The mass of a radioactive substance follows a continuous exponential decay model, with a decay rate parameter of 1% per day. A sample of this radioactive substance has an initial mass of 2.5kg. Find the mass of the sample after five days.

Answer:

  a.  17.0 m²

Explanation:

The product of the two dimensions is 16.99013 m². The least precise contributor has 3 significant figures, so the most precise result available is one with 3 significant figures: 17.0 m².

__

Additional comment

Given that each measurement may be in error by 1/2 of a least-significant digit, their product can be as little as 16.9700025, or as great as 17.0102625. This amounts to 16.9901325 ± 0.0201300. The value 17.0 suggests a range from 16.95 to 17.05, which exceeds the actual range possible with the given measurements. On the other hand, a 4 significant-figure value (16.99) suggests a much smaller range in the product than there may actually be: (16.985, 16.995)

The car will pass the truck after 20 seconds.

To find when the car will pass the truck, we need to determine the time it takes for the car to reach a speed of 25 m/s and the distance traveled by the truck in that time.

The car is accelerating at a rate of 1.25 m/s². Using the equation v = u + at, where v is the final velocity, u is the initial velocity (0 m/s), a is the acceleration, and t is the time, we can solve for t: 25 m/s = 0 m/s + 1.25 m/s² * t.

Simplifying the equation, we get t = 20 seconds. Therefore, the car will pass the truck after 20 seconds.

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Answer:

No, it is impossible

Explanation:

Kinematics equation:

[tex]Vf^{2} =Vo^{2} -2gy[/tex]

if height is maximum:

y=H and Vf=0

so:

Analysis: From the last equation we see that the maximum height depends ONLY on the initial speed. This means that if both objects reach the same maximum height, then they necessarily need to have the SAME initial velocity. If they have the same initial velocity and in order to reach the maximum height at the SAME time the only way is that they are released at the SAME TIME.

Answer:

Part a)

[tex]\Delta x = 36.35 m[/tex]

Part b)

height will be 107.2 m

Part c)

[tex]t = 1.78 s[/tex]

Explanation:

Initial velocity of the ball is given as

v = 7.90 m/s

angle of projection of the ball

[tex]\theta = 23^o[/tex]

now the two components of velocity of ball is given as

[tex]v_x = 7.90 cos23 = 7.27 m/s[/tex]

[tex]v_y = 7.90 sin23 = 3.09 m/s[/tex]

Part a)

Since ball strike the ground after t = 5 s

so the distance moved by the ball in horizontal direction is given as

[tex]\Delta x = v_x \times t[/tex]

[tex]\Delta x = 7.27 (5)[/tex]

[tex]\Delta x = 36.35 m[/tex]

Part b)

Now in order to find the height of the ball we can find the vertical displacement of the ball

[tex]\Delta y = v_y t + \frac{1}{2}at^2[/tex]

[tex]\Delta y = (3.09)(5) - \frac{1}{2}(9.81)(5^2)[/tex]

[tex]\Delta y = -107.2 m[/tex]

So height will be 107.2 m

Part c)

when ball reaches a point 10 m below the level of launching then the displacement of the ball is given as

[tex]\Delta y = -10 m[/tex]

so we will have

[tex]\Delta y = v_y t + \frac{1}{2}at^2[/tex]

[tex]-10 = 3.09 t - \frac{1}{2}(9.81)t^2[/tex]

so we will have

[tex]t = 1.78 s[/tex]

Explanation:

Given that,

Electrostatic force, [tex]F=3.7\times 10^{-9}\ N[/tex]

Distance, [tex]r=5\ A=5\times 10^{-10}\ m[/tex]

(a) [tex]F=\dfrac{kq^2}{r^2}[/tex], q is the charge on the ion              

[tex]q=\sqrt{\dfrac{Fr^2}{k}}[/tex]

[tex]q=\sqrt{\dfrac{3.7\times 10^{-9}\times (5\times 10^{-10})^2}{9\times 10^9}}[/tex]      

[tex]q=3.2\times 10^{-19}\ C[/tex]

(b) Let n is the number of electrons are missing from each ion. It can be calculated as :

[tex]n=\dfrac{q}{e}[/tex]

[tex]n=\dfrac{3.2\times 10^{-19}}{1.6\times 10^{-19}}[/tex]

n = 2

Hence, this is the required solution.                        

The electrostatic constant is also known as Coulomb's constant or the electric constant. Its unit is [tex]\rm \frac{Nm^2}{C^2}[/tex].

It is a fundamental physical constant that appears in Coulomb's law, which describes the interaction between electric charges. It's denoted by the symbol K.

Given information:

Unit of force (F) = Newton

Unit of charge (Q) = Coloumb

Unit of distance (r) = Meters

Now,

On substituting the values of given units:

[tex]\rm F = \frac{Kq_1q_2}{r^2}\\N =\frac{K C\times C}{m^2}\\N = \frac{K C^2}{m^2}\\K = \frac{Nm^2}{C^2}[/tex]

The unit of electrostatic constant (K) is [tex]\rm \frac{Nm^2}{C^2}[/tex]. This constant (K) plays a crucial role in understanding and calculating the forces and interactions between charged particles in the realm of electrostatics.

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Final answer:

The unit for the electrostatic constant k is Newton meters squared per Coulomb squared (N·m²/C²), and k is also known as Coulomb's constant with a value of approximately 8.99 × 10⁹ N·m²/C².

Explanation:

The unit for the electrostatic constant k in the formula F = k[tex]q_{1}[/tex][tex]q_{2}[/tex] /r² can be determined by rearranging the formula to solve for k, which gives us k = Fr² / [tex]q_{1}[/tex][tex]q_{2}[/tex] . Since the unit for the electrostatic force F is Newtons (N), the distance r is in meters (m), and the charge [tex]q_{1}[/tex]and [tex]q_{2}[/tex] are in Coulombs (C), the units for k would be Newton meters squared per Coulomb squared (N·m²/C²). The value of the electrostatic constant k is approximately 8.99 × 10⁹ N·m²/C², also known as Coulomb's constant.

Answer:

C) about 1/10 as great.

Explanation:

We use the relation between Impulse, I, and momentum, p:

[tex]I=\Delta p\\ F*t=m(v_{f}-v{o})\\ \\[/tex]

[tex]F=m(v_{f}-v{o})/t=-mv{o}/t\\ \\[/tex]     the final speed is zero

We can see that the average Force is inversely proportional to the time, so if the time is 10 times bigger, the average Force is 1/10 as great

Average force body experience is about 1/10 as great as  when the legs are kept stiff

from Newtons second law, force. f is the product of mass, m and acceleration, a

f = m * a

a = ( v - u ) / t

f = m * ( v- u ) / t

so force is inverrsely related to time, making the time of the impact 10 times as great as stiff-legged landing impiles mathematically as follows:

for stiff-legged

f1 = m * ( v - u ) / t

for bent knees

f2 = m * ( v - u ) / 10t

f2 = f1 / 10

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Answer:

the potential energy increases and the electric potential increases

Explanation:

we know here that Voltage i.e. (Electric potential) increases from the initial point  to the final point

consider if 2 object of different charge 1 is twice the charge of other moveing in same distance in electric filed

than object of twice the charge require twice the force so twice amount of work

This work change the potential energy by  equal amount of work done

so electric potential energy is depend on the amount of charge on object

so if work being done on a positive test charge by an external force in moving the charge from one location to another

the potential energy increases and the electric potential increases

When a positive test charge is moved from one location to another, the potential energy increases and the electric potential energy increases.

The work done in moving a unit positive test charge from infinity to a certain point in the electric field is known as potential energy.

V = E x d

V = (F/q) x d

where;

Thus, when a positive test charge is moved from one location to another, the potential energy increases and the electric potential energy increases.

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Answer:

[tex]2LiBr+Pb(NO_3) = PbBr_2+ 2LiNO_3[/tex]  is a double displacement reaction

Explanation:

[tex]2LiBr+PbNO_3 = PbBr_2+2LiNO_3[/tex]

                                                       It is of the form [tex]AX+BY = AY+BX[/tex]

                                                       [tex]Fe+2HCl = FeCl_2+H_2[/tex]

Both oxidation and reduction occur in this reaction. Fe gets oxidized and H gets reduced.

                                          [tex]Fe = Fe^(2+)+2e^-[/tex]

                                          [tex]2H^++2e^- = H_2[/tex]

                                          [tex]CaO+H_2 O = Ca(OH)_2[/tex]

It is an exothermic combination reaction. Calcium reacts with water to produce calcium hydroxide and heat is released in this process.

It is a decomposition reaction where nickel chloride decomposes to nickel and chlorine.

Answer:

18. Double Displacement Reaction

19. Single Displacement Reaction

20. Synthesis Reaction

21. Decomposition Reaction

Explanation:

Double Displacement formula:

AB + CD --> AD + CB

Single Displacement formula:

A + BC --> AC + B

Synthesis formula:

A + B --> AB

Decomposition formula:

AB --> A + B

Answer:

The acceleration of the object is 9.3 m/s²

Explanation:

For a straight movement with constant acceleration, this equation for the position applies:

x = x0 + v0 t + 1/2 a t²

where

x = position at time t

x0 = initial position

v0 = initial velocity

a = acceleration

t = time

we have two positions: one at time t = 1 s and one at time t = 2 s. We know that the difference between these positions is 14.0 m. These are the equations we can use to obtain the acceleration:

x₁ = x0 + v0 t + 1/2 a (1 s)²

x₂ = x0 + v0 t + 1/2 a (2 s)²

x₂ - x₁ = 14 m

we know that the object starts from rest, so v0 = 0

substracting both equations of position we will get:

x₂ - x₁ = 14

x0 + v0 t + 1/2 a (2 s)² - (x0 + v0 t + 1/2 a (1 s)²) = 14 m

x0 + v0 t + 2 a s² - x0 -v0 t - 1/2 a s² = 14 m

2 a s² - 1/2 a s² = 14 m

3/2 a s² = 14 m  

a = 14 m / (3/2 s²) = 9.3 m/s²

The constant acceleration of the object is 9.33 m/s².

The given parameters;

The acceleration of the object is calculated by applying the second kinematic equation as follows;

s = ut  +  ¹/₂at²

where;

at t = 1.0 s

x₁ = 0  +   ¹/₂(1²)a

x₁ =  ¹/₂(a)

at t = 2.0 s

x₂ = 0 +  ¹/₂(2²)a

x₂ = 2a

The change in position;

Δx = x₂ - x₁ = 14

14 = 2a -  ¹/₂(a)

[tex]14 = \frac{3a}{2} \\\\3a = 2(14)\\\\3a = 28\\\\a = \frac{28}{3} = 9.33 \ m/s^2[/tex]

Thus, the constant acceleration of the object is 9.33 m/s².

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Answer:

These are the answers for 1, 2 and 3

Explanation:

Sorry I couldn't help you with 4 and 5

1.

Answer:

y = 11.48 m

x = 13.0 m

Explanation:

Components of initial velocity is given as

[tex]v_x = 7.2 cos25 = 6.52 m/s[/tex]

[tex]v_y = 7.2 sin25 = 3.04 m/s[/tex]

Now after t = 2 s the vertical position is given as

[tex]y = y_0 + v_y t + \frac{1}{2}a_y t^2[/tex]

[tex]y = 25 + 3.04(2) - \frac{1}{2}(9.8)(2^2)[/tex]

[tex]y = 11.48 m[/tex]

Now horizontal position is given as

[tex]x = v_x t[/tex]

[tex]x = 6.52 \times 2[/tex]

[tex]x = 13.04 m[/tex]

2.

Answer:

d = 26.6 m

Explanation:

Initial position on y axis is given as

[tex]y = 1.5 m[/tex]

velocity of ball in y direction

[tex]v_y = 0[/tex]

now we have

[tex]\Delta y = v_y t + \frac{1}{2}gt^2[/tex]

[tex]1.5 = \frac{1}{2}(9.8) t^2[/tex]

[tex]t = 0.55 s[/tex]

now the distance moved by the ball in horizontal direction is given as

[tex]d = v_x t[/tex]

[tex]d = 48.1 \times 0.55[/tex]

[tex]d = 26.6 m[/tex]

3

Answer:

[tex]A + B = 12.42\hat i + 0.35 \hat j[/tex]

Explanation:

Here we can see the two vectors inclined at different angles

so two components of vector A is given as

[tex]A = 11.3 cos21\hat i - 11.3 sin21\hat j[/tex]

[tex]A = 10.55 \hat i - 4.05 \hat j[/tex]

Similarly for other vector B we have

[tex]B = 4.78cos67 \hat i + 4.78 sin67\hat j[/tex]

[tex]B = 1.87\hat i + 4.4 \hat j[/tex]

now we need to find A + B

so we have

[tex]A + B = (10.55\hat i - 4.05\hat j) + (1.87\hat i + 4.4 \hat j)[/tex]

[tex]A + B = 12.42\hat i + 0.35 \hat j[/tex]

4.

Answer:

d = 81.86 m

Explanation:

Displacement of airplane is given as

[tex]d_1[/tex] = 72 km in direction 30 degree East of North

[tex]d_1 = 72sin30\hat i + 72cos30\hat j[/tex]

[tex]d_1 = 36\hat i + 62.35\hat j[/tex]

[tex]d_2[/tex] = 48 km South

[tex]d_2 = -48\hat j[/tex]

[tex]d_3[/tex] = 100 km in direction 30 degree North of West

[tex]d_3 = -100 cos30\hat i + 100 sin30\hat j[/tex]

[tex]d_3 = -86.6\hat i + 50\hat j[/tex]

so net displacement is given as

[tex]d = d_1 + d_2 + d_3[/tex]

[tex]d = 36\hat i + 62.35\hat j - 48\hat j - 86.6\hat i + 50 \hat j[/tex]

[tex]d = -50.6\hat i + 64.35\hat j[/tex]

now magnitude of displacement is given as

[tex]d = \sqrt{50.6^2 + 64.35^2}[/tex]

[tex]d = 81.86 m[/tex]

5.

Answer:

1) final speed at which it will hit the ground again

2) acceleration during the motion of the ball

Explanation:

As we know that the speed at which the ball is thrown is always same to the speed by which it will hit back on the ground

so we know that final speed will be same as initial speed

Also we know that during the motion the acceleration of ball is due to gravity so it will be

[tex]a = - g[/tex]

Answer:

The natural, fundamental frequency of this string is 24 hertz.          

Explanation:

Length of the string, l = 2 m

Number of segments, n = 5

Frequency, f = 120 Hz

Let f' is the natural fundamental frequency of this string. The frequency for both side ended string is given by :

[tex]f=\dfrac{nv}{2l}[/tex]

[tex]v=\dfrac{2fl}{n}[/tex]

[tex]v=\dfrac{2\times 120\times 2}{5}[/tex]        

v = 96 m/s

For fundamental frequency, n = 1

[tex]f'=\dfrac{v}{2l}[/tex]

[tex]f'=\dfrac{96}{2\times 2}[/tex]

f' = 24 Hertz

So, the natural, fundamental frequency of this string is 24 hertz. Hence, this is the required solution.

The natural, fundamental frequency of this standing wave is equal to 24 Hertz.

Given the following data:

Length of the string = 2.0 meters.

Number of segments = 5.

Frequency = 120 Hertz.

First of all, we would determine the velocity of the standing wave by using this formula:

[tex]F=\frac{nV}{2L} \\\\V=\frac{2FL}{n} \\\\V=\frac{2 \times 120 \times 2.0}{5}\\\\V=\frac{480}{5}[/tex]

V = 96 m/s.

Now, we can calculate the natural, fundamental frequency by using this formula:

[tex]F'=\frac{V}{2L} \\\\F'=\frac{96}{2 \times 2.0} \\\\F'=\frac{96}{4.0}[/tex]

F' = 24 Hertz.

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Answer:

The required radius of its motion is [tex]0.084m[/tex].

Explanation:

The formula for calculating the required  radius of its motion is given by

[tex]F = (mv^2)/r[/tex]

Where m= mass  

V= moving velocity

F=frictional force

r = radius of its motion

Then the required radius of its motion is given by

[tex]r =(mv^2)/F[/tex]

Given that

mas =0.0818 kg

Frictional force= 0.108 N

Moving with Velocity of  = 0.333 m/s

radius of its motion = [tex]\frac{[0.0818 kg \times (0.333 m/s)^2]}{0.108 N}[/tex]

Hence the required radius of its motion is r = [tex]8.4 cm=0.084m[/tex]

Answer:

0.084

Explanation:

Acellus

Answer:

Technician A says that this is because the front wheel cylinders are closer to the master cylinder than are the rear wheel cylinders.

Explanation:

Since the position of cylinder is near the front wheel so the normal force of the front wheel is more than the normal force on the rear wheel

as we know that the center of mass of the wheel is shifted towards the front wheel as the balancing is done with reference to its center of mass

so we will have

[tex]N_1 d_1 = N_2 d_2[/tex]

also we have

[tex]N_1 + N_2 = W[/tex]

so here we can say

friction force on front wheel will be more

[tex]F_f = \mu N_1[/tex]

so here front wheel has to do more work to stop the vehicle

Technician B is correct; the front brakes do more work because the vehicle's weight shifts to the front during braking due to dynamic load transfer. This is a physics principle related to force and motion, rather than the hydraulic pressure distribution which is equal for all brakes due to Pascal's principle.

Technician B suggests that the front brakes do more work than the rear brakes because the weight of a vehicle shifts to the front during a stop. This is correct, as deceleration causes the vehicle's weight to transfer to the front due to inertia, resulting in greater pressure on the front brakes. This phenomenon is known as weight transfer or dynamic load transfer. The claim by Technician A that proximity to the master cylinder affects braking force is not accurate, as hydraulic systems utilize Pascal's principle to ensure equal pressure distribution throughout the brake fluid regardless of the distance from the master cylinder.

The estimated diameter of the Moon is approximately [tex]3.536 \times 10^4[/tex] meters, (two significant figures as [tex]3.5 \times 10^4[/tex] meters).

Here, we have to set up a proportion to solve for the diameter of the Moon using the given information:

The pencil's diameter = 0.7 cm

Distance from the eye to the pencil = 0.75 m

Earth-Moon distance = [tex]3.8 \times 10^5[/tex] km = [tex]3.8 \times 10^8[/tex] m

Let, the diameter of the Moon as "D."

When the pencil blocks out the Moon, the ratio of the pencil's diameter to the distance from the eye to the pencil is equal to the ratio of the Moon's diameter to the Earth-Moon distance:

Diameter of Moon / Earth-Moon distance = Pencil's diameter / Distance to pencil

D / (  [tex]3.8 \times 10^8[/tex] m) = (0.7 cm) / (0.75 m)

Now, solve for D:

D = (0.7 cm) * ( [tex]3.8 \times 10^8[/tex] m) / (0.75 m)

D ≈ [tex]3.536 \times 10^6[/tex] cm

Convert the diameter of the Moon to meters:

D ≈ [tex]3.536 \times 10^4[/tex] m

So, the estimated diameter of the Moon is approximately [tex]3.536 \times 10^4[/tex] meters, which can be expressed using two significant figures as [tex]3.5 \times 10^4[/tex] meters.

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Answer:

An annular Solar Eclipse

Explanation:

Solar eclipse is an event that occurs naturally on Earth when the moon in its orbit is positioned between the Earth and the Sun.Solar Eclipse can be total ,partial or annular.In the total solar eclipse, the moon completely covers the sun where as in the annular solar eclipse the moon covers the center of the Sun leaving outer edges of the Sun to be visible forming the ring of fire.In partial solar eclipse the Earth moves through the lunar penumbra as the moon moves between Earth and Sun.The moon blocks only some parts of the solar disk.Annular solar eclipse happens during new moon and the moon is at its farthest position from the Earth called Apogee.

A solar eclipse occurs when the moon blocks the sun. It can either be a total eclipse, where the sun is completely covered, or a partial or annular eclipse when the new moon is too far to entirely cover the sun.

A solar eclipse occurs when the moon moves between the earth and the sun, blocking out sunlight and casting a shadow. This can either result in a total eclipse, where the full face of the sun is covered, or a partial eclipse when part of the sun is still visible. A total eclipse only happens when the moon is close enough to the earth to totally cover the sun. When the new moon is too far from the earth to completely cover the sun, the eclipse can be either partial or become what's known as an 'annular' eclipse. In an annular solar eclipse, the moon is located too far from the Earth to completely cover the sun's disk, resulting in a ringlike appearance.

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Answer:

V=20cm/s

Explanation:

The average speed is the distance total divided the time total:

[tex]V=X/T[/tex]

First stage:

T1=5s

[tex]v_{f}  =v_{o} - at[/tex]

But, [tex]v_{f}  =0[/tex]   (decelerates to rest)

then: [tex]a =v_{o} /t=0.3/5=0.06m/s^{2}[/tex]

on the other hand:

[tex]x =v_{o}*t - 1/2*at^{2}=0.3*5-1/2*0.06*5^{2}=0.75m[/tex]

X1=75cm

Second stage:

T2=5s

[tex]x =v_{o}*t + 1/2*at^{2}=0+1/2*0.1*5^{2}=1.25m[/tex]

X2=125cm

Finally:

X=X1+X2=200cm

T=T1+T2=10s

V=X/T=20cm/s

The average speed of the particle is 20 centimetre per second.

Average speed is given as total distance covered by the particle divided by the total time of the journey.

The particle decelerates from 30 cm/s to rest (0 cm/s) in 5.0 s. Hence, the deceleration can be given as,

a = (0 - 30 cm/s) / 5 s = - 6 cm/s²

From the kinematic equation:

s = ut + [tex]\frac{1}{2}at^2[/tex], where s = displacement, a = acceleration, t = time, and u = initial velocity of the particle, we can determine the displacement.

so, s = (30 cm/s) (5 s) - [tex]\frac{1}{2} (6 cm/s^2)(5 s)^2[/tex] = 150 cm - 75 cm = 75 cm

The particle then accelerates uniformly at 10 cm/s² for another 5.0 s. The final velocity after this period is given as:

v = u + at

Here, u = 0 cm/s, a = 10 cm/s². t = 5s. Hence,

v = (10 × 5) m/s = 50 cm/s

Using the kinematic equation:

v² = u² + 2as, we get:

(50 cm/s)² = 2 (10 cm/s²) s

or, s = 125 cm

Total displacement of the particle = 75 cm + 125 cm = 200 cm

total time of journey = 5s + 5s = 10s

so, average velocity = 200 cm / 10 s = 20 cm/s

Answer:

35 meters

Explanation:

The river flows at 2 m/s from North to South and motor can propel the boat at 5m/s. As the downstream direction is positive, we are considering the river flow also propels the boat adding its speed to the boat. It means the boat and the person in the inner tube are in fact moving at 7 m/s. Distance can be calculated as follows:

[tex]v = d/t[/tex]  ⇒[tex]d = vt[/tex] ⇒[tex]d = 7\frac{m}{s}x5s[/tex]

[tex]d = 35m[/tex]

The motorboat will cover a distance of 35 meters downstream in 5 seconds. This is calculated by adding the boat's velocity relative to the water (5 m/s) to the velocity of the river current (2 m/s), giving a resultant velocity of 7 m/s and multiplying it by the time interval.

We need to calculate the distance the motorboat will cover downstream in a 5-second interval. The speed of the river current is 2 m/s and the speed of the motorboat relative to the water is 5 m/s. Since we are considering the downstream direction as positive, the boat's velocity relative to an observer on the shore would be the sum of these two speeds.

The boat's speed relative to the shore (resultant velocity) is:

Velocity of the boat relative to the shore = Velocity of the boat relative to the water + Velocity of the river = 5 m/s + 2 m/s = 7 m/s

The distance covered by the boat over a period of 5 seconds would be:
Distance = Velocity × Time = 7 m/s × 5 s = 35 m

Therefore, the motorboat will move 35 meters downstream as observed by someone outside of the water, like the person in the inner tube.

Answer:

yes

Explanation:

because when you slow down, the resistance slows with the speed.

Answer:

Yes, air resistance decrease with speed

Explanation:

Air resistance is a kind of fluid friction that acts when objects flow through fluids. It is affected by the velocity of moving objects and the area of the objects. When an object moves with a greater velocity the air resistance acting on them will be high, so the speed decreases.

Fluid friction acts in fluids namely liquids and gases. In liquids the friction is called buoyancy and in gases it is called air resistance or drag. When two objects having the same mass but different area move through air, the object with larger area will have less velocity compared with the other object.

Answer:

No the distance traveled in last 0.1 s is not same as that the distance traveled in first 0.1 s

so it will cover more distance in last 0.1 s then the distance in first 0.1 s

Explanation:

As we know that when stone is dropped from the diving board then its velocity at the time of drop is taken to be ZERO

so here we can say that its displacement from the top position in next 0.1 s is given as

[tex]d_1 = v_y t + \frac{1}{2}at^2[/tex]

[tex]d_1 = 0 + \frac{1}{2}(9.81)(0.1)^2[/tex]

[tex]d_1 = 0.05 m[/tex]

Now during last 0.1 s of its motion the stone will attain certain speed

so we will have

[tex]d_2 = v_y(0.1) + \frac{1}{2}(9.81)(0.1)^2[/tex]

[tex]d_2 = 0.1 v_y + 0.05 m[/tex]

so it will cover more distance in last 0.1 s then the distance in first 0.1 s

Final answer:

The distance a rock travels during a 0.1-second interval while falling will vary because of acceleration due to gravity. Early in its fall, it will travel less distance, and just before impact, it will cover more distance due to increased speed.

Explanation:

The distance traveled by a rock in free fall will not be the same in two intervals of time if these intervals occur at different stages of the fall, because the rock is accelerating due to gravity.

Near the top of its flight, it will have just started to accelerate, so it will cover a smaller distance in the first 0.1-second interval. However, just before the rock hits the water, it will have been accelerating for the entire duration of the fall, meaning it will be traveling much faster and will cover a greater distance in the last 0.1-second interval before impact.

Answer:

[tex]\theta=41.52^{\circ}[/tex]

Explanation:

Given that,

Velocity of the  airplane, v = 240 m/s

Angle with horizontal, [tex]\theta=30^{\circ}[/tex]

The altitude of the plane is 2.4 km, d = 2400 m

Vertical speed of the airplane, [tex]v_y=v\ sin\theta=240\ sin(30)=120\ m/s[/tex]

Horizontal speed of the airplane, [tex]v_x=v\ cos\theta=240\ sin(30)=207.84\ m/s[/tex]

So, the equation of the projectile for the flare is given by :

[tex]4.9t^2+120t-2400=0[/tex]

On solving the above equation, we get the value of t as:

t = 13.04 seconds

Horizontal distance travelled,

[tex]d=v_x\times t[/tex]

[tex]d=207.84\times 13.04[/tex]

d = 2710.23 m

Let [tex]\theta[/tex] is the angle with which it hits the target. So,

[tex]tan\theta=\dfrac{2400}{2710.23}[/tex]

[tex]\theta=41.52^{\circ}[/tex]

Hence, this is the required solution.

To solve this problem, you would apply principles of physics like projectile motion and trigonometry. We calculate the horizontal and vertical velocities using the given initial velocity and angle. The final total velocity and angle can be found by using these calculations as the horizontal velocity does not change.

The subject requires the application of the concepts of physics, specifically kinematics and trigonometry. Understanding the question in context, we are given that the airplane is flying at a velocity of 240m/s at an angle of 30.0° with the horizontal. A flare is released from the plane when it is at an altitude of 2.4km, and it hits a target on the ground. The problem needs us to find the angle θ.

Considering the fact that the time for projectile motion is completely determined by vertical motion, we set up the problem in the following way: We break down the initial velocity into components using the initial angle. The horizontal velocity (Vx) can be calculated using Vx = V*cos(θ), and the vertical velocity (Vy) can be calculated using Vy = V*sin(θ), where V is the initial velocity and θ is the initial angle.

Since the horizontal motion is constant and the initial position is known, we can use these two vertical and horizontal velocities to find the total velocity and the angle it makes with the horizontal. The trick here is to remember that since the x component (horizontal velocity) doesn't change, we can determine the final total velocity and its angle using these components.

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... prejudice based on misogyny.

Also a good bit of stupidity.

Answer:

- 3.33 m /s

Explanation:

m1 = 5 kg

m2 = 10 kg

u1 = 10 m/s

u2 = - 10 m/s

Let the velocity of the combination of the blob is v.

Use the conservation of momentum

[tex]m_{1}u_{1}+m_{2}u_{2}=\left ( m_{1}+m_{2} \right )v[/tex]

5 x 10 - 10 x 10 = (5 + 10)v

50 - 100 = 15 v

v = - 3.33 m /s

Thus, the velocity of the blob after sticking together is - 3.33 m/s.

Answer:hh

The acceleration may point in the opposite direct as the velocity

Explanation:

By definition free-fall is an uniform accelerate movement so speed always is increasing in fact acelertion and velocity always point in the same direction

Answer:

T h e  a c c e l .  e r a t i o n   m a y   p o i n t   i n   t h e   o p p o s i t e   d i r e c t   a s   t h e   v e l o c i t y   .  

Explanation:

Answer:

25%

Explanation:

If there is 20% scrap, then

80% of (production + scrap) = 72 pcs/hr

Now,

[tex]\frac{80}{100} \times (72+scrap)= 72 pcs/hr\\0.80\times (72+Scrap) = 72 \\ 72+Scrap = \frac{72}{0.80}\\72 + Scrap = 90\\Scrap = 18 pcs /hr[/tex]

The percent increase in labor productivity is, [tex]\frac{18}{72} =0.25[/tex].

Or it can be written as  25% of  which would give 80 pieces per hour.                                            

The work done in stretching a spring in two stages can be estimated by dividing the stretching process into two stages, calculating the average force in each stage, and then calculating the work done in each stage. The total work done is the sum of the work done in each stage.

To calculate the work done in stretching the spring in two stages, we can assume an average force for each stage. The force exerted by the spring at any displacement from its equilibrium length is given by Hooke's Law, F = kx, where 'F' is the force, 'k' is the spring constant, and 'x' is the displacement from equilibrium.

For stretching the spring from 0.3 m to 0.5 m (stage one), the average force exerted would be F_avg1 = k(x2 + x1) / 2 = 22 * ( 0.5 + 0.3 ) / 2 = 8.8 N. The work done can be then calculated as Work1 = F_avg1 * (x2 - x1) = 8.8 * (0.5-0.3) = 1.76 J.

For stretching the spring from 0.5 m to 0.7 m (stage two), the average force would be F_avg2 = k(x2 + x1) / 2 = 22 * ( 0.7 + 0.5 ) / 2 = 13.2 N. The work done in this stage would be Work2 = F_avg2 * (x2 - x1) = 13.2 * (0.7 - 0.5) = 2.64 J.

Therefore, the total work done in stretching the spring in two stages would be Work_total = Work1 + Work2 = 1.76 J + 2.64 J = 4.4 J.

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To estimate the work done in stretching the spring, divide the process into two stages: 0.3 m to 0.5 m and 0.5 m to 0.7 m. The total work done is 4.4 J.

Stage 1: Stretching from 0.3 m to 0.5 m

The initial force (F₁) at 0.3 m is:

The final force (F_mid) at 0.5 m is:

The average force (F_avg₁) for this stage is:

The distance stretched (d1) is:

Thus, the work done (W₁) is:

Stage 2: Stretching from 0.5 m to 0.7 m

The initial force (F_mid) at 0.5 m is:

The final force (F₂) at 0.7 m is:

The average force (F_avg₂) for this stage is:

The distance stretched (d2) is:

Thus, the work done (W₂) is:

Total Work Done in stretching the spring from 0.3 m to 0.7 m is:

Answer:

The acceleration from it's legs is [tex]a=138.20\frac{m}{s^{2} }[/tex]

Explanation:

Let's order the information:

Initial height: [tex]y_{i}=0m[/tex]

Final height: [tex]y_{f}=2.26m[/tex]

The bush accelerates from [tex]y_{i}=0m[/tex] to [tex]y_{e}=0.16m[/tex].

We can use the following Kinematic Equation to know the velocity at [tex]y_{e}[/tex]:

[tex]v_{f}^{2} = v_{e}^{2} - 2g(y_{f}-y_{e})=2ay_{e}[/tex]

where g is gravity's acceleration (9.8m/s). Since [tex]v_{f}=0[/tex],

[tex]2g(y_{f}-y_{e}) = v_{e}^{2}[/tex]

⇒ [tex]v_{e}=6.41\frac{m}{s}[/tex]

Working with the same equation but in the first height interval:

[tex]v_{e}^{2} = v_{i}^{2} + 2(a-g)(y_{e}-y_{i})[/tex]

Since [tex]v_{i}=0[/tex] and [tex]y_{i}=0[/tex],

[tex]v_{e}^{2} = 2(a-g)y_{e}[/tex]

⇒[tex]a-g=\frac{v_{e}^{2}}{2y_{e}}[/tex]

⇒[tex]a=\frac{v_{e}^{2}}{2y_{e}}+g[/tex] ⇒ [tex]a=138.20\frac{m}{s^{2} }[/tex]

Explanation:

Given that,

Mass of the object, m₁ = 23 kg

Acceleration of this object, a₁ = 57 m/s/s

Mass of another object, m₂ = 23 kg

We need to find the acceleration of another object. It can be calculated using second law of motion as :

[tex]F=ma[/tex]

[tex]a=\dfrac{F}{m}[/tex]

Here, F is same. So,

[tex]\dfrac{a_1}{a_2}=\dfrac{m_2}{m_1}[/tex]

[tex]a_2=\dfrac{a_1m_1}{m_2}[/tex]

[tex]a_2=\dfrac{57\times 23}{23}[/tex]

[tex]a_2=57\ m/s/s[/tex]

So, another object will create same acceleration as 57 m/s/s. Hence, this is the required solution.

Final answer:

The same force that accelerates an object of 23 Kg at 57 m/s² would also accelerate another object of mass 23 Kg at 57 m/s², as per Newton's second law of motion.

Explanation:

If a certain force accelerates an object of mass 23 Kg at 57 m/s², the same force would produce the same acceleration on another object of mass 23 Kg. This is because acceleration is directly proportional to force and inversely proportional to mass, according to Newton's second law of motion, which can be expressed as F = ma. Since both the force and mass are the same in this scenario, the acceleration would also be the same, which is 57 m/s².

Answer:

A. Scatterplot

Explanation:

because it is

Answer:

The answer to your question is: mass = 38.93 kg

Explanation:

Data

mass = ?

Weight = 382 N

gravity = 9.81 m/s2

Formula

Weight = mass x gravity

mass = weight / gravity

mass = 382 / 9.81         substitution

mass = 38.93 kg           result

The mass of a dog that weighs 382 N can be calculated using the weight formula w=mg, rearranged as m=w/g. Substituting the values, we find that the mass of the dog is approximately 39 kg.

To calculate the mass of a dog that weighs 382 N, we use the formula w = mg, where w is weight, m is mass, and g is the acceleration due to gravity, which on Earth is approximately 9.8 m/s². So, to find the mass, we rearrange the formula to m = w/g.

Substituting the given values into the equation, m = 382 N / 9.8 m/s² = 39.0 kg. So, the mass of the dog is approximately 39 kg when rounded to the nearest whole number.

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