You are working in the large animal ward at the hospital. You are receiving a horse that needs immediate treatment for dehydration. The vet asks you to calculate the fluid deficit for this horse. He is a 950-pound horse that is about 7% dehydrated. What is his fluid deficit?
A) 63 L
B) 15 L
C) 5 L
D) 30 L

Answer:

0.027m

Explanation:

the bolt loses contact with the piston only when acceleration due to gravity equals acceleration of piston

ω² * A = g where ω is angular velocity, A amplitude, g acceleration due to gravity

ω is given by 2πf, ω² is 4π²f²

A= g/4π²f² depending on the value of g used either 10m/s² or 9.8m/s²,

i used 10m/s² in this answer

Answer:

D. 1/4 lambda

Explanation:

Given:

Initially out of phase speakers by 180°.

Then on being separated by 1.5 λ.

The initial case of speakers being out of phase by 180°

On separating the speakers by a distance of 1.5 λ.

Answer:

Current, I = 3 A

Explanation:

It is given that,

Length of the wire, l = 1 m

Magnetic field acting on the wire, B = 0.2 T

The magnetic force acting on the wire, F = 0.6 N

Let the current flowing through the wire is given by I. The magnetic force acting on an object in the uniform magnetic field is given by :

[tex]F=ILB\ sin\theta[/tex]

Here, [tex]\theta=90^{\circ}[/tex]

[tex]F=ILB[/tex]

[tex]I=\dfrac{F}{LB}[/tex]

[tex]I=\dfrac{0.6\ N}{1\ m\times 0.2\ T}[/tex]

I = 3  A

So, the current flowing through the rod 3 A.

Answer:

 W = 24.28 kN

Explanation:

given,

Mass of satellite = 5850 Kg

height , h = 4.1 x 10⁵ m

Radius of planet = 4.15 x 10⁶ m

Time period = 2 h

                    = 2 x 3600 = 7200 s

Time period of satellite

[tex]T = \dfrac{2\pi}{R}\sqrt{\dfrac{(R+h)^3}{g}}[/tex]

R is the radius of planet

h is the height of satellite

[tex]T^2 = \dfrac{4\pi^2}{R^2}\ {\dfrac{(R+h)^3}{g}}[/tex]

now calculation of acceleration due to gravity

[tex]g = \dfrac{4\pi^2}{R^2}\ {\dfrac{(R+h)^3}{T^2}}[/tex]

[tex]g = \dfrac{4\pi^2}{(4.15\times 10^6)^2}\ {\dfrac{(4.15\times 10^6+4.1\times 10^5)^3}{(7200)^2}}[/tex]

g = 4.15 m/s²

True weight of satellite

W = m g

W = 5850 x 4.15

W = 24277.5 N

 W = 24.28 kN

True weight of the satellite is   W = 24.28 kN

The true weight of the satellite, when the satellite is at rest on the surface of the planet, is 24.28 kN.

Time period of satellites is the total time taken by a satellite to complete a full orbit around a body. It can be given as,

[tex]T=\dfrac{2\pi}{R}\sqrt{\dfrac{(R+h)^3}{g}}[/tex]

Here, (R) is the radius of the body, and (g) is the gravitational acceleration force.

In a circular orbit 4.1 x10 to the 5th power m above the surface of a planet. The period of the orbit is 2 hours and the radius of the planet is 4.15 x 10 to the 6th power m.

To find the weight of the satellite, first find the value of gravitation acceleration using the time period formula as,

[tex]2=\dfrac{4\pi^2}{4.15\times10^6}\sqrt{\dfrac{(4.15\times10^6+4.1\times10^5)^3}{g}}\\g=4.15\rm m/s^2[/tex]

The weight of the body is mass time gravity. As the satellite has a mass of 5850 kg and value of g is 4.15 m/s². Thus, the weight of it is,

[tex]W=5850\times4.15\\W=24277.5\rm N\\W=24.28\rm \; kN[/tex]

Thus, the true weight of the satellite, when the satellite is at rest on the surface of the planet, is 24.28 kN.

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Answer:52.72 L

Explanation:

Given

Energy absorb by system [tex]Q=51 J[/tex]

Piston is working against a pressure of [tex]P=0.545 atm[/tex]

Final volume of system [tex]V_f=55.6 L[/tex]

change in internal Energy [tex]\Delta U=-106 J[/tex]

Work done by system [tex]W=P(V_f-V_i)[/tex]

According to first law of thermodynamics

[tex]Q=dU+PdV[/tex]

[tex]51=-106+W[/tex]

[tex]W=157 J[/tex]

[tex]157=0.545\times 10^5\times 10^{-3}(55.6-V)[/tex]

[tex]157=54.5\times (55.6-V)[/tex]

[tex]55.6-V=2.88[/tex]

[tex]V=52.72 L[/tex]

Answer:

Wavelength, [tex]\lambda=0.011\ m[/tex]

Explanation:

Given that,

Number of cycles in a spiral spring is 2.91 in every 3.67 s

The velocity of the pulse in the spring is 0.925 cm/s, v = 0.00925 m/s

To find,

Wavelength

Solution,

Number of cycles per unit time is called frequency of a wave. The frequency of the longitudinal pulse is,

[tex]f=\dfrac{2.91}{3.67}=0.79\ Hz[/tex]

The wavelength of a wave is given by :

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

[tex]\lambda=\dfrac{0.00925\ m/s}{0.79\ Hz}[/tex]

[tex]\lambda=0.011\ m[/tex]

So, the wavelength of the longitudinal pulse is 0.011 meters. Hence, this is the required solution.

To find the wavelength, the frequency is calculated by dividing the number of cycles by the total time. The velocity is then converted from cm/s to m/s. The wavelength is calculated using these values in the equation for wave speed to get approximately 0.012 meters.

In the scenario described in your question, your hand completes 2.91 back-and-forth cycles every 3.67 seconds, resulting in longitudinal pulses in a spiral spring. Here, we have frequency and wave velocity, and we need to find the wavelength. We can determine the frequency by dividing the number of cycles by the total time and the wavelength using the formula for wave speed: v = fλ, where v is the velocity, f is the frequency, and λ is the wavelength.

Frequency (f) = number of cycles / total time = 2.91 cycles / 3.67 s = 0.793 Hz

Velocity (v) = 0.925 cm/s = 0.00925 m/s (since we need the answer in meters)

To find the wavelength, we can use the formula v = fλ, to rearrange this to solve for λ, we get λ = v/f. So, λ = 0.00925 m/s / 0.793 Hz = 0.01166 meters or approximately 0.012 meters.

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Final answer:

The speed of an object of mass m when it hits the planet's surface after being dropped from height h is found by using the conservation of energy, yielding the formula v = √[2GM(1/R - 1/(R+h))] where G is the gravitational constant, M the planet's mass, and R its radius.

Explanation:

To find the speed v of an object of mass m when it hits the surface of a planet, we will use the principles of energy conservation in the context of gravitational fields. The total mechanical energy (potential plus kinetic) at the beginning and at the end must be equal since we are ignoring air resistance and any other non-conservative forces.

The initial potential energy when the object is at height h above the planet is given by the gravitational potential energy formula U = -G(Mm)/(R+h) and the initial kinetic energy is zero as the object is initially at rest. When the object reaches the surface of the planet, its potential energy is U = -G(Mm)/R and its kinetic energy is K = (1/2)m*v^2. Conservation of energy dictates that the initial total energy equals the final total energy:

-G(Mm)/(R+h) = -G(Mm)/R + (1/2)m*v^2

Solving for v, the speed of the object at the planetary surface, we get:

v = √[2GM(1/R - 1/(R+h))]

This expression shows that the object's speed increases with a greater initial height h, a more massive planet M, and decreases with a larger planetary radius R.

Answer:

Air found in the soil is trapped in it and is not exposed to the air currents, poor  in oxygen and rich in moisture.

Explanation:

Air found in the soil is trapped in it and is not exposed to the air currents.

It contains more moisture than the atmospheric air.

It is rich in carbon dioxide and poor in oxygen.

The air found in the soil forms a part of the lithosphere and not the atmosphere.

Nitrogen trapped in the soil is used by the plants to make protein, carbon dioxide is used for the photosynthesis and oxygen is used for the respiration of roots and microorganisms.

Answer:

e. is definitely zero

Explanation:

Given that

At initial condition the speed of the pop cans is zero.

We know that linear momentum

P = Mass x velocity

P =  m v

At initial condition v = 0

P= 0

If there is no any external force then the linear momentum of the system will be conserve.And given that ,consider the system isolated.

Therefore the answer is e.

Answer:

9.49596 m

Explanation:

[tex]\omega_f[/tex] = Final angular velocity = 0

[tex]\omega_i[/tex] = Initial angular velocity = 19 rad/s

[tex]\alpha[/tex] = Angular acceleration = -1.26 rad/s²

[tex]\theta[/tex] = Angle of rotation

Equation of rotational motion

[tex]\omega_f^2-\omega_i^2=2\alpha \theta\\\Rightarrow \theta=\frac{\omega_f^2-\omega_i^2^2}{2\alpha}\\\Rightarrow \theta=\frac{0^2-19^2}{2\times -1.26}\\\Rightarrow \theta=143.25396\ rad[/tex]

Converting to m

[tex]143.25396\times \pi d=143.25396\times \pi\times 0.0211=9.49596\ m[/tex]

The distance the coin rolls before it stops is 9.49596 m

We can calculate the kinetic energy of the ejected electrons in the photoelectric effect by applying the equation KE = hf - BE, where 'KE' is kinetic energy, 'h' is Planck's constant, 'f' is the frequency of the light, and 'BE' is the binding energy or work function of a metal (in this case, titanium).

The photoelectric effect is the process where light of sufficient energy (in this case, frequency) shone on a metal surface can release electrons (photoelectrons). Kinetic energy of these ejected electrons can be calculated according to the equation: KE = hf - BE. Here, 'KE' is the kinetic energy we're striving to find, 'h' is Planck's constant, 'f' is the frequency of the incident light, and 'BE' is the binding energy or work function of the electron.

For titanium metal, you've provided that the work function (BE) is 6.93 × 10⁻¹⁹ J. The frequency ('f') of the light used is 1.216 × 10¹⁵ s⁻¹. And, Planck's constant ('h') approximately equals 6.63 × 10⁻³⁴ Js.

To execute the calculation: KE = (6.63 × 10⁻³⁴ Js x 1.216 × 10¹⁵ s⁻¹) - 6.93 × 10⁻¹⁹ J. The solution will provide your kinetic energy in Joules

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Answer:

Option B

Explanation:

Maintenance-free battery uses Recom­bination Electrolyte in order to limit   the oxygen and hydrogen formation during charging.

Each plate of the battery uses a glass micro-fiber separator that absorbs the whole liquid electrolyte in its pore thus resulting in no free acid.

As the battery charges to its fullest, the oxygen produced at the positive plate moves via the pores of the separator to the negative plate.

Initially it reacts and forms [tex]PbSO_{4}[/tex], i.e., Lead Sulphate, then on further charging it gets converted to Pb, i.e., lead.

Due to this, the negative plate is not able to reach the correct potential in order to liberate hydrogen, and hence no water formation takes place.

Thus technician B is correct.

Answer:

e. Reduced conflict.

Explanation:

Outsourcing is a tool that allows you to hire a provider outside the company for the execution of secondary activities, such as cleaning or mail, or covering other areas of the company, such as financial or accounting systems or the human resources area

- Advantages of Outsourcing

- Cost reduction

- Focus on the main activity

- Transformation of fixed costs into variables

- Reduce risk

- Improve quality

- Productivity increase

- Improve innovation processes

- Greater flexibility

- Access to the latest technologies

- Increase in competitiveness

Advantages of outsourcing project work include increased flexibility, higher level of expertise, and reduced costs.

The advantages of outsourcing project work may likely include increased flexibility because organizations can access a global talent pool and adapt to changing markets. Outsourcing can also provide a higher level of expertise as specialized firms or individuals with specific skills can be hired. Additionally, outsourcing can lead to reduced costs by eliminating the need for in-house resources and infrastructure.

However, one advantage that is unlikely to be associated with outsourcing project work is reduced conflict. When different parties are involved in a project, conflicts may arise due to differences in goals, perspectives, or communication barriers. Outsourcing does not automatically guarantee a reduction in conflict.

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Answer:

405.3m

Explanation:

Since the CD spin rate is 500 rpm, or revolution per minutes, its angular speed in rad per second is

[tex]\omega = 500 rev/min * 2\pi rad/rev * 1/60 min/sec = 52.36 rad/s[/tex]

The dusk is 4.3 cm from center, so its velocity must be

[tex]v = R\omega = 4.3 * 52.36 = 225.14 cm/s[/tex]

Then the distance traveled by the dusk after 3 minutes, or 180 seconds is

[tex]d = v*t = 225.14 * 180 = 40526.54 cm[/tex] or 405.3m

Answer:

0.06683

Explanation:

m = Mass of block = 3.85 kg

g = Acceleration due to gravity = 9.81 m/s²

[tex]\mu[/tex] = Coefficient of kinetic friction

x = Compression of spring = 0.103 m

k = Spring constant = 138 N/m

Work done against friction is given by

[tex]W=m\mu gs\\\Rightarrow W=\mu 3.85\times 9.81\times 0.29\\\Rightarrow W=10.952865\mu[/tex]

The potential energy of the spring is given by

[tex]P=\frac{1}{2}kx^2\\\Rightarrow P=\frac{1}{2}\times 138\times 0.103^2\\\Rightarrow P=0.732021\ J[/tex]

The potential energy and the work done against friction will balance the system

[tex]0.732021=10.952865\mu\\\Rightarrow \mu=\frac{0.732021}{10.952865}\\\Rightarrow \mu=0.06683[/tex]

The coefficient of kinetic friction between the horizontal surface and the block is 0.06683

Wind-driven currents are found NEAR THE SURFACE of the oceans

Explanation:

Surface currents are at the interphase between the hydrosphere and atmosphere. Therefore the feel the greatest effect of drag by wind currents, especially prevailing winds (that blow predominantly in one direction like westerlies and easterlies) within the lower atmosphere.  The deep currents, on the other hand, are more influenced by Coriolis effect of the earth’s rotation. It is these differences in influences of surface and deeper currents that cause Ekman transport in oceans.

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Answer:

The alternative energy sources are defined as those resources that are used in place of the natural and non-renewable resources. This resources plays an important role in the conservation of natural resources.

The fossil fuels are the resources on which the people are directly dependent. Burning up of these fossils leads to the emission of carbon, which has a direct impact on earth. A small increase in the amount of carbon dioxide can lead to the increase in the surface temperature of earth.

In addition to this, these fossil fuels such as coal, petroleum, oil and natural gases are found to be present in a limited proportion, and it is a very expensive process to obtain these resources, so sustainable development method must be adopted in order to save this natural resources for the future generation.

Some of the examples of alternative resources that are widely used in place of fossil fuels are wind energy, solar energy, tidal energy, biomass energy and bio-fuels.

Thus, it is very important to develop and use alternative resources.

Final answer:

Developing alternative energy sources is vital for mitigating climate change, reducing reliance on finite fossil fuels, and enhancing economic opportunity and security. Renewable energy such as solar, wind, and hydropower are crucial for the sustainable transition.

Explanation:

Developing alternative energy sources is crucial for a number of reasons. First, as renewable energy sources like solar and wind become more technically superior and cost-effective compared to fossil fuels, market forces will naturally encourage a transition away from non-renewable resources. This helps prevent dependency on finite resources that will eventually deplete.

Second, climate change concerns necessitate the development of alternative energy sources. Political measures may impose financial penalties on fossil fuel use to mitigate harmful ecological impacts, prompting a migration towards more sustainable energy choices.

Lastly, alternative energy sources like solar, wind, and hydropower can provide increased economic opportunity, job creation, and energy security. Especially in light of climate-related disasters that reveal the vulnerabilities of fossil-fuel-dependent energy systems, diversification is key. It is also critical to plan now for a transition to sustainable energy to avoid the potential "energy trap" where too much energy is consumed in building new infrastructure, leaving insufficient resources for society's needs.

Explanation:

When a electron is collided with a photon with exactly the same energy it would require to get to any of the farther orbits,electron transition takes place to an orbit depending on the energy of the photon.

When electrons emit exactly the same amount energy that is difference between the current energy level and the new level,then the electron makes a transition to the new level.

An electron in an atom is likely to move from one energy level to another when it gains or loses energy.

Explanation:

The change in an electron’s position with respect to energy levels is termed as Atomic electron transition. In spite of having similar charge and mass, the energy level of any electron in an atom, surrounding the nucleus, differs depending on its orbital position from the nucleus.

Electrons positioned nearest to the atomic nucleus carry least energy. To move an electron from its original ground state energy level to a higher level; energize the atom and it will excite the electrons thus making it move from its lower energy stable state to an unstable state with higher energy level. Releasing energy of an atom decreases the energy level of its excited electrons, de-energizing it and thus stabilizing the atom.

Answer:

option C

Explanation:

The correct answer is option C

A light that transmits through n₂ travels t distance before reflection off the n₁ medium and again travels distance t before reaching the point from where it entered n₂  medium. Hence it travels 2 t distance more than the light that is reflected off n₂.

It( light entering n₂) also travels an additional distance equal to, half of the wavelength, when reflected off n₁ ( as n₁ is greater than n₂).  

Wavelength in n₂ is = [tex]\dfrac{\lambda}{n_2}[/tex]  

Hence, path length difference = [tex]2t +\dfrac{\lambda}{2 n_2}[/tex]

The effective path length difference between the light that reflected off of the n2 medium and the light that reflected off the n1 medium is

Path length difference = 2t+λ/(2n2)

Generally, Wavelength is simply defined as the distance between points in the adjacent cycles of a waveform signal channeled through a space.

In conclusion, A light that travels through n2, travels in a time t, a distance before reflection from the n1 channel,  travels a distance d before reaching the point from where it entered n2  channel.

Path length difference = 2t+λ/(2n2)

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Answer:

option D.

Explanation:

The correct answer is option D.

The irony is the figure of speech which represents the contradiction between what is stated and what actually the scenario is.

the statement by the poet does not have any contradictory statements.

The extended metaphor is a part of speech which is used when there is a comparison between two unlike things in the paragraph.

in the given statement of the poem, there is no comparison.

Personification is the part of speech where human quality are given to non-living things.

in the give statement wind in the wire took up the story can be taken as the human quality.

so, the statement part of speech is personification.

Answer:

Explanation:

Convergent lens is the lens which converges the rays of light falling on it. It is thicker at the middle and thinner at the edges. It is also known as convex lens.

Divergent lens is the lens which diverge the rays of light falling on it. It is thinner at the middle and thicker at the edges. It is also called as concave lens.

Convergent lenses, or convex lenses, thicken in the middle and focus light rays to a point, forming real or virtual images; divergent lenses, or concave lenses, are thinner in the middle, causing the light rays to spread out and only form virtual images. Snell’s law describes the refraction process in both lens types as being influenced by differences in the index of refraction.

Difference Between Convergent and Divergent Lenses

Lenses are often categorized as either convergent (convex) or divergent (concave) depending on how they refract light. A converging lens is thicker at the middle and causes parallel light rays entering the lens to converge, or come together, at a single point known as the focal point. This lens can create both real and virtual images, the nature of which depends on the position of the object relative to the lens. In contrast, a divergent lens is thinner at the middle and causes parallel light rays to spread apart or diverge after passing through the lens. Divergent lenses only form virtual images.

Snell's law helps explain the refraction in both types of lenses, considering the difference in the index of refraction between the lens material and the surrounding air. The lens power is determined by its ability to bend light, described by the lens's focal length, with more powerful lenses having shorter focal lengths.

Answer:

the person will be in the shore at 10.73 minutes after launch the shoe.

Explanation:

For this we will use the law of the lineal momentum.

[tex]L_i = L_f[/tex]

Also,

L = MV

where M is de mass and V the velocity.

replacing,

[tex]M_i V_i = M_{fp}V_{fp} + M_{fz}V_{fz}[/tex]

wher Mi y Vi are the initial mass and velocity, Mfp y Vfp are the final mass and velocity of the person and Mfz y Vfz are the final mass and velocity of the shoe.

so, we will take the direction where be launched the shoe as negative. then:

(70)(0) = (70-0.175)([tex]V_fp[/tex]) + (0.175)(-3.2m/s)

solving for [tex]V_fp[/tex],

[tex]V_fp[/tex] = [tex]\frac{(3.2)(0.175)}{69.825}[/tex]

[tex]V_fp[/tex] = 0.008m/s

for know when the person will be in the shore we will use the rule of three as:

1 second -------------- 0.008m

t seconds-------------- 5.15m

solving for t,

t = 5.15m/0.008m

t = 643.75 seconds = 10.73 minutes

The time to reach the shore is 643.75 seconds.

The problem presented involves conservation of momentum on a frictionless surface, which is a physics concept. To solve for the time it takes the person to reach the shore, we can use the principle that the momentum before throwing the shoe is equal to the momentum after throwing the shoe, as there are no external forces acting on the system (since friction is ignored).

The initial momentum of the system is zero because the person is not moving. After throwing the shoe, the momentum of the shoe can be calculated using the formula: p = m × v, where p is momentum, m is mass, and v is velocity. The momentum of the shoe is 0.175 kg × 3.2 m/s, which must be equal and opposite to the momentum of the person. Thus, the velocity of the person, v_p, can be found through the equation m_shoe × v_shoe = m_person × v_person.

Once the velocity of the person is calculated, the time, t, taken to cover the distance to the shore can be found using the formula: t = d / v_p, where d is the distance to the shore.

Carrying out the calculations gives us:

p_shoe = 0.175 kg × 3.2 m/s = 0.56 kg m/s

v_person = p_shoe / m_person = 0.56 kg m/s / 70 kg = 0.008 m/s

t = d / v_person = 5.15 m / 0.008 m/s = 643.75 seconds

The person will take approximately 643.75 seconds to reach the shore.

The rollercoaster initially had 78,000 J of energy. It converted two-thirds of the energy into kinetic energy and later doubled it on a curve. Therefore, the coaster's new total mechanical energy is 182,000 J.

In this energy problem, the roller coaster car starts out with 78,000 J of potential energy. It then converts two-thirds of its energy into kinetic energy, which is 2/3 * 78,000 J = 52,000 J. However, this isn't the end of the energy conversion. As the roller coaster car takes a curve, it doubles its kinetic energy to become 2 * 52,000 J = 104,000 J. Therefore, the new total mechanical energy of the car, considering both its remaining potential and newly gained kinetic energy, is its original potential energy (78,000 J) minus the potential energy converted to kinetic and then doubled (2/3 * 78,000 J * 2), which gives us 78,000 J - (2/3 * 78,000 J * 2) = 78,000 J - 104,000 J = -26,000 J. However, energy can't be negative, so it means the question might be flawed or we need to ignore the energy conservation law in this case and simply sum up potential and kinetic energies getting 78,000 J + 104,000 J = 182,000 J.

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To find the mechanical energy of the roller coaster car, we calculate the converted kinetic energy and then account for it being doubled during the ride. The car's total mechanical energy remains at 78,000 J due to conservation of energy.

The problem involves calculating the mechanical energy of a roller coaster car after it has converted some of its initial potential energy into kinetic energy and then doubled that kinetic energy. Initially, the car starts with 78,000 J of potential energy. As the problem states, the car converts two-thirds of this energy into kinetic energy. This conversion can be calculated as (2/3) × 78,000 J = 52,000 J of kinetic energy. Then, as the car takes a curve, it doubles this kinetic energy, resulting in 2 × 52,000 J = 104,000 J of kinetic energy. Due to the conservation of mechanical energy, and considering that no energy is lost to friction or other forces, the total mechanical energy of the car will be the same as the initial potential energy it had at the top of the first rise. Therefore, the car now has a total mechanical energy of 78,000 J.

Answer:

Three times

Explanation:

The amount of heat added to a substance when its temperature is increased from T_1 to T_2 is given by

[tex]Q=mc(T_2-T_1)[/tex]

c= specific heat capacity

m= mass of the substance

⇒Q∝c

that is if c is increased three times the amount of heat added is also increased three times. Therefore, the amount of heat added to the copper is three times the heat added to lead.

To calculate the value of 'do' in the given pulley system, we need to know the efficiency.

In order to calculate the value of 'do' in the given pulley system, we need to understand the concepts of actual mechanical advantage (AMA) and ideal mechanical advantage (IMA).

AMA is the ratio of the output force (load) to the input force (effort). In this case, the load is the engine with a weight of 2,000 newtons and the effort force is 250 newtons. So, AMA = Load/Effort = 2000 N/250 N = 8.

IMA is the theoretical mechanical advantage calculated by counting the number of ropes supporting the load. In this case, since there is only one rope supporting the load, IMA = 1.

The relationship between AMA and IMA is given by the equation: AMA = IMA x efficiency.

Since the efficiency is not provided in the question, we cannot directly calculate the value of 'do' without this information.

Answer:

A. Bohr's model focused on the nucleus

Answer:

2388078.86544 N/C

Explanation:

[tex]\rho[/tex] = Charge density = 9.22 mC/m³

r = Distance = 7.35 cm

[tex]r_o[/tex] = Outer radius = 3.5 cm

[tex]r_i[/tex] = Inner radius = 2.98 cm

l = Length of cylinder

[tex]\epsilon_0[/tex] = Permittivity of free space = [tex]8.85\times 10^{-12}\ F/m[/tex]

V = Volume

E = Electric field

Charge is given by

[tex]Q=\rho V\\\Rightarrow Q=\rho\pi l(r_o^2-r_i^2)[/tex]

Area

[tex]A=2\pi rl[/tex]

From Gauss law the flux through a cylindrical surface is given by

[tex]EA=\frac{Q}{\epsilon_0}\\\Rightarrow E=\frac{Q}{\epsilon_0A}\\\Rightarrow E=\frac{\rho\pi l(r_o^2-r_i^2)}{\epsilon_02\pi rl}\\\Rightarrow E=\frac{\rho(r_o^2-r_i^2)}{\epsilon_02r}\\\Rightarrow E=\frac{9.22\times 10^{-3}(0.035^2-0.0298^2)}{8.85\times 10^{-12}\times 2\times 0.0735}\\\Rightarrow E=2388078.86544\ N/C[/tex]

The electric at the given distance is 2388078.86544 N/C

Answer:

1.556 N , 0.989 N, 0.567 N

Explanation:

Radius of sphere, r = 1.21 cm = 0.0121 m

density of platinum , d = 2.14 x 10^4 kg/m^3

density of mercury, d' = 13.6 x 10^3 kg/m^3

Volume of sphere, [tex]\frac{4}{3}\pi \times r^{3}= \frac{4}{3}\times 1.34\times \left (0.0121  \right )^{3}[/tex]

V = 7.42 x 10^-6 m^3

Weight of sphere = volume of sphere x density of platinum x gravity

W = V x d x g = 7.42 x 10^-6 x 2.14 x 10^4 x 9.8 = 1.556 N

Buoyant force, B = Volume x density of mercury x gravity

B = 7.42 x 10^-6 x 13.6 x 10^3 x 9.8 = 0.989 N

Apparent weight = True weight - Buoyant force

Apparent weight = 1.556 - 0.989 = 0.567 N

To find the weight of the platinum sphere, calculate the mass of the sphere using its density and volume. Then, use the formula weight = mass × gravitational acceleration. The buoyant force acting on the sphere is equal to the weight of the fluid displaced, which in this case is the weight of an equivalent volume of mercury. The sphere's apparent weight can be calculated by subtracting the buoyant force from its actual weight.

To find the weight of the platinum sphere, we can use the formula:

Weight = Mass × Gravitational acceleration

Given the density of platinum and the radius of the sphere, we can calculate the mass of the sphere using the formula:

Mass = Density × Volume

Using the volume of a sphere formula, we can determine the volume of the sphere. Once we have the mass, we can calculate the weight of the sphere.

The buoyant force acting on the sphere can be calculated using Archimedes' principle, which states that the buoyant force equals the weight of the fluid displaced. In this case, the fluid is mercury. Since the sphere is totally immersed in mercury, the buoyant force would be the weight of an equivalent volume of mercury.

The sphere's apparent weight can be calculated by subtracting the buoyant force from the weight of the sphere. This gives us the net force acting on the sphere when it is immersed in mercury.

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Answer:

(A) l = 0.39 m      

(B)  l =0.38 m  

(C) l = 0.14 m

Explanation:

Answer:

Explanation:

Answer:

Explanation:

from the question we are given the following values:

mass (m) = 1.6 kg

height (h) = 1.05 m

compression of spring (l) = ?

spring constant (k) = 330 N/m

acceleration due to gravity (g) = 9.8 m/s^{2}

(A) initial potential energy of the object = final potential energy of the spring

         potential energy of the object = mg(1.05 + l)  

         potential energy of the spring = 0.5 x k x l^{2}  (k= spring constant)

 therefore we now have

              mg(1.05 + l)  = 0.5 x k x l^{2}

              1.6 x 9.8 x (1.05 + l)  = 0.5 x 300 x l^{2}

               15.68 (1.05 + l) = 150 x l^{2}

                   16.5 + 15.68l = 150l^{2}

l = 0.39 m        

(B)   with constant air resistance the equation applied in part A above becomes

initial P.E of the object - air resistance = final P.E of the spring

mg(1.05 + l) - 0.750(1.05 + l) = 0.5 x k x l^{2}        

     1.6 x 9.8 x (1.05 + l) - 0.750(1.05 + l)  = 0.5 x 300 x l^{2}

         (16.5 + 15.68l) - (0.788 + 0.75l) = 150l^{2}        

          16.5 + 15.68l - 0.788 - 0.75l = 150l^{2}

            15.71 + 14.93l = 150^{2}

            l =0.38 m  

(C)   where g = 1.63 m/s^{2} and neglecting air resistance

      the equation mg(1.05 + l)  = 0.5 x k x l^{2} now becomes

        1.6 x 1.63 x (1.05 + l)  = 0.5 x 300 x l^{2}

        2.608 (1.05 +l) = 0.5 x 300 x l^{2}

        2.74 + 2.608l = 150 x l^{2}

l = 0.14 m

The compression of the spring when it is dropped from 1.05 m is 0.37 m.

The compression of the spring when air resistance is considered 0.36 m.

The compression of the spring when air resistance is neglected and gravity is 1.63 is 0.14 m.

The given parameters;

The compression of the spring is determined by applying the principle of conservation of energy;

[tex]\frac{1}{2} kx^2 = mgh\\\\\frac{1}{2} kx^2 = mg(1.05 + x)\\\\kx^2 = 2mg(1.05 + x)\\\\330x^2 = 2\times 1.6 \times 9.8(1.05 + x)\\\\330x^2 = 32.93 + 31.36x\\\\330x^2 - 31.36x - 32.93 = 0\\\\a = 330, \ b = -31.36, \ c = -32.93\\\\x = \frac{-b \ \ +/- \ \sqrt{b^2 -4ac} }{2a} \\\\x = \frac{-(-31.36) \ \ +/- \ \sqrt{(-31.36)^2 -4(330\times -32.93)} }{2(330)}\\\\x = 0.37 \ m[/tex]

Considering air resistance, the compression of the spring is calculated as follows;

[tex]\frac{1}{2} kx^2 = mg(1.05+ x) - F(1.05+ x)\\\\\frac{1}{2} \times 330 x^2 = 1.6\times 9.8(1.05 + x) - 0.75(1.05 + x)\\\\165x^2 = 16.46 + 15.68x - 0.79 - 0.75x \\\\165x^2 -14.93x - 15.67 = 0\\\\a = 165, \ \ b = -14.93 \ \ c = -15.67 = 0\\\\x = \frac{-b \ \ +/- \ \sqrt{b^2 - 4ac} }{2a} \\\\x = \frac{-(-14.93) \ \ +/- \ \sqrt{(-14.93)^2 - 4(15.67)} }{2(165)}\\\\x = 0.36 \ m[/tex]

The compression of the spring when air resistance is neglected and gravity is 1.63;

[tex]\frac{1}{2} kx^2 = mg(1.05 + x)\\\\\frac{1}{2} \times 330 x^2 = 1.6 \times 1.63(1.05 + x)\\\\165 x^2 = 2.74 + 2.61x \\\\165 x^2 - 2.61x- 2.74 = 0\\\\a = 165, \ \ b = -2.61, \ c = \ -2.74\\\\x = \frac{-b \ \ +/- \ \ \sqrt{b^2 - 4ac} }{2a} \\\\x = \frac{-(-2.61) \ \ +/- \ \ \sqrt{(-2.61) ^2 - 4(165\times -2.74)} }{2(165)}\\\\x = 0.14 \ m[/tex]

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Answer:

A perfect example of wave reflection is an echo.

Explanation:

A wave reflection takes place when waves cannot pass through a surface and in turn they bounce back. It is not necessary that wave reflections can only happen with sound waves, they can also take place in light waves. Also, the waves which are reflected have the same frequency as the original wave, but their direction is different. When a wave strikes an object in the same angle, they bounce back straight but when they hit an object with different angle, their direction changes.