N · μ

Where:

Fr = friction force.

N = normal force.

μ = coefficient of static friction.

If the object is not being accelerated in the vertical direction, the normal force is equal to the weight of crate (with opposite sign). Then:

Fr = 50 N · 0.50

Fr = 25 N

Since the 20-N force is applied to the right of the box, the friction force will be directed to the left because the friction force opposes the displacement. Then, the right answer is "b": 25 N to the left.

The resulting static friction force on the crate will be 20 N to the left, matching the applied force but acting in the opposite direction to prevent the crate from moving.

The question is related to static and kinetic friction in physics. A 50-N crate on a horizontal floor has a coefficient of static friction (μs) of 0.50. When a 20-N force is applied, the force of static friction (fs) that acts on the crate in response can be calculated. Since the applied force is less than the maximum possible static friction force (μs × normal force), the static friction will equal the applied force but act in the opposite direction, preventing the crate from moving. Here, the normal force (N) is equal to the weight of the crate because the floor is horizontal and there is no vertical acceleration.

The maximum static friction force would be fs(max) = μs × N = 0.50 × 50 N = 25 N. However, the applied force is only 20 N. Since this is less than the maximum, the actual static frictional force will match the applied force of 20 N, opposing the direction of the applied force, which is to the left. Thus, the correct answer is a. 20 N to the left.

Answer:

a)[tex]v=\dfrac{2.KE}{qBR}[/tex]

b)[tex]m=\dfrac{(qBR)^2}{2.KE}[/tex]

Explanation:

Given that

Charge = q

Magnetic filed = B

Radius = R

We know that kinetic energy KE

[tex]KE=\dfrac{1}{2}mv^2[/tex]                    ----------1

m v² = 2 .KE            

The magnetic force F = q v B

Radial force

[tex]Fr=\dfrac{1}{R}mv^2[/tex]

For uniform force these two forces should be equal

[tex]q v B=\dfrac{1}{r}mv^2[/tex]

q v B R =m v²

q v B R =  2 .KE

[tex]v=\dfrac{2.KE}{qBR}[/tex]

Now put the velocity v in the equation

[tex]KE=\dfrac{1}{2}mv^2[/tex]

[tex]m=\dfrac{2 .KE}{v^2}[/tex]

[tex]m=\dfrac{2.KE}{\left(\dfrac{2.KE}{qBR}\right)^2}[/tex]

[tex]m=\dfrac{(qBR)^2}{2.KE}[/tex]

Final answer:

To find the speed and mass of a charged particle moving in a magnetic field, we use its uniform circular motion to derive formulas for speed (v = qBR/m) and mass (m = q^2B^2R^2/(2KE)). These expressions help us understand the relationship between the particle's physical properties and its motion within the magnetic field.

Explanation:

To find the expressions for the speed v and mass m of a charged particle moving in a circular path of radius R inside a uniform magnetic field, we utilize the motion equations for a particle undergoing uniform circular motion due to a magnetic force. The magnetic force provides the centripetal force required for this motion and is given by qvB, where q is the charge, v is the velocity, and B is the magnetic field strength. This force is equal to the centripetal force needed for circular motion, which is given by mv2/R.

(a) Rearranging the formula qvB = mv2/R to solve for v, we get:
 v = qBR/m

(b) To find the mass m, we use the particle’s kinetic energy KE and the velocity from part (a). Since KE = 1/2 mv2 and the value of v is qBR/m, we can substitute it to get:
 m = q2B2R2/(2KE)

The units of these expressions can also be derived to ensure they're correct. Additionally, if we consider changes to the magnetic field's strength or the particle's charge, we can infer how these changes affect the radius R using the derived formulas.

Answer:

True A and B

Explanation:

Let's propose the solution of the exercise before seeing the affirmations.

We use the law of refraction

      n₁ sin θ₁ = n₂. Sin θ₂

Where n₁ and n₂ are the refractive indices of the two means, θ₁ and θ₂ are the angles of incidence and refraction, respectively

      sin θ₂ = (n1 / n2) sin θ₁

Let's apply this equation to the case presented. The index of refraction and airs is 1 (n1 = 1)

     Sin θ₂ = (1 / n2) sin θ₁

 the angle  θ₂ which is the  refracted angle is less than the incident angle

Let's analyze the statements time

A. False. We saw that it deviates

B. True Approaches normal (vertical axis)

C. False It deviates, but it is not parallel to normal

D. False It deviates, but approaching the normal not moving away

E. True. Because its refractive index is higher than air,

When a beam of light with an angle of incidence less than 90° enters a denser medium like a glass slab, it bends closer to the normal, bends away from the normal, and slows down, dependent on the refractive indices of the two media. Here options B, D, and E are correct.

When a beam of light travels from air into a denser medium, such as a glass slab, it undergoes refraction. Refraction is the bending of light as it passes from one medium to another with a different optical density.

The angle of incidence, the angle formed between the incident ray and the normal (a line perpendicular to the surface at the point of incidence), plays a crucial role in determining the behavior of the refracted light.

These statements are correct. The degree to which the light bends depends on the refractive indices of the two media. In this case, as light enters the glass slab, it slows down due to the higher refractive index of glass compared to air.

The bending of light towards the normal and slowing down are characteristic behaviors of light when it travels from a less dense to a denser medium. Here options B, D, and E are correct.

To learn more about beam

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Answer:

The number of capillaries is

[tex]N=2.625x10^9[/tex] Capillaries

Explanation:

[tex]v_{aorta}=42cm/s[/tex], [tex]r_{aorta}=1.1 cm[/tex], [tex]v_{cap}=0.064cm/s[/tex], [tex]r_{cap}=5.5x10^{4}cm[/tex],

To find the number of capillaries in the human body use the equation:

[tex]N_{cap}=\frac{v_{aorta}*\pi*r_{aorta}^2}{v_{cap}*\pi*r_{cap}^2}[/tex]

So replacing numeric

[tex]N_{cap}=\frac{42cm/s*\pi*(1.1cm)^2}{0.064cm/s*\pi*(5.5x10^{-4}cm)^2}[/tex]

Now we can find the number of capillaries

[tex]N=26250000000[/tex]

[tex]N=2.625x10^9[/tex] Capillaries

Answer:

ω = 26.35 rad/s

Explanation:

given,                            

speed of discus thrower = 25.3 m/s

whirling through  = 1.29 rev          

radius of circular arc = 0.96 m          

final angular speed of the discus = ?

using formula                      

v =  ω r                  

v  is the velocity of disk

ω is the angular speed of the discus

r is the radius of arc                      

[tex]\omega = \dfrac{v}{r}[/tex]                

[tex]\omega = \dfrac{25.3}{0.96}[/tex]                      

      ω = 26.35 rad/s

Final angular speed of the discus is equal to ω = 26.35 rad/s

The final angular speed is approximately 26.354 rad/s. To find the final angular speed, we use the relation [tex]\omega = v / r[/tex]. With v = 25.3 m/s and r = 0.96 m.

Calculate the final angular speed (ω) using the linear speed provided. Rotational motion relies on the relationship between linear speed (v) and angular speed (ω), which is expressed as [tex]v = r\cdot \omega[/tex], where r is the circular path radius. Rearranging this equation yields [tex]\omega = v / r[/tex], demonstrating the angular speed's direct and inverse relationship.

Here, v = 25.3 m/s (final linear speed) and r = 0.96 m (radius of the circle):

Conclusion:

Thus, the final angular speed of the discus is approximately 26.354 rad/s.

The velocity of Ned as measured by Pam is the interpretation of v.

Answer: Option D

Explanation:

According to question, we know that this is an issue depending on the logical and translation of the factors. From the measured information taken what is gathered by the two people is communicated and we have given as:

The Ned reference framework : (x, t)  

The Pam reference framework :  [tex]\left(x^{\prime}, t^{\prime}\right)[/tex]

From the reference framework, we realize that ν is the speed of Pam (the other reference framework) as estimation by Ned.  

At that point, [tex]v^{\prime}[/tex] is the speed of Ned (from the other arrangement of the reference) as estimation by Pam.

In the context of relativity, the velocity denoted by v' represents the velocity of Ned as measured by Pam. Primed quantities typically refer to measurements in the moving reference frame, making option (d) correct.

The question is asking about the interpretation of the notation v', which is used in a relativistic physics context. The correct interpretation of v' in the context of relativity would be d. The velocity of Ned as measured by Pam. This is because primed quantities (e.g. x', t', v') typically refer to measurements made in the moving reference frame relative to the unprimed frame. Since Pam's frame is the one moving with velocity v in Ned's frame, v' would be the velocity Ned appears to have when observed from Pam's frame. Accordingly, option (d) is the correct choice.

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Answer:

0.639 V

Explanation:

The volatge of the cell containing both Ag/AgCl reference electrode and

[tex]Fe^{2+}/Fe^{3+}[/tex] electrode = 0.693 V

Thus,

[tex]E_{cathod}-E_{anode} =0.693 V[/tex]

E_{anode}=0.197 V

Note: potential of the silver-silver chloride reference electrode (0.197 V)

⇒E_{Cthode}= 0.693+0.197 = 0.890V

To calculate the voltage of the cell containing both the calomel reference

electrode and [tex]Fe^{2+}/Fe^{3+}[/tex] electrode as follows

Voltage of the cell = [tex]E_{cathod}-E_{anode}[/tex]

E_{anode}= calomel electrode= 0.241 V

Voltage of the cell = 0.890-0.241 = 0.639 V

Therefore, the new volatge is = 0.639 V

One of the scientific characteristics that can make the difference between the Earth and the moon is the so-called Rayleigh dispersion effect. This concept is identified as the dispersion of visible light or any other electromagnetic radiation by particles whose size is much smaller than the wavelength of the dispersed photons. Our atmosphere allows even our 'shadows' to be clear.

On the moon under the absence of the atmosphere or any other mechanism that allows absorbing or failing to re-irradiate sunlight towards the area in its shadows, which makes the shadows on the moon look darker.

Answer:

411087.52089 J

[tex]\frac{K_r}{K_b}=154.31213[/tex]

Explanation:

R = Radius of Earth = 6370000 m

h = Altitude of satellite = 810 km

r = R+h = 63700000+810000 m

m = Mass of bullet = 3.7 g

Velocity of bullet = 1200 m/s

The relative velocity between the pellets and satellite is 2v

Now, the square of velocity is proportional to the kinetic energy

[tex]K\propto v^2[/tex]

[tex]\\\Rightarrow 4K\propto (2v)^2\\\Rightarrow 4K\propto 4v^2[/tex]

Kinetic energy in terms of orbital mechanics is

[tex]K=\frac{GMm}{2r}[/tex]

In this case relative kinetic energy is

[tex]K_r=4\frac{GMm}{2r}\\\Rightarrow K_r=2\frac{6.67\times 10^{-11}\times 5.98\times 10^{24}\times 3.7\times 10^{-3}}{(6370+810)\times 10^3}\\\Rightarrow K_r=411087.52089\ J[/tex]

The relative kinetic energy is 411087.52089 J

The ratio of kinetic energies is given by

[tex]\frac{K_r}{K_b}=\frac{411087.52089}{\frac{1}{2}\times 3.7\times 10^{-3}\times 1200^2}\\\Rightarrow \frac{K_r}{K_b}=154.31213[/tex]

The ratio is [tex]\frac{K_r}{K_b}=154.31213[/tex]

Final answer:

The specific gravity of a liquid can be calculated using the formula: Specific Gravity = mL / mA. Specific gravity is a dimensionless number used to compare the density of a substance with the density of water.

Explanation:

The specific gravity of a liquid can be calculated using the formula:

Specific Gravity = mL / mA

Here, mL is the apparent mass of the object in the unknown liquid, and mA is the apparent mass of the object in water. Specific gravity is a dimensionless number, so it doesn't have any units. It is used to compare the density of a substance with the density of water, which is 1.0 g/mL.

To solve the problem it is necessary to apply the concepts related to torque, as well as the concepts where the Force is defined as a function of mass and acceleration, which in this case is gravity.

Considering the system in equilibrium, we perform sum of moments in the rear wheel (R2)

[tex]\sum M = 0[/tex]

[tex]F_g*1.68-R_1*d = 0[/tex]

[tex]mg*1.68-R_1*d = 0[/tex]

Another of the parameters given in the problem is that the front wheel supports 43% of the weight, that is

[tex]R1=0.43F_g[/tex]

[tex]R1=0.43mg[/tex]

Replacing, we have to

[tex]mg*1.68 -R_1*d = 0[/tex]

[tex]mg*1.68 -0.43mg*d = 0[/tex]

[tex]mg*1.68 =0.43mg*d[/tex]

[tex]1.68 = 0.43*d[/tex]

[tex]d =3.9m[/tex]

Therefore the wheelbase of the truck is 3.9m between the front and the rear.

With the use of physics principles, the truck's wheelbase, given that the rear wheels support 57.0% of the weight, and this weight acts at the center of gravity 1.68 meters in front of the rear wheels, is found to be 3.90 meters.

The question asks for the wheelbase of the truck, which can be solved using physics principles such as torque and equilibrium. The center of gravity is the point where all the weight can be considered to be concentrated for the purpose of calculations. Here, we know that the rear wheels support 57.0% of the weight of the truck, and this weight acts at the center of gravity, which is 1.68 meters in front of the rear wheels. Given that the truck is in equilibrium (i.e., not tipping over), the torques about any point caused by the weight must cancel out. Hence, the total distance from the rear wheels (where the 57% weight acts) to the front wheels (where the 43% weight acts) is (1.68 m * 57.0 / 43.0) m = 2.22 meters. Therefore, the wheelbase of the truck is 1.68 m + 2.22 m = 3.90 meters.

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Answer:

Thermal energy will be equal to 784 J

Explanation:

We have given that mass of the child m = 40 kg

Height h = 2 m

Acceleration due to gravity [tex]g=9.8m/sec^2[/tex]

We have to find the thermal energy '

The thermal energy will be equal to potential energy

And we know that potential energy is given by

[tex]W=mgh=40\times 9.8\times 2=784J[/tex]

So the thermal energy will be equal to 784 J

Answer:

563712.04903 Pa

Explanation:

m = Mass of material = 3.3 kg

r = Radius of sphere = 1.25 m

v = Volume of balloon = [tex]\frac{4}{3}\pi r^3[/tex]

M = Molar mass of helium = [tex]4.0026\times 10^{-3}\ kg/mol[/tex]

[tex]\rho[/tex] = Density of surrounding air = [tex]1.19\ kg/m^3[/tex]

R = Gas constant = 8.314 J/mol K

T = Temperature = 345 K

Weight of balloon + Weight of helium = Weight of air displaced

[tex]mg+m_{He}g=\rho vg\\\Rightarrow m_{He}=\rho vg-m\\\Rightarrow m_{He}=1.19\times \frac{4}{3}\pi 1.25^3-3.3\\\Rightarrow m_{He}=6.4356\ kg[/tex]

Mass of helium is 6.4356 kg

Moles of helium

[tex]n=\frac{m}{M}\\\Rightarrow n=\frac{6.4356}{4.0026\times 10^{-3}}\\\Rightarrow n=1607.85489[/tex]

Ideal gas law

[tex]P=\frac{nRT}{v}\\\Rightarrow P=\frac{1607.85489\times 8.314\times 345}{\frac{4}{3}\pi 1.25^3}\\\Rightarrow P=563712.04903\ Pa[/tex]

The absolute pressure of the Helium gas is 563712.04903 Pa

Final answer:

To find the absolute pressure of helium gas in the balloon, we can use the ideal gas law. Since the thickness of the material is negligible compared to the radius of the balloon, we can consider the balloon as a sphere. Once we have the number of moles, we can substitute the values into the ideal gas law and solve for P, the absolute pressure.

Explanation:

To find the absolute pressure of helium gas in the balloon, we can use the ideal gas law: PV = nRT, where P is the pressure, V is the volume, n is the number of moles, R is the gas constant, and T is the temperature. In this case, we need to solve for P. Since the thickness of the material is negligible compared to the radius of the balloon, we can consider the balloon as a sphere and use the formula for the volume of a sphere: V = (4/3)πr^3, where r is the radius. Given that the radius is 1.25 m and the volume is known, we can calculate the number of moles of helium using the ideal gas law and the molar mass of helium.

Once we have the number of moles, we can substitute the values into the ideal gas law and solve for P, the absolute pressure. Remember to convert the temperature from Celsius to Kelvin by adding 273.15 to the given temperature.

Para resolver este problema es necesario aplicar los conceptos de Fuerza, dados en la segunda Ley de Newton y el concepto de Trabajo, como expresión de la fuerza necesaria para realizar una actividad en una distancia determinada.

El trabajo se define como

W = F*d

Where,

F = Force

d = Distance

At the same time we have that the Force by second's Newton law is equal to

F = mg

Where,

m = mass

g = Gravitational acceleration

PART A) Using our values and replacing we have that

[tex]W = F*d\\W = mg*d\\W=281.5*9.8(17.1*10^{-2}\\W = 471.738 J\approx 472J[/tex]

PART B) Using Newton's Second law we have that,

[tex]F = mg \\F= 281.5*9.8\\F= 2758.7 N \approx 2.76kN[/tex]

Answer:0.548 gallon

Explanation:

Given

Average coefficient of volume expansion for carbon Tetrachloride [tex]\beta =5.81\times 10^{-4} /^{\circ}C[/tex]

Volume of steel container [tex]V=50 gallon[/tex]

Initial temperature [tex]T_i=10^{\circ}C[/tex]

Final temperature [tex]T_f=30^{\circ}C[/tex]

[tex]\Delta T=20^{\circ}C[/tex]

Coefficient of expansion for steel is [tex]\alpha =11\times 10^{-6}[/tex]

[tex]\beta =3\alpha =3\times 11\times 10^{-6}[/tex]

[tex]\beta =33\times 10^{-6}/^{\circ}C[/tex]

[tex]\Delta V_{spill}=\Delta V_{liquid}-\Delta V_{steel}[/tex]

[tex]\Delta V_{spill}=(\beta _{carbon}-\beta _{steel})V_0(\Delta T)[/tex]

[tex]\Delta V_{spill}=(5.81\times 10^{-4}-33\times 10^{-6})50\times 20[/tex]

[tex]\Delta V_{spill}=0.548\ gallon[/tex]

Approximately 0.04927 gal of carbon tetrachloride will spill over when the temperature rises to 30.0°C inside a 50.0-gal steel container.

To calculate how much carbon tetrachloride will spill over when the temperature rises, we need to find the change in volume for the steel container and the carbon tetrachloride. The change in volume can be calculated using the formula:

ΔV = V * β * ΔT

where ΔV is the change in volume, V is the initial volume, β is the coefficient of volume expansion, and ΔT is the change in temperature.

Using the given values, the change in volume for the steel container is 0.000605 gal and for the carbon tetrachloride is 0.04927 gal. Therefore, approximately 0.04927 gal of carbon tetrachloride will spill over when the temperature rises to 30.0°C.

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Answer:

0.958 m

Explanation:

So the total mass of the system is

M = 1.93 + 2.95 + 2.41 + 3.99 = 11.28  kg

let y be the distance from the center of mass to the origin. With the reference to the origin then we have the following equation

[tex]My = m_1y_1 + m_2y_2 +m_3y_3 + m_4y_4[/tex]

[tex]11.28y = 1.93*2.91 + 2.95*2.43 + 2.41*0 + 3.99*(-0.496) = 10.806[/tex]

[tex]y = \frac{10.806}{11.28} = 0.958 m[/tex]

So the center of mass is 0.958 m from the origin

Answer:

(a) [tex]\displaystyle s(t)= \frac{t^3}{3}-\frac{t^2}{2}-20t+C\ \ \ \ \forall\ \  3\leqslant t\leqslant 9[/tex]

(b) 78 m

Explanation:

Physics' cinematics as rates of change.

Velocity is defined as the rate of change of the displacement. Acceleration is the rate of change of the velocity.

[tex]\displaystyle v=\frac{ds}{dt}[/tex]

Knowing that

[tex]\displaystyle v(t)= t^2 - t - 20[/tex]

(a) To find the displacement we need to integrate the velocity

[tex]\displaystyle \frac{ds}{dt}=t^2 - t - 20[/tex]

[tex]\displaystyle ds=(t^2 - t - 20)dt[/tex]

[tex]\displaystyle s(t)= \int(t^2 - t - 20)dt=\frac{t^3}{3}-\frac{t^2}{2}-20t+C\ \ \ \ \forall \ \ \ 3\leqslant t\leqslant 9[/tex]

(b) The displacement can be found by evaluating the integral

[tex]\displaystyle d=\int_{3}^{9} (t^2 - t - 20)dt[/tex]

[tex]\displaystyle d=\left | \frac{t^3}{3}-\frac{t^2}{2}-20t \right |_3^9=\frac{45}{2}+\frac{111}{2}=78\ m[/tex]

To find displacement, we integrate the velocity function from 3 to 9. The displacement is the integral of the velocity function. For distance, we integrate the absolute value of the velocity function from 3 to 9 because distance is a scalar quantity and includes total path length.

To solve the problem, we need to find the displacement and distance traveled by the particle. For part (a), the displacement for the given time period is obtained by integrating the velocity function from 3 to 9. The displacement is the integral of the velocity function v(t) = t2 - t - 20 from 3 to 9, which gives us the value s(9) - s(3).

For part (b), to calculate the distance traveled, we need to integrate the absolute value of the velocity function because the distance is always positive. Negative values would represent backward motion, but the distance traveled includes total path length and does not care about direction.

So, the distance traveled from time 3 to 9 would be ∫ |t2 - t - 20| dt from 3 to 9. The calculation of this integral will give the distance traveled.

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Answer:

Total internal reflection is going on. The refractive index of water is about 1.3, so sin 90/sin r=1/sinr=1.3. So the fish can only see objects outside the water within about 50 degrees of the vertical

I examine the same second hand on the clock. Again, there are two points called A and B on the clock, with A farther from the center than B. "The angular acceleration for both points is 0" is true.

Answer: Option C

Explanation:

The clock is in rotator motion. All the three hands of clock, move in same direction, but different speeds. And hence, we count hours, minutes and seconds.  And, when we take each hand, they move related to the centre of the clock, where all the three are attached.

So, there is a centripetal acceleration which depends upon the velocity.  But, the motion is uniform everywhere in the circle. The hands have no tangential acceleration. And hence, there is no angular acceleration, which is derived from tangential one. So, at any point, the angular acceleration is zero.

Answer:

the heat released by the magnesium is 72 kJ

Explanation:

the heat exchanged will be

Q = m*c*(T final - T initial)  

where Q= heat released, c= specific heat capacity, T initial= initial temperature of water, T final = final temperature of water

Assuming the specific heat capacity of water as c= 1 cal/g°C=4.186 J/g°C

replacing values

Q = m * c* (T final - T initial) = 1910 g * 4.186 J/g°C*(33.10 °C - 24°C) =  72 kJ

Answer:

 i = 0.3326 L

Explanation:

A fixed string at both ends presents a phenomenon of standing waves, two waves with the same frequency that are added together. The expression to describe these waves is

    2 L = n λ           n = 1, 2, 3…

The first harmonic or leather for n = 1

Wave speed is related to wavelength and frequency

     v = λ f

     λ = v / f

Let's replace in the first equation

    2 L = 1 (v / f₁)

For the shortest length L = L-l

   2 (L- l) = 1 (v / f₂)

These two equations form our equation system, let's eliminate v

    v = 2L f₁

    v = 2 (L-l) f₂

    2L f₁ = 2 (L-l) f₂

    L- l = L f₁ / f₂

    l = L - L f₁ / f₂

    l = L (1- f₁ / f₂)

.

Let's calculate

    l / L = (1- 309/463)

    i / L = 0.3326

Answer:

T_t = Ts  (1-A[tex])^{1/4}[/tex] √ (Rs/D)

Explanation:

The black body radiation power is given by Stefan's law

       P = σ A e T⁴

This power is distributed over a spherical surface, so the intensity of the radiation is

     I = P / A

Let's apply these formulas to our case. Let's start by calculating the power emitted by the Sun, which has an emissivity of one (e = 1) black body

    P_s = σ A_s 1 T_s⁴

This power is distributed in a given area, the intensity that reaches the earth is

     I = P_s / A

    A = 4π R²

The distance from the Sun Earth is R = D

     I₁ = Ps / 4π D²

     I₁ = σ (π R_s²) T_s⁴ / 4π D²

     I₁ = σ T_s⁴ R_s² / 4D²

Now let's calculate the power emitted by the earth

     P_t = σ A_t (e) T_t⁴

     I₂ = P_t / A_t

     I₂ = P_t / 4π R_t²2

     I₂ = σ (π R_t²) T_t⁴ / 4π R_t²2

     I₂ = σ T_t⁴ / 4

The thermal equilibrium occurs when the emission of the earth is equal to the absorbed energy, the radiation affects less the reflected one is equal to the emitted radiation

     I₁ - A I₁ = I₂

     I₁ (1 - A) = I₂

Let's replace

    σ T_s⁴  R_s²/4D²   (1-A)  = σ T_t⁴ / 4

    T_s⁴ R_s² /D²   (1-A) = T_t⁴

    T_t⁴ = T_s⁴  (1-A)  (Rs / D) 2

    T_t = Ts  (1-A[tex])^{1/4}[/tex] √ (Rs/D)

Answer:

[tex]\dfrac{F}{l}=2\times 10^{-7}\ N/m[/tex]

Explanation:

It is given that,

Distance between two infinitely long wires, d = 1 m

Current flowing in both of the wires, I = 1 A

The magnetic field in a wire is given by :

[tex]B=\dfrac{\mu_oI}{2\pi d}[/tex]

The force per unit length acting on the two infinitely long wires is given by :

[tex]\dfrac{F}{l}=\dfrac{\mu_o I_1I_2}{2\pi d}[/tex]

[tex]\dfrac{F}{l}=\dfrac{4\pi \times 10^{-7}\times 1^2}{2\pi \times 1}[/tex]

[tex]\dfrac{F}{l}=2\times 10^{-7}\ N/m[/tex]

So, the force acting on the parallel wires is [tex]2\times 10^{-7}\ N/m[/tex]. Hence, this is the required solution.

The force per unit length between the two wires is [tex]\( 2 \times 10^{-7} \)[/tex] newtons per meter.

The force per unit length (F/L) between two infinitely long wires carrying current can be calculated using Ampere force law, which is given by:

[tex]\[ \frac{F}{L} = \frac{\mu_0 I_1 I_2}{2 \pi r} \][/tex]

 Plugging in the values, we get:

[tex]\[ \frac{F}{L} = \frac{(4\pi \times 10^{-7} \text{ N/A}^2) \times (1 \text{ A}) \times (1 \text{ A})}{2 \pi \times (1 \text{ m})} \][/tex]

Simplifying the expression by canceling out [tex]\( \pi \)[/tex] and multiplying the numerical values, we have:

[tex]\[ \frac{F}{L} = \frac{(4 \times 10^{-7} \text{ N/A}^2) \times (1 \text{ A})^2}{2 \times (1 \text{ m})} \][/tex]

[tex]\[ \frac{F}{L} = \frac{4 \times 10^{-7} \text{ N}}{2 \text{ m}} \][/tex]

[tex]\[ \frac{F}{L} = 2 \times 10^{-7} \text{ N/m} \][/tex]

 Therefore, the force per unit length between the two wires is [tex]\( 2 \times 10^{-7} \)[/tex] newtons per meter.

The answer is: [tex]2 \times 10^{-7} \text{ N/m}[/tex]

Answer:

20J

Explanation:

Using conservation law of momentum;

since the bodies were at rest, their initial momentum is zero

0 =  M1Vx + M2Vy

- M1Vx = M2Vy where Vx is the final velocity of x after the spring has been release and Vy is final velocity of y and M1 and M2 are the masses of x and y

also M1 = 2/5 M2

substitute M1 into the the equation above

-2/5 M2Vx =  M2Vy

cancel M2 on both side

-2/5Vx =  Vy

comparing the kinetic energy of both x and y

for x K.E = 1/2 M1 Vx²

and y K.E = 1/2M2 Vy²

substitute for M1 = 2/5 M2

K.Ex = 1/2 × 2/5 M2 Vx²

divide  K.Ex / K.Ey = (1/2 × 2/5 M2 Vx²) / 1/2 M2 Vy²

cancel the common terms

K.Ex / K.Ey = (2/5 Vx²) / Vy²

substitute -2/5Vx for Vy

(2/5 Vx²) / ( -2/5 Vx)² = (2/5 Vx²) / ( 4/25 Vx²)

cancel Vx²

(2/5) / (4/25) = 2/5 ÷ 4/25 = 2/5 × 25/4 = 5/2

the ratio of x and y kinetic energy is 5:2

since the kinetic energy of x is 50

50 : 20 = 5 : 2 if 10 is used to divide both sides

the kinetic energy of y = 20 J

Final answer:

The kinetic energy of object Y is 312.5 J.

Explanation:

The kinetic energy of an object is given by the equation KE = 1/2 mv^2, where m is the mass of the object and v is its velocity. Since object X has a kinetic energy of 50 J, we can use this equation to find the velocity of X. Rearranging the equation, we have v = sqrt(2KE/m). Plugging in the values, we get v = sqrt(2*50 / (2/5)m) = sqrt(500/m).

Since object Y has a mass that is 2/5 times the mass of X, its mass is (2/5)m. Therefore, its velocity can be calculated as v = sqrt(500 / (2/5)m) = sqrt(1250/m).

To find the kinetic energy of Y, we use the formula KE = 1/2 mv^2. Plugging in the mass of Y and its velocity, we get KE = 1/2 ((2/5)m) (sqrt(1250/m))^2 = 1/2 (5/10) m (1250/m) = 1/2 * (5/10) * 1250 = 312.5 J.

Answer:

a) Fh = 25.23 N

b) The direction of the force exerted by the hand is pointed to the downward (negative) direction.

c) Fs = 37.97 N

d) The direction of the force exerted by the shoulder is pointed to the upward (positive) direction.

Explanation:

Given data

Distance from the small end of the bat to the shoulder: d = 23.5 cm

Distance from the small end of the bat to the center of mass: r = 70.0 cm

Mass of the bat: m = 1.30 Kg

This situation can be seen in the pic.

a) We can apply

∑τA = 0   ⇒  + (23.5cm)*Fh - (70 - 23.5)cm*m*g = 0

⇒   + (23.5cm)*Fh - (70 - 23.5)cm*(1.30 Kg)*(9.8 m/s²) = 0

⇒   Fh = 25.23 N (↓)

b) The direction of the force exerted by the hand is pointed to the downward (negative) direction.

c) We apply

∑Fy = 0  (↑)

⇒      - Fh + Fs - m*g = 0

⇒     Fs = Fh + m*g

⇒     Fs = 25.23 N + (1.30 Kg)*(9.8 m/s²)

⇒     Fs = 37.97 N (↑)

d) The direction of the force exerted by the shoulder is pointed to the upward (positive) direction.

Answer:

(a) [tex]2.26\times 10^{13}\ N/C.s[/tex]

(b) 5 A

Solution:

As per the question:

Radius of the circular plate, R = 9 cm = 0.09 m

Distance, d = 2.0 mm = [tex]2.0\times 10^{- 3}\ m[/tex]

At [tex]t_{1}[/tex], current, I = 5 A

Now,

Area, A = [tex]\pi R^{2} = \pi 0.09^{2} = 0.025[/tex]

We know that the capacitance of the parallel plate capacitor, C = [tex]\frac{\epsilon_{o} A}{d}[/tex]

Also,

[tex]q = CV[/tex]

[tex]q = \frac{\epsilon A}{d}V[/tex]

Also,

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

Now,

(a) The rate of change of electric field:

[tex]\frac{dE}{dt} = \frac{dq}{dt}(\frac{1}{A\epsilon_{o}})[/tex]

where

[tex]I = \frac{dq}{dt} = 5\ A[/tex]

[tex]\frac{dE}{dt} = 5\times (\frac{1}{0.025\times 8.85\times 10^{- 12}}) = 2.26\times 10^{13}\ N/C.s[/tex]

(b) To calculate the displacement current:

[tex]I_{D} = epsilon_{o}\times \frac{d\phi}{dt}[/tex]

where

[tex]\frac{d\phi}{dt}[/tex] = Rate of change of flux

[tex]I_{D} = Aepsilon_{o}\times \frac{dE}{dt}[/tex]

[tex]I_{D} = 0.025\times 8.85\times 10^{- 12}\times 2.26\times 10^{13} = 5\ A[/tex]

To develop this problem it is necessary to apply the concepts related to the Dopler effect.

The equation is defined by

[tex]f_i = f_0 \frac{c}{c+v}[/tex]

Where

[tex]f_h[/tex]= Approaching velocities

[tex]f_i[/tex]= Receding velocities

c = Speed of sound

v = Emitter speed

And

[tex]f_h = f_0 \frac{c}{c+v}[/tex]

Therefore using the values given we can find the velocity through,

[tex]\frac{f_h}{f_0}=\frac{c-v}{c+v}[/tex]

[tex]v = c(\frac{f_h-f_i}{f_h+f_i})[/tex]

Assuming the ratio above, we can use any f_h and f_i with the ratio 2.4 to 1

[tex]v = 353(\frac{2.4-1}{2.4+1})[/tex]

[tex]v = 145.35m/s[/tex]

Therefore the cars goes to 145.3m/s