Based on the stability classification, if, over the airport, rising air reaches the point of saturation below 3000 m, it is likely that:_______

Answer:

a) The heavier piece has a translational kinetic energy of 4647.857 joules, b) The lighter piece has a translational kinetic energy of 2582.143 joules.

Explanation:

a) The object breaking can be described by means of the Principle of Energy Conservation, knowing that heavier piece has 1.8 times the mass of the lighter ([tex]m_{h} = 1.8\cdot m_{l}[/tex]), both are modelled as particle due to the absence of rotation and that energy liberated by explosion is transform into kinetic energy, the equation that describes the phenomenon is:

[tex]E_{ex} = K_{h} + K_{l}[/tex]

Where:

[tex]E_{ex}[/tex] - Energy liberated by the explosion, measured in joules.

[tex]K_{h}[/tex], [tex]K_{l}[/tex] - Translational kinetic energies of the heavier and lighter piece, respectively.

This expression is expanded by using the definition of translational kinetic energy and supposing the both parts are liberated at the same initial speed ([tex]v_{o}[/tex]). Then:

[tex]E_{ex} = \frac{1}{2}\cdot (m_{h} + m_{l})\cdot v_{o}^{2}[/tex]

As can be seen, the energy liberated by expression is directly proportional to the mass of the system. Hence, the kinetic energy can be estimated by simple rule of three:

[tex]K_{h} = \frac{m_{h}}{m_{h}+m_{l}}\times E_{ex}[/tex]

If [tex]m_{h} = 1.8\cdot m_{l}[/tex] and [tex]E_{ex} = 7230\,J[/tex], then:

[tex]K_{h} =\frac{1.8\cdot m_{l}}{2.8\cdot m_{l}}\times E_{ex}[/tex]

[tex]K_{h} = \frac{9}{14}\cdot (7230\,J)[/tex]

[tex]K_{h} = 4647.857\,J[/tex]

The heavier piece has a translational kinetic energy of 4647.857 joules.

b) The translational kinetic energy of the lighter piece is calculated by using the equation derived from the Principle of Energy Conservation:

[tex]K_{l} = E_{ex} - K_{h}[/tex]

Given that [tex]E_{ex} = 7230\,J[/tex] and [tex]K_{h} = 4647.857\,J[/tex], the translational kinetic energy of the lighter piece is:

[tex]K_{l} = 7230\,J - 4647.857\,J[/tex]

[tex]K_{l} = 2582.143\,J[/tex]

The lighter piece has a translational kinetic energy of 2582.143 joules.

Answer:

The force is  [tex]F = 784 \ N[/tex]

Explanation:

From the question we are told that

      The mass of the man is  [tex]m = 70 \ kg[/tex]

      The mass of the beam is [tex]m_b = 10 \ kg[/tex]

Now from the question we can deduce that when this beam start to tip that both the force exerted by the weight of the man and that of the beam is been supported by the  right support so

 The force exerted on the right support is mathematically evaluated as

           [tex]F = (m + m_b) * g[/tex]

substituting values

         [tex]F = (70 + 10 ) * 9.8[/tex]

         [tex]F = 784 \ N[/tex]

The force exerted on the beam by the right support is 784 Newton.

Given the data in the question;

Force exerted on the beam by the right support; [tex]F = W = \ ?[/tex]

When the beam just starts to tip, the right support holds up the combined mass of the man and the beam.

Hence;

[tex]M_{net} = m_m + m_b\\\\M_{net} = 70kg + 10kg\\\\M_{net} = 80kg[/tex]

Now, To determine the force exerted on the beam by the right support, we use the general formula for weight or equation of force of gravity which is expressed as:

[tex]F = W = m * g[/tex]

Where m is mass and g represents the acceleration due to gravity( [tex]9.8m/s^2[/tex] )

We substitute our values into the equation

[tex]F = 80kg * 9.8m/s^2\\\\F = 784kg.m/s^2\\\\F = 784N[/tex]

Therefore, the force exerted on the beam by the right support is 784 Newton.

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Answer:

Option A. 11

Explanation:

The atomic number of an element does not change.

Recall:

Atomic number = proton number

If the atom is neutral, then,

Proton number = electron number

Since the element is sodium, then, the atomic number of sodium–25 is 11.

Also, we were told to obtain the electrons of a neutral atom of sodium–25

Therefore,

Atomic number = proton number = 11

Since the atom is neutral,

Proton number = electron number = 11

Answer:

A. 11

Explanation:

A neutral atom of sodium-25 has the same number of protons and electrons. Since it has 11 protons, it also must have 11 electrons!

Answer:

Torque τ =w ×0 = 0

Explanation:

We know that the torque is given by the product of the force and perpendicular distance between the force and the axis.

Here the gravity force act at the center and the rotational axis is also passing through the center.

Therefore the perpendicular distance between the force and the rotational axis would be zero.

Hence the torque will be

Torque = Force × Perpendicular distance

Torque = mg×0 = 0

Therefore the torque would be zero.

following are the response to the given question:

Calculating the torque:

[tex]\text{= Force} \times \text{Perpendicular distance}[/tex]

Therefore, the final torque would be '0'.

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Answer:

The  wavelength is [tex]\lambda_ 1 = 574.2 nm[/tex]

Explanation:

From the question we are told that  

      The  thickness is [tex]t = 198 nm = 198 *10^{-9 }\ m[/tex]

      The refractive  index of the non-reflective coating is  [tex]n_m = 1.45[/tex]  

       The  refractive  index of glass is [tex]n_g = 1.50[/tex]

Generally the condition for  destructive  interference is mathematically represented as

            [tex]2 * n_m * t * cos (\theta) = n * \lambda[/tex]

Where [tex]\thata[/tex] [tex]\theta[/tex] is the angle of refraction which is  0° when the light is strongly transmitted

    and  n is the order maximum interference

        so  

             [tex]\lambda = \frac{2 * n * t * cos (\theta )}{n}[/tex]

at the point n =  1  

           [tex]\lambda _1 = \frac{2 * 1.45 * 198*10^{-9} * cos (0 )}{1}[/tex]

           [tex]\lambda_1 = 574.2 *10^{-9}[/tex]

          [tex]\lambda_1 = 574.2 nm[/tex]

at  n =2  

         [tex]\lambda _2 = \frac{\lambda _1 }{2}[/tex]

         [tex]\lambda _2 = \frac{574.2*10^{-9} }{2}[/tex]

         [tex]\lambda _2 = 2.87 1 *10^{-9} \ m[/tex]

         [tex]\lambda _2 = 287. 1 nm[/tex]

Now we know that the wavelength range of visible light is  between

           [tex]390 \ nm \to 700 \ nm[/tex]

   So the wavelength of visible light that is been transmitted is  

          [tex]\lambda_ 1 = 574.2 nm[/tex]

Answer:

-   λ = 31.89

-   f = 110.29Hz

-   Ф = 2.39

Explanation:

You have the following waveform expression:

[tex]y(x,t)=ym\ sin(2.39+693t+0.197x)[/tex]      (1)

The general expression for a wave can be written as:

[tex]y(x,t)=y_o\ sin(kx\pm \omega t+\phi)[/tex]          (2)

The sign of the term wt determines the direction of the motion of the wave.

In comparison with the equation (1) you have:

k: wavenumber = 0.197

w: angular frequency = 693

Ф: phase constant of the wave = 2.39

- The wavelength of the wave is given by the following formula:

[tex]\lambda=\frac{2\pi}{k}=\frac{2\pi}{0.197}=31.89m[/tex]

The wavelength of the wave is 31.89m

- The frequency is:

[tex]f=\frac{\omega}{2\pi}=\frac{693}{2\pi}=110.29Hz[/tex]

The frequency of the wave is 110.29Hz

- The phase constant is 2.39

Answer:

El trabajo realizado por la fuerza de rozamiento sobre el bloque tras recorrer este último una distancia de 5 metros sobre el plano es de 500.566 joules.

Explanation:

El fenómeno alrededor del bloque puede ser modelado por el Principio de Conservación de la Energía y el Teorema del Trabajo y la Energía. Al descender lentamente, significa que la aceleración neta experimentada por el bloque es aproximadamente cero. El diagrama de cuerpo libre del bloque se presenta a continuación como archivo adjunto. Las ecuaciones de equilbrio del sistema son:

[tex]\Sigma F_{x'} = P\cdot \cos \theta + m\cdot g \cdot \sin \theta - f = 0[/tex]

[tex]\Sigma F_{y'} = N + P\cdot \sin \theta -m\cdot g\cdot \cos \theta = 0[/tex]

Donde:

[tex]P[/tex] - Fuerza externa aplicada a la caja, medida en newtons.

[tex]m[/tex] - Masa del bloque, medida en kilogramos.

[tex]g[/tex] - Aceleración gravitacional, medidas en metros sobre segundo al cuadrado.

[tex]f[/tex] - Fuerza de rozamiento, medida en newtons.

[tex]N[/tex] - Fuerza normal del plano sobre la caja, medida en newtons.

[tex]\theta[/tex] - Ángulo de inclinación del plano, medido en grados sexagesimales.

Dado que todas las fuerzas son constantes, se puede emplear la definición de trabajo como el producto de la fuerza paralela a la dirección del movimiento y la magnitud de distancia recorrida en el movimiento, entonces la primera ecuación de equilibrio queda así al multiplicar cada lado por la distancia recorrida:

[tex]P\cdot \Delta s \cdot \cos \theta + m\cdot g \cdot \Delta s \cdot \sin \theta - W_{f} = 0[/tex]

Ahora, la cantidad de trabajo realizado por la fuerza de rozamiento es:

[tex]W_{f} = (P\cdot \cos \theta+m\cdot g\cdot \sin \theta)\cdot \Delta s[/tex]

Si [tex]P = 50\,N[/tex], [tex]m = 10\,kg[/tex], [tex]g = 10\,\frac{m}{s^{2}}[/tex], [tex]\theta = 37^{\circ}[/tex] and [tex]\Delta s = 5\,m[/tex], entonces el trabajo realizado por la fuerza de rozamiento es:

[tex]W_{f} = \left[(50\,N)\cdot \cos 37^{\circ}+(10\,kg)\cdot \left(10\,\frac{m}{s^{2}} \right)\cdot \sin 37^{\circ}\right]\cdot (5\,m)[/tex]

[tex]W_{f} = 500.566\,J[/tex]

El trabajo realizado por la fuerza de rozamiento sobre el bloque tras recorrer este último una distancia de 5 metros sobre el plano es de 500.566 joules.

Answer:

540C.

Explanation:

A capacitor of capacitance C when charged to a voltage of V will have a charge Q given as follows;

Q = CV          ----------(i)

From the question, the initial charge on the capacitor is the charge on it before it was connected to the resistor. In other words, the initial charge on the capacitor will have a maximum value which can be calculated using equation (i) above.

Where;

C = 6F

V = 90V

Substitute these values into equation (i) as follows;

Q = 6 x 90

Q = 540 C

Therefore, the initial charge on the capacitor is 540C.

Answer:

[tex]$ \phi_{21} = \frac{\phi_{12}}{2} $[/tex]

Which means that the flux through each loop of the second coil is half as much as flux through each loop of first coil.

Explanation:

The flux through each loop of the first coil due to current in the second coil is,

[tex]\phi_{12} = \phi[/tex]

The number of loops in the first coil is

no. of loops = 2N

Total flux passing through the first coil is

[tex]\phi_{12} = 2N\phi[/tex]

The flux through each loop of the second coil due to current in the first coil is,

[tex]\phi_{21} = \phi[/tex]

The number of loops in the second coil is

no. of loops = N

Total flux passing through the second coil is

[tex]\phi_{21} = N\phi[/tex]

Comparing both

[tex]\phi_{12} = \phi_{21} \\\\ 2N\phi = N\phi\\\\\phi_{21} = \frac{\phi_{12}}{2}[/tex]

Which means that the flux through each loop of the second coil is half as much as flux through each loop of first coil.

Answer:

The transmitted intensity is   [tex]I = 40 \ W/m^2[/tex]

Explanation:

From the question we are told that

     The intensity of the unpolarized  light  [tex]I_o = 80 \ W /m^2[/tex]

Generally for a single filter the transmitted intensity of light  is mathematically evaluated as

           [tex]I = \frac{I_o}{2}[/tex]

substituting values

          [tex]I = \frac{80}{2}[/tex]

          [tex]I = 40 \ W/m^2[/tex]

Answer:

The study of charges in motion and their  interaction with magnetic fields is known as electromagnetism.

Any material with an unequal number of  electrons and or protons could generally be  termed as ion.

Explanation:

i hope this will help you :)

Answer:

The air-water interface is an example of boundary. The transmitted portion of the initial wave energy is way smaller than the reflected portion. This makes the boundary  wave hard to hear.

When both the source of the sound and your ears are located underwater, the sound is louder because the sound waves can travel directly to your ear.

Explanation:

The air-to-water sound wave transmission is inhibited because more of reflection than transmission of the wave occurs at the boundary. In the end, only about 30% of the sound wave eventually reaches underwater. For sound generated underwater, all the wave energy is transmitted directly to the observer. Sound wave travel faster in water than in air because, the molecules of water are more densely packed together, and hence can easily transmit their vibration to their neighboring molecules, when compared to air.

Answer: The air-water interface is an example of boundary. The (transmitted) portion of the initial wave is way smaller than the (reflected) portion. This makes the (transmitted) wave hard to hear.

When both the source of the sound and your ears are located underwater, the sound is louder because the sound waves can (travel directly to your ears.)

Explanation:

The part of the sound wave that is transmitted across the boundary between air and water is much smaller than the part of the wave that is reflected. This is what makes it hard to hear your friend knocking two rocks together above the surface.

When you and the rocks are underwater, the sound that comes from knocking the rocks together can travel directly to your ears rather than having to be transmitted across mediums.

Centripetal acceleration = (speed squared) / (radius)

Centripetal acceleration = (10 m/s)² / (1.0 m)

Centripetal acceleration = (100 m²/s²) / (1.0 m)

Centripetal acceleration = 100 m/s²

Answer:

The angular speed (in rev/s) when her arms and one leg open outward is 1.161 rev/s

Explanation:

Given;

moment of inertia of a skater with arms out, [tex]I_{arms \ out}[/tex] = 3.1 kg.m²

moment of inertia of a skater with arms in, [tex]I_{arms \ in}[/tex] = 0.9 kg.m²

inward angular speed, [tex]\omega _{in}[/tex] = 4 rev/s

The angular momentum of the skater when her arms are out and one leg extended is equal to her angular momentum when her arms and legs are in.

[tex]L_{out} = L_{in}[/tex]

[tex]I_{out} \omega_{out} = I_{in} \omega_{in}\\\\\omega_{out} = \frac{ I_{in} \omega_{in} }{I_{out} } \\\\\omega_{out} = \frac{0.9*4}{3.1} \\\\\omega_{out} = 1.161 \ rev/s[/tex]

Therefore, the angular speed (in rev/s) when her arms and one leg open outward is 1.161 rev/s

Answer:

large

Explanation:

Cumulus clouds is a term in metrology that defines the type of clouds which are characterized by its low altitude, puffy appearance, and fair-weather nature. They are generally considered as low-level clouds, with less than than 2,000m in altitude except they are the more vertical cumulus congestus form.

Thus, it can be noted that, the difference between the surface dew point temperature and the surface temperature is related to relative humidity. Hence, in a situation when there is a LARGE difference between the surface temperature and the surface dewpoint temperature, then the relative humidity is very low (e.g., 10%).

Therefore, the bases of developing convective cumulus clouds will be relatively higher at a location with a relatively LARGE difference between the surface temperature and surface dew point temperature.

Answer:

The excess charge is [tex]Q = 3.5 *10^{-7} \ C[/tex]

Explanation:

From the question we are told that

      The diameter is [tex]d = 45 \ cm = 0.45 \ m[/tex]

       The potential of the surface is [tex]V = 14 \ kV = 14 *10^{3} \ V[/tex]

The radius of the sphere is  

           [tex]r = \frac{d}{2}[/tex]

substituting values

          [tex]r = \frac{0.45}{2}[/tex]

         [tex]r = 0.225 \ m[/tex]

The potential on the surface is mathematically represented as  

          [tex]V = \frac{k * Q }{r }[/tex]

Where k is coulomb's constant with value  [tex]k = 9*10^{9} \ kg\cdot m^3\cdot s^{-4} \cdot A^{-2}.[/tex]

  given from the question that there is no other charge the Q is the excess charge  

Thus  

        [tex]Q = \frac{V* r}{ k}[/tex]

substituting values

        [tex]Q = \frac{14 *10^{3} 0.225}{ 9*10^9}[/tex]

        [tex]Q = 3.5 *10^{-7} \ C[/tex]

Answer:

Time needed for one revolution is 0.38 s

Explanation:

The formula for the frequency of rotation of a spaceship, to create the desired artificial gravity, is as follows:

f = (1/2π)√(a/r)

where,

f = frequency of rotation = ?

a = artificial gravity required = 0.5 g

g = acceleration due to gravity on surface of Earth = 9.8 m/s²

r = radius of ship = 35 mm/2 = 17.5 mm = 17.5 x 10⁻³ m

Therefore,

f = (1/2π)√[(0.5)(9.8 m/s₂)/(17.5 x 10⁻³ m)]

f = 2.66 Hz

Now, for the time required for one revolution, is given as:

Time Period = T = 1/f

T = 1/2.66 Hz

T = 0.38 s

The time required for one revolution to simulate the desired gravity is 0.38 s.

The frequency can be calculate by the formula

[tex]\bold {f = (\dfrac {1}{2\pi})\sqrt{ar}}[/tex]

where,

f - frequency of rotation = ?

a-  artificial gravity required = 0.5 g

g -  gravitational acceleration on surface of Earth = 9.8 m/s²

r -  radius of ship = 35 mm/2 = 17.5 mm = 17.5 x 10⁻³ m

Put the value in the equation,

[tex]\bold {f = \dfrac {1}{2\pi}\squrt {(0.5)(9.8\ m/s^2)}{(17.5 x 10^{-3} m)}}\\\\\bold {f = 2.66\ Hz}[/tex]

the time required for one revolution can be calculated as

[tex]\bold {T =\dfrac 1f}\\\\\bold {T = \dfrac 1{2.66}\ Hz}\\\\\bold {T = 0.38\ s}[/tex]

Therefore, the time required for one revolution to simulate the desired gravity is 0.38 s.

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Answer:

c.  [tex]|F_T|=8\frac{Gm^2}{d^2}[/tex]

Explanation:

In order to calculate the gravitational force on the mass of the center, you take into account the following formula:

[tex]F=G\frac{m_1m_2}{r}[/tex]         (1)

Furthermore, you take into account the components of the resultant vector.

By the illustration, you have that the force is given by:

[tex]F_T=F_1+F_2+F_3+F_4\\\\F_1=\frac{Gm_1m}{r^2}[-cos45\°\hat{i}+sin45\°\hat{j}]\\\\F_2=\frac{Gm_2m}{r^2}[cos45\°\hat{i}+sin45\°\hat{j}]\\\\F_3=\frac{Gm_3m}{r^2}[cos45\°\hat{i}-sin45\°\hat{j}]\\\\F_4=\frac{Gm_4m}{r^2}[-cos45\°\hat{i}-sin45\°\hat{j}][/tex]

where:

m1 = m

m2 = 2m

m3 = m

m4 = 4m

m: mass at the center of the system

The distance r is:

[tex]r=\sqrt{(\frac{d}{2})^2+(\frac{d}{2})^2}=\frac{d}{\sqrt{2}}[/tex]

You replace the values for all masses and sum the contributions of all forces:

[tex]F_1=\frac{\sqrt{2}}{2}\frac{Gm^2}{(\frac{d^2}{2})}[-\hat{i}+\hat{j}]=\sqrt{2}\frac{Gm^2}{d^2}[-\hat{i}+\hat{j}]\\\\F_2=\frac{\sqrt{2}}{2}\frac{2Gm^2}{(\frac{d^2}{2})}[\hat{i}+\hat{j}]=2\sqrt{2}\frac{Gm^2}{d^2}[\hat{i}+\hat{j}]\\\\F_3=\frac{\sqrt{2}}{2}\frac{Gm^2}{(\frac{d^2}{2})}[\hat{i}-\hat{j}]=\sqrt{2}\frac{Gm^2}{s^2}[\hat{i}-\hat{j}]\\\\F_4=\frac{\sqrt{2}}{2}\frac{4Gm^2}{(\frac{d^2}{2})}[-\hat{i}-\hat{j}]=4\sqrt{2}\frac{Gm^2}{d^2}[-\hat{i}-\hat{j}]\\\\F_T=-2\sqrt{2}\frac{Gm^2}{d^2}}[\hat{i}+\hat{j}][/tex]

and the magnitude is:

c.  [tex]|F_T|=8\frac{Gm^2}{d^2}[/tex]

Answer:

a) 1.95 V

b) 1.87 mA

c) 0.115 A

Explanation:

Given that

Number of primary turns, N(p) = 480

Number of secondary turns, N(s) = 7.8

Velocity of primary turns, V(p) = 120 V

Velocity of secondary turns, V(s) = ?

Current in the primary, I(p) = ?

Current in the secondary, I(s) ?

To solve this question, we would be using the formula

V(s)/V(p) = N(s)/N(s), now substituting the values, we have

V(s) / 120 = 7.8 / 480

V(s) = (7.8 * 120) / 480

V(s) = 936 / 480

V(s) = 1.95 V

To find the current in the primary, remember ohms law?

I = V/R

I(s) = V(s) / R(s)

I(s) = 1.95 / 17

I(s) = 0.115 A

Now, remember the relationship between current and voltage

I(p)/I(s) = V(s)/V(p)

I(p) / 0.115 = 1.95 / 120

I(p) = (1.95 * 0.115) / 120

I(p) = 0.22425 / 120

I(p) = 0.00187 A

I(p) = 1.87 mA

Answer:

D

Explanation:

W = P∆V

Use the above equation and substitute, thanks

Answer:

d. may be either greater, smaller, or equal to that observed inside the bus.

Explanation:

Answer:

Therefore, the answer is E. They strike the plane at the same time.

Explanation:

Here, it is seen that the time depends only on acceleration due to gravity (which is a constant) and vertical displacement, and not on velocity of the bullets or mass of the bullets.

Hence, the bullets that are fired simultaneously parallel to the horizontal plane will strike the plane at the same time.

using equation of motion for displacement

s= ut + ¹/₂gt²

here, g is the acceleration due to gravity along y- direction

U along y is 0

s = (0)t + ¹/₂gt²

s=¹/₂gt²

make t the subject of formula =  [tex]\sqrt{\frac{2s}{g} }[/tex]

Explanation:

a)

θ = 4.91 + 9.7t + 2.06t² when t = 0

θ = 4.91 rad

θ = 4.91 + 9.7t + 2.06t²

ω = dθ/dt = 9.7 + 2.06t, when t =0

ω = dθ/dt = 9.7 + 0

ω = 9.7 rad/s

α = d²θ/dt² = 2.06

α= 2.06 rad/s²

b) please use same method above for t = 2.94 s

At zero seconds, the angular position is 4.91 rad, the angular velocity is  9.7 radian/second and the angular acceleration is 2.06 rad/s².

When the angular velocity change in relation to time, then it results in angular acceleration. It comes with direction, so it is a vector quantity.

Given: Angular position equation (θ) = 4.91 + 9.7t + 2.06[tex]t^{2}[/tex]

If the angular velocity is ω, angular acceleration is α, and t is the time then

(A) At time t = 0 second

θ = 4.91 + 9.7 × 0 + 2.06 × [tex]0^{2}[/tex]

θ = 4.91 rad

Angular velocity (ω) = dθ/dt

ω = dθ/dt,

ω = 9.7 + 2.06t   (at t = 0)

ω = 9.7 radian/second

Angular acceleration (α) = d²θ/dt²

α= 2.06 rad/s²

Similarly, at t= 2.94 sec

θ = 51.23 rad

ω = 15.76 rad/s

α = 2.06 rad/s²


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Answer:

The work done by the force is 820.745 joules.

Explanation:

Let suppose that changes in potential energy can be neglected. According to the Work-Energy Theorem, an external conservative force generates a change in the state of motion of the object, that is a change in kinetic energy. This phenomenon is describe by the following mathematical model:

[tex]K_{1} + W_{F} = K_{2}[/tex]

Where:

[tex]W_{F}[/tex] - Work done by the external force, measured in joules.

[tex]K_{1}[/tex], [tex]K_{2}[/tex] - Translational potential energy, measured in joules.

The work done by the external force is now cleared within:

[tex]W_{F} = K_{2} - K_{1}[/tex]

After using the definition of translational kinetic energy, the previous expression is now expanded as a function of mass and initial and final speeds of the object:

[tex]W_{F} = \frac{1}{2}\cdot m \cdot (v_{2}^{2}-v_{1}^{2})[/tex]

Where:

[tex]m[/tex] - Mass of the object, measured in kilograms.

[tex]v_{1}[/tex], [tex]v_{2}[/tex] - Initial and final speeds of the object, measured in meters per second.

Now, each speed is the magnitude of respective velocity vector:

Initial velocity

[tex]v_{1} = \sqrt{v_{1,x}^{2}+v_{1,y}^{2}}[/tex]

[tex]v_{1} = \sqrt{\left(12\,\frac{m}{s} \right)^{2}+\left(22\,\frac{m}{s} \right)^{2}}[/tex]

[tex]v_{1} \approx 25.060\,\frac{m}{s}[/tex]

Final velocity

[tex]v_{2} = \sqrt{v_{2,x}^{2}+v_{2,y}^{2}}[/tex]

[tex]v_{2} = \sqrt{\left(16\,\frac{m}{s} \right)^{2}+\left(29\,\frac{m}{s} \right)^{2}}[/tex]

[tex]v_{2} \approx 33.121\,\frac{m}{s}[/tex]

Finally, if [tex]m = 3.5\,kg[/tex], [tex]v_{1} \approx 25.060\,\frac{m}{s}[/tex] and [tex]v_{2} \approx 33.121\,\frac{m}{s}[/tex], then the work done by the force is:

[tex]W_{F} = \frac{1}{2}\cdot (3.5\,kg)\cdot \left[\left(33.121\,\frac{m}{s} \right)^{2}-\left(25.060\,\frac{m}{s} \right)^{2}\right][/tex]

[tex]W_{F} = 820.745\,J[/tex]

The work done by the force is 820.745 joules.

Answer:

less than

Explanation:

The force of kinetic friction for a particular pair of interacting objects is always less than the force of static friction.

The force of static friction between two surfaces is always higher than the force of kinetic friction.

Answer:

432 J

Explanation:

When moving linearly:

Kinetic Energy = (1/2)mV^2

So here you have:

KE=(1/2)(6)(12^2)=(1/2)(6)(144)=432

The unit for energy is Joules (J), so your answer would be 432 J.

Answer:

A) 8π ft²/ft

B) 24π ft²/ft

C) 48π ft²/ft

Explanation:

Surface area of the spherical balloon is not clear here but it is supposed to be;

S = 4πr²

where:

r is the radius of the spherical balloon

So thus, the rate of change of the surface area of the spherical balloon by its radius will be:

dS/dr = 8πr

A) at r = 1ft;

dS/dr = 8 × π × 1

dS/dr = 8π ft²/ft

B) at r = 3 ft;

dS/dr = 8 × π × 3

dS/dr = 24π ft²/ft

C) at r = 6ft;

dS/dr = 8 × π × 6

dS/dr = 48π ft²/ft

Answer:

a conductor is an object or type of material that allows the flow of charge (electrical current) in one or more directions.

Explanation:

. Materials made of metal are common electrical conductors.

Answer:

The angular momentum of the particle about the origin is [tex]\vec l = -19.305\,k\,\left[kg\cdot \frac{m}{s} \right][/tex].

Explanation:

Vectorially speaking, the angular momentum is given by the following cross product:

[tex]\vec l = \vec r \times m\vec v[/tex]

This cross product can be solved with the help of determinants and its properties, that is:

[tex]\vec l = \left|\begin{array}{ccc}i&j&k\\r_{x}&r_{y}&0\\m\cdot v_{x}&m\cdot v_{y}&0\end{array}\right|[/tex]

[tex]\vec l = m\left|\begin{array}{ccc}i&j&k\\r_{x}&r_{y}&0\\v_{x}& v_{y}&0\end{array}\right|[/tex]

The 3 x 3 determinant is solved by the Sarrus Law:

[tex]\vec l = m \cdot (r_{x}\cdot v_{y} - r_{y}\cdot v_{x})k[/tex]

If [tex]m = 1.30\,kg[/tex], [tex]\vec r = 1.50\,i + 2.20\,j\,[m][/tex] and [tex]\vec v = 4.50\,i-3.30\,j\,\left[\frac{m}{s} \right][/tex], the angular momentum of the particle about the origin is:

[tex]\vec l = (1.30\,kg)\cdot \left[\left(1.50\,m\right)\cdot\left(-3.30\,\frac{m}{s} \right)-\left(2.20\,m\right)\cdot\left(4.50\,\frac{m}{s} \right)\right]k[/tex]

[tex]\vec l = -19.305\,k\,\left[kg\cdot \frac{m}{s} \right][/tex]

The angular momentum of the particle about the origin is [tex]\vec l = -19.305\,k\,\left[kg\cdot \frac{m}{s} \right][/tex].