How many σ bonds and π bonds does the co2 molecule have?

The backbone of the DNA molecule is formed by alternating sugar and phosphate groups. The nitrogenous bases are located in the interior of the molecule.

The backbone of the DNA molecule is made up of the alternating sugar and phosphate groups. The sugar and phosphate groups are bonded by covalent bonds, and they line up on the outside of each strand. The nitrogenous bases, which include adenine (A), thymine (T), cytosine (C), and guanine (G), are stacked in the interior of the DNA molecule.

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The backbone of a DNA molecule is formed from alternating sugar and phosphate groups of nucleotides. The nitrogenous bases, which are not part of the backbone, protrude from it and are involved in the formation of the double helix structure.

The backbone of the DNA molecule consists of alternating sugar and phosphate groups. A nucleotide, which is the building block of DNA, consists of three components: a nitrogenous base, a pentose sugar, and a phosphate group. The backbone is formed by the bonding of the phosphate group of one nucleotide to the sugar of the next nucleotide, creating a chain of sugar-phosphate bonds.

For instance, the phosphate group is attached to the 5' carbon of one nucleotide and the 3' carbon of the next nucleotide. In this sense, the DNA molecule can be visualized as a twisted ladder where the backbone represents the rails of the ladder and the nitrogenous bases represent the steps.

It's important to note that the nitrogenous bases are not part of the backbone; They stick out from the backbone and are involved in hydrogen bonding with the nitrogenous bases of the complementary DNA strand, resulting in a double helix structure. The two strands of the DNA run in opposite directions making them antiparallel.

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Answer:

[tex]\rho = 0.50 g/L[/tex]

Explanation:

As we know that

PV = nRT

here we have

[tex]P = 1.0 atm[/tex]

[tex]P = 1.013 \times 10^5 Pa[/tex]

so we have

[tex]V = 1.4 \times 10^{-3} m^3[/tex]

T = 290 K

now we have

[tex](1.013 \times 10^5)(1.4 \times 10^{-3}) = n(8.31)(290)[/tex]

[tex]n = 0.06 [/tex]

now the mass of gas is given as

[tex]m = n M[/tex]

[tex]m = (0.06)(28)[/tex]

[tex]m = 1.65 g[/tex]

now density of gas when its volume is increased to 3.3 L

so we will have

[tex]\rho = \frac{m}{V}[/tex]

[tex]\rho = \frac{1.65 g}{3.3 L}[/tex]

[tex]\rho = 0.50 g/L[/tex]

Final answer:

The density of a gas can be calculated using the ideal gas law, which states that PV = nRT. To find the density, we can rearrange the equation and substitute the given values.

Explanation:

The density of a gas can be calculated using the ideal gas law, which states that PV = nRT, where P is the pressure, V is the volume, n is the number of moles, R is the ideal gas constant, and T is the temperature. To find the density, we can rearrange the equation as follows:

Density = mass/volume = (molar mass * n) / V

Using the given information, we can substitute the values into the equation and solve for the density.

Answer:

5295.3 N

Explanation:

According to law of momentum conservation, the change in momentum of the ball shall be from the momentum generated by the batter force

mv + P = mV

P = mV - mv = m(V - v)

Since the velocity of the ball before and after is in opposite direction, one of them is negative

P = 0.14(44.8 - (-19.5)) = 9 kg m/s

Hence the force exerted to generate such momentum within 1.7ms (0.0017s) is

F = P/t = 9/0.0017 = 5295.3 N

Answer:

a) W = 10995.6 J

b) W = - 9996 J

c) Kf = 999.6 J

d) v = 5.77 m/s

Explanation:

Given

m = 60 Kg

h = 17 m

a = g/10

g = 9.8 m/s²

a) We can apply Newton's 2nd Law as follows

∑Fy = m*a     ⇒     T - m*g = m*a     ⇒    T = (g + a)*m

where T is the force exerted by the cable

⇒    T = (g + (g/10))*m = (11/10)*g*m = (11/10)*(9.8 m/s²)*(60 Kg)

⇒    T = 646.8 N

then we use the equation

W = F*d = T*h = (646.8 N)*(17 m)

W = 10995.6 J

b) We use the formula

W = m*g*h     ⇒    W = (60 Kg)(9.8 m/s²)(-17 m)

⇒    W = - 9996 J

c) We have to obtain Wnet as follows

Wnet = W₁ + W₂ = 10995.6 J - 9996 J

⇒    Wnet = 999.6 J

then we apply the equation

Wnet = ΔK = Kf - Ki = Kf - 0 = Kf    

⇒  Kf = 999.6 J

d) Knowing that

K = 0.5*m*v²    ⇒    v = √(2*Kf / m)

⇒    v = √(2*999.6 J / 60 Kg)

⇒    v = 5.77 m/s

Answer:

Explanation:

mass =60kg d = 17m  a=g/10

(a) work done on the astronaut by the force from the helicopter = fd

but f =m(g+a)

 w= m( g+g/10)d

wt = 11/10 mgd

w =11/10 * 60 *9.8 * 17 = 10995.6J  = 1IKJ

(b) workdone  by her weight = -mgh

   = 60*9.8* 17 = -9996J

(C) Kinetic energy = wt + w

                             = (10995.6 - 9996)J = 999.6J

(d) Kinetic energy =1/2m[tex]v^{2}[/tex]

hence velocity = [tex]\sqrt{2ke/m}[/tex] = 5.777m/s

Explanation:

Here velocity of ball and bat are in opposite direction.

Velocity of ball = 40 m/s

Velocity of bat = 18 m/s

Since they are in opposite direction relative velocity is given by,

           Relative velocity = 40 + 18 = 58 m/s

Distance to home plate = 18 m

We have

                Displacement = Velocity x Time

                           18 = 58 x Time

                          Time = 0.3 seconds

Option A is the correct answer.

Final answer:

To find the two possible frequencies of the untuned piano string, we can use the formula for beat frequency. From the given information, the original frequency of the untuned string can be either 266.0 Hz or 262.0 Hz. To find the percentage increase in tension on the untuned string, we can use the formula for calculating percentage increase.

Explanation:

To find the two possible frequencies of the untuned piano string, we can use the formula for beat frequency:

Beat frequency = |Frequency of the first string - Frequency of the second string|

In this case, the beat frequency is given as 2.00 s. The frequency of the first string is 264.0 Hz. Let's assume the frequency of the second string is x Hz.

So, we can set up the equation:

2.00 = |264.0 - x|

Solving for x, we get two possible frequencies: 266.0 Hz and 262.0 Hz.

To find the original frequency of the untuned string, we can use the formula:

Original frequency = Frequency of the first string ± Beat frequency

For positive beat frequencies, the original frequency would be:

Original frequency = 264.0 + 2.00 = 266.0 Hz

For negative beat frequencies, the original frequency would be:

Original frequency = 264.0 - 2.00 = 262.0 Hz

To find the percentage increase in tension on the untuned string, we can use the formula:

Percentage increase = (Change in tension / Original tension) x 100

Since the tension on the first string is unchanged (as it is the tuned string), the change in tension on the untuned string is equal to the change in frequency. Assuming the original frequency of the untuned string is 262.0 Hz:

Change in tension = |Original frequency - New frequency|

Change in tension = |262.0 - 264.0| = 2.0 Hz

Therefore, the percentage increase in tension on the untuned string is:

(2.0 / 262.0) x 100 = 0.763%

Answer:

Explanation:

Kinetic energy of the block

= 1/2 m v²

= .5 x 3 x 4 x 4

= 24 J

Negative work of - 24 J is required to be done on this object to bring it to rest.

magnitude of acceleration due to frictional force

= force / mass

2 / 3

= 0 .67 m /s²

Let the body slide by distance d before coming to rest so work done by force = Kinetic energy

=  2 x d = 24

d = 12 m

The magnitude of the work done to bring the block to rest is 2 times the distance the block slides. The magnitude of the acceleration of the block is 2/3 m/s^2. The block slides a distance of 8/3 m before it comes to rest.

The work done on an object is given by the equation:

Work = Force x Distance

In this case, the work done on the block to bring it to rest is equal to the force applied multiplied by the distance the block slides.

Given that the force exerted by the surface is 2 Newtons, we can calculate the magnitude of the work done:

Work = 2 N x Distance

To determine the distance the block slides, we need to calculate its deceleration using Newton's second law:

Force = mass x acceleration

Since the friction force is constant and in the opposite direction of motion, we can write:

2 N = 3 kg x acceleration

Solving for acceleration, we find:

acceleration = 2 N / 3 kg

With the acceleration calculated, we can use the kinematic equation:

vf^2 = vi^2 + 2ad

Since the final velocity is 0 (block comes to rest), the equation simplifies to:

0 = (4 m/s)^2 + 2(-acceleration)d

Solving for distance, we find:

d = (4 m/s)^2 / (2 x -acceleration)

Now, we can substitute the calculated acceleration into the equation to find the distance the block slides.

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Answer:

becomes narrower

Explanation:

Confidence intervals for the population mean μ and population proportion p becomes narrower as the size of the sample increases.

As,the sample size increases,standard error decreases,so margin of error decreases and hence width of CI decreases.

Answer:

Option c

Explanation:

Soil tilth refers to the physical condition of the soil, particularly with regards to the suitability of the soil for the growth of crop.

The determinants of the tilth in the soil incorporates the arrangement and steadiness of aggregated particles of the soil, pace of water penetration, level of air circulation, dampness content and seepage.

Thus option C follows the definition of the soil tilth.

Answer:

Option (C)

Explanation:

The soil tilth is defined as one of the physical property that determines the necessary condition for the better growth of plants and crops.

This property depends upon various factors such as-

These are the main features that characterize the soil tilth, and fulfilling the above required necessary condition, a plant grows in a much better way.

Thus, the correct answer is option (C).

The mass of Actinium 227 left is 0.0078 kg

Explanation:

The amount of mass left of a radioactive isotope after time t is given by the equation:

[tex]m(t) = m_0 (\frac{1}{2})^{-\frac{t}{\tau_{1/2}}}[/tex]

where

[tex]m_0[/tex] is the initial amount of the sample

t is the time

[tex]\tau_{\frac{1}{2}}[/tex] is the half-life of the isotope

For the sample of Actinium 227 in this problem,

[tex]m_0 = 2 kg[/tex]

[tex]\tau_{1/2}=20 years[/tex]

t = 160 years

Substituting into the equation,

[tex]m(160) = (2 kg) (\frac{1}{2})^{-\frac{160}{20}}=0.0078 kg[/tex]

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The work done is 1425 J

Explanation:

The work done by a force to move an object is given by

[tex]W=Fd cos \theta[/tex]

where

F is the magnitude of the force

d is the displacement

[tex]\theta[/tex] is the angle between the direction of the force and of the displacement

For the suitcase in this problem, we have:

F = 95.0 N is the force applied

d = 15.0 m is the displacement

[tex]\theta=0[/tex], since the force is parallel to the displacement

Substituting, we find

[tex]W=(95.0)(15.0)(cos 0)=1425 J[/tex]

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Answer:

True

Explanation:

t = Time taken = 6 s

u = Initial velocity = 0

v = Final velocity

a = Acceleration = 34.3 m/s²

[tex]v=u+at\\\Rightarrow v=0+34.3\times 6\\\Rightarrow v=205.8\ m/s[/tex]

After the six seconds the acceleration from the rocket stops. After the fuel is exhausted the velocity of the rocket will be 205.8 m/s which will reduce by the acceleration due to gravity (i.e., 9.81 m/s²).

Free fall is the state of a body where the only the force of gravity is acting on it other forces are not acting on it.

Hence, the statement here is true.

Answer:

(A) Vf = 13.8 m/s

(B)  Vf = 15.1 m/s      

Explanation:

length of rope (L) = 35 m

angle to the vertical = 44 degrees

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

(A) from conservation of energy

final kinetic energy + final potential energy = initial kinetic energy + initial potential energy

0.5m(Vf)^{2} + mg(Hf) =  0.5m(Vi)^{2} + mg(Hi)

where

m = mass

Hi = initial height = 35 cos 44 = 25.17

Hf = final height = length of vine = 35 m

Vi = initial velocity = 0 since he starts from rest

Vf = final velocity

the equation now becomes

0.5m(Vf)^{2} + mg(Hf) = mg(Hi)

0.5m(Vf)^{2} = mg (Hi - Hf)

0.5(Vf)^{2} = g (Hi - Hf)

0.5(Vf)^{2} = 9.8 x (25.17 - 35)

0.5(Vf)^{2} = - 96.3  (the negative sign tells us the direction of motion is downwards)

Vf = 13.8 m/s

(B) when the initial velocity is 6 m/s the equation remains

      0.5m(Vf)^{2} + mg(Hf) =  0.5m(Vi)^{2} + mg(Hi)

       m(0.5(Vf)^{2} + g(Hf)) =  m(0.5(Vi)^{2} + g(Hi))

      0.5(Vf)^{2} + g(Hf) = 0.5(Vi)^{2} + g(Hi)

      0.5(Vf)^{2} = 0.5(Vi)^{2} + g(Hi) - g(Hf)

       0.5(Vf)^{2} = 0.5(6)^{2} + (9.8 x (25.17 - 35))

        0.5(Vf)^{2} =  -114.3  ( just as above, the negative sign tells us the direction of motion is downwards)      

       Vf = 15.1 m/s

Answer:

a) [tex]v_{f} \approx 0.328\,\frac{m}{s}[/tex], b) [tex]v_{f} \approx 6.009\,\frac{m}{s}[/tex]

Explanation:

Let consider that bottom has a height of zero. The motion of Tarzan can be modelled after the Principle of Energy Conservation:

[tex]U_{g,1} + K_{1} = U_{g,2} + K_{2}[/tex]

The final speed is:

[tex]K_{2} = U_{g,1} - U_{g,2} + K_{1}[/tex]

[tex]\frac{1}{2}\cdot m \cdot v_{f}^{2} = m\cdot g \cdot L\cdot (\cos \theta_{2}-\cos \theta_{1}) + \frac{1}{2}\cdot m \cdot v_{o}^{2}[/tex]

[tex]v_{f}^{2} = 2 \cdot g \cdot L \cdot (\cos \theta_{2} - \cos \theta_{1}) + v_{o}^{2}[/tex]

[tex]v_{f} = \sqrt{v_{o}^{2}+2\cdot g \cdot L \cdot (\cos \theta_{2}-\cos \theta_{1})}[/tex]

a) The final speed is:

[tex]v_{f} = \sqrt{(0\,\frac{m}{s} )^{2}+2\cdot (9.807\,\frac{m}{s^{2}} )\cdot (35\,m)\cdot (\cos 0^{\textdegree}-\cos 44^{\textdegree})}[/tex]

[tex]v_{f} \approx 0.328\,\frac{m}{s}[/tex]

b) The final speed is:

[tex]v_{f} = \sqrt{(6\,\frac{m}{s} )^{2}+2\cdot (9.807\,\frac{m}{s^{2}} )\cdot (35\,m)\cdot (\cos 0^{\textdegree}-\cos 44^{\textdegree})}[/tex]

[tex]v_{f} \approx 6.009\,\frac{m}{s}[/tex]

Final answer:

A wooden block that floats in an unknown liquid with only one-third submerged indicates that the unknown liquid is more dense than water.

Explanation:

When the wooden block is placed in an unknown liquid and only one-third of it is submerged, it suggests that the block is less dense than the unknown liquid. This is due to the principle of buoyancy, which states that an object will displace a volume of fluid that is equal to its own weight. Since the wooden block floats higher in the unknown liquid compared to how it floats in water, where it must submerge more to displace enough water to equal its weight, we can conclude that the unknown liquid is more dense than water.

Final answer:

The escape velocity of a spherical asteroid with a given radius and given gravitational acceleration can be calculated using a special formula. The distance a particle travels from the surface when it leaves it at a given radial velocity can be determined using the projectile height equation. The speed at which an object hits an asteroid after falling from a given height can be calculated using the falling object terminal velocity equation.

Explanation:

(a) Escape velocity can be defined as the minimum speed required for an object to escape the gravitational pull of a celestial body. To calculate the escape velocity on a spherical asteroid we can use the formula:

escape velocity = sqrt(2 * acceleration due to gravity * radius).

Using the given values, the escape velocity of a spherical asteroid is:

exhaust rate = sqrt(2 * 3.00 m/s2 * 500 000 m) = 6928 m/s.

(b) To calculate the distance from the surface that a particle will travel when it leaves the surface of the asteroid with a radial velocity of 1000 m/s, we can use the formula for the height of the projectile:

Height = (radial velocity)2 / (2 * acceleration due to gravity).

After entering the specified values, the particle travels the distance:

Altezza = (1.000 m/s)2 / (2 * 3,00 m/s2) = 166.666,67 m.

(c) To calculate the speed at which an object hits an asteroid as it falls 1000 km above the surface, we can use the equation for the final velocity of the falling object:

Final velocity = sqrt (initial velocity2 + 2 * acceleration due to gravity * height).

Substituting the given values, the object hits the asteroid with a speed of:

Final velocity = square(0 + 2 * 3.00 m/s2 * 1,000,000 m) = square(6,000,000 m2/s2) = 2,449 m/s.

Answer:

a. The temperature of the ice/water system remains constant.

c. Heat energy enters the ice/water system.

Explanation:

As we know that when ice coverts into the water then it is known as phase transfer. In the phase transfer process temperature and the pressure remains constant but the heat enters into the system. This heat is responsible for melting the ice. The heat is taken by ice is known as latent heat.

Therefore the option "a" and "c" are correct.

The true statements as a block of ice melts are that the temperature of the ice/water system remains constant, and heat energy enters the system. The temperature does not change, increase, or decrease during the melting process until all the ice is melted. So the correct options are a and c.

As a block of ice melts, several key processes occur within the ice/water system:

Therefore, from the options provided:

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Answer

Given,

Flow rate of river is equal to 300,000 L/s.

Width of river = 18 m

and depth of river = 22 m

a) Average speed of river

     Q = 300,000 L/s

         = 300 m³/s

     Q = Av

     [tex]v = \dfrac{Q}{A}[/tex]

     [tex]v = \dfrac{300}{18 \times 22}[/tex]

     [tex]v = \dfrac{300}{396}[/tex]

     [tex]v = 0.757\ m/s[/tex]

b) Average speed when river is widen to 63 m and depth is increased to

     [tex]v = \dfrac{Q}{A}[/tex]

     [tex]v = \dfrac{300}{63 \times 42}[/tex]

     [tex]v = \dfrac{300}{2646}[/tex]

     [tex]v = 0.113\ m/s[/tex]

Final answer:

The average speed of the river in the gorge is 0.75 m/s, and downstream of the falls, when the river widens and its depth increases, the average speed decreases to 0.125 m/s.

Explanation:

To calculate the average speed of the river at Huka Falls, we can use the formula for flow rate, which is the volume of fluid passing a point in the river per unit of time:

Flow rate (Q) = Area (A)  imes Velocity (V)

(a) Average speed in the gorge: Given that the flow rate (Q) is 300,000 liters per second (which is equal to 300 cubic meters per second, since 1,000 liters is equal to 1 cubic meter), and the cross-sectional area of the river in the gorge (A) is 20 meters wide  imes 20 meters deep (400 square meters), we can solve for velocity (V) using the formula:

Q = A  imes V

300 m³/s = 400 m²  imes V

V = 300 m³/s \/ 400 m²

V = 0.75 meters per second

(b) Average speed downstream of the falls: Downstream, the river widens to 60 meters and deepens to an average of 40 meters, so the cross-sectional area is 2,400 square meters. Using the same flow rate, we can find the new velocity:

Q = A  imes V

300 m³/s = 2,400 m²  imes V

V = 300 m³/s \/ 2,400 m²

V = 0.125 meters per second

To find the final angular velocity of the system, we need to apply the principle of conservation of angular momentum. The final angular momentum can be obtained by equating the initial angular momentum and the final angular momentum of the system. Solving for the final angular velocity gives us a value of approximately 38.54 rad/s.

To find the final angular velocity of the system, we need to apply the principle of conservation of angular momentum. The initial angular momentum of the system is given by:

Li = Itωt + Irωr

Where It and Ir are the moments of inertia of the turntable and the runner respectively, and ωt and ωr are their respective angular velocities.

Since the runner comes to rest relative to the turntable, ωr = 0. Therefore, the final angular momentum of the system is:

Lf = Itωt

Using the conservation of angular momentum principle, we can set Li equal to Lf:

Itωt = Itωt

Substituting the given values:

81.0kg × m² × 0.190rad/s = It × ωt

Solving for ωt, we find that the final angular velocity of the system is approximately 38.54 rad/s.

To find the final angular velocity of the runner and turntable system, we apply conservation of angular momentum. The final angular velocity is calculated to be 0.611 rad/s. This involves determining the initial angular momenta of both the runner and the turntable, then using the total moment of inertia to find the final velocity.

To find the final angular velocity of the system when the runner comes to rest relative to the turntable, we need to apply the principle of conservation of angular momentum. The initial angular momentum of the system (runner plus turntable) must equal the final angular momentum since there are no external torques acting.

Step-by-Step Calculation :

Determine the initial angular momentum of the runner:

Determine the initial angular momentum of the turntable:

Calculate the total initial angular momentum:

Find the final angular velocity:

The final angular velocity of the system is 0.611 rad/s.

Answer:71 dB

Explanation:

Given

sound Level [tex]\beta _1=124 dB[/tex]

distance [tex]r_1=5.01 m[/tex]

From sound Intensity

[tex]\beta =10dB\log (\frac{I_1}{I_0})[/tex]

[tex]124=10dB\log (\frac{I_1}{I_0})[/tex]

[tex]12.4=\log (\frac{I_1}{I_0})[/tex]

[tex]I_1=(1\times 10^{-12})\times 10^{12.4}[/tex]

[tex]I_1=2.51 W/m^2[/tex]

we know Intensity [tex]I\propto ^\frac{1}{r^2}[/tex]

[tex]I_1r_1^2=I_2r_2^2[/tex]

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

[tex]I_2=2.51\cdot (\frac{5.01}{2.25\times 10^3})^2[/tex]

[tex]I_2=1.24\times 10^{-5} W/m^2[/tex]

Sound level corresponding to [tex]I_2[/tex]

[tex]\beta _2=10\log (\frac{I_2}{I_0})[/tex]

[tex]\beta _2=10\log (\frac{1.24\times 10^{-5}}{1\times 10^{-12}})[/tex]

[tex]\beta _2=70.93\approx 71 dB[/tex]

Answer:

a) V = 0.085 m^3

b) m = 17 kg

Explanation:

1) Data given

mb = 68 kg (mass for the block)

20% of the block volume is floating

100-20= 80% of the block volume is submerged

2) Notation

mb= mass of the block

Vw= volume submerged

mw = mass water displaced

V= total volume for the block

3) Forces involved (part a)

For this case we have two forces the buoyant force (B), defined as the weight of water displaced acting upward and the weight acting downward (W)

Since we have an equilibrium system we can set the forces equal. By definition the buoyant force is given by :

B = (mass water displaced) g = (mw) g   (1)

The definition of density is :

[tex] \rho_w = \frac{m_w}{V_w} [/tex]

If we solve for mw we got [tex]m_w = \rho_w V_w [/tex]  (2)

Replacing equation (2) into equation (1) we got:

[tex] B = \rho_w V_w g [/tex] (3)

On this case Vw represent the volume of water displaced = 0.8 V

If we replace the values into equation (3) we have

0.8 ρ_w V g = mg  (4)

And solving for V we have

 V =  (mg)/(0.8 ρ_w g )

We cancel the g in the numerator and the denominator we got

V = (m)/(0.8 ρ_w)

V = 68kg /(0.8 x 1000 kg/m^3) = 0.085 m^3

4) Forces involved (part b)

For this case we have bricks above the block, and we want the maximum mass for the bricks without causing  it to sink below the water surface.

We can begin finding the weight of the water displaced when the block is just about to sink (W1)

W1 = ρ_w V g

W1 = 1000 kg/m^3 x 0.085 m^3 x 9.8 m/s^2 = 833 N

After this we can calculate the weight of water displaced before putting the bricks above (W2)

W2 = 0.8 x 833 N = 666.4 N

So the difference between W1 and W2 would represent the weight that can be added with the bricks (W3)

W3 = W1 -W2 = 833-666.4 N = 166.6 N

And finding the mass fro the definition of weight we have

m3 = (166.6 N)/(9.8 m/s^2) = 17 Kg

Final answer:

The volume of the block of wood and the maximum mass of bricks it can carry without sinking are determined using principles of buoyancy and uniform density.

Explanation:

(a) To determine the volume of the block of wood, we use the fact that 20.0% of its volume is above the water. Given a uniform density, this means the submerged volume is 80% of the total volume. Hence, the volume of the block is 0.8 x (68.0 kg / 920 kg/m³) = 0.472 m³.

(b) The maximum mass of bricks that can be loaded without sinking the block can be calculated using the concept of buoyancy. The buoyant force equals the weight of the water displaced, so the mass of the bricks should not exceed the mass of the water displaced by the volume of the submerged part of the block. Therefore, the maximum mass of bricks is 0.472 m³ x 1100 kg/m³ x 9.8 m/s² = 5148.64 kg.

Answer:

 θ₂ = 3 θ₁

Explanation:

given,

telescope of lens diameter = 12 inch

another telescope of lens diameter = 4 inch

comparison of resolution power.

Using the formula of resolution

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

for diameter = 12 inch

 [tex]\theta_1 = \dfrac{1.22 \lambda}{D_1}[/tex].....(1)

for diameter = 4 inch

 [tex]\theta_2 = \dfrac{1.22 \lambda}{D_2}[/tex].......(2)

dividing equation (2) from (1)

[tex]\dfrac{\theta_2}{\theta_1} = \dfrac{D_1}{D_2}[/tex]

now,

[tex]\dfrac{\theta_2}{\theta_1} = \dfrac{12}{4}[/tex]

[tex]\dfrac{\theta_2}{\theta_1} =3[/tex]

 θ₂ = 3 θ₁

hence, we can say that resolution of telescope of 12 inch is 3 time smaller than the resolution of 4 inch telescope.

Answer:

t = 0.0735 m

Explanation:

Angular acceleration of the flywheel is given as

[tex]\alpha = 3 rad/s^2[/tex]

now after t = 8 s the speed of the flywheel is given as

[tex]\omega = \alpha t[/tex]

[tex]\omega = 3 \times 8 [/tex]

[tex]\omega = 24 rad/s[/tex]

now rotational kinetic energy of the wheel is given as

[tex]K = \frac{1}{2}I\omega^2[/tex]

[tex]K = \frac{1}{2}(\frac{1}{2}mR^2)(24^2)[/tex]

[tex]800 = \frac{1}{4}m(0.23)^2(24^2)[/tex]

[tex]m = 105 kg[/tex]

now we have

[tex]m = \rho (\pi R^2) t[/tex]

[tex]105 = 8600(\pi \times 0.23^2) t[/tex]

[tex]t = 0.0735 m[/tex]

We have that for the Question, it can be said that  thickness must it have to store 800 J of kinetic energy at t = 8.00 s

h=0.0735m

From the question we are told

Generally the equation for the   is mathematically given as

[tex]N=\pir^2h*P\\\\N=3.14*(23*10^{-2}^2)*h*8600\\\\N=1428.5h\\\\[/tex]

Therefore

[tex]E=\frac{1}{2}Iw^2\\\\800=\frac{1}{2}*(\frac{NR^2}{2}w^2)\\\\800=\frac{1}{2}*(\frac{(1428.523*10^{-2})^2}{2}(2*8)^2)[/tex]

h=0.0735m

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The change in internal energy of the system is +187 J

Explanation:

According to the first law of thermodynamics, the change in internal energy of a system is given by the equation:

[tex]\Delta U = Q + W[/tex]

where

[tex]\Delta U[/tex] is the change in internal energy

Q is the heat absorbed by the system

W is the work done on the system

For the system in this problem, we have

W = +108 J is the work done on it

Q = +79 J is the hear added to it

So, the change in internal energy is

[tex]\Delta U = 108 + 79 = +187 J[/tex]

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Answer: Thermal comductivity (K) is 3.964x 10 ^-3 W/m.k

Explanation:

Thermal comductivity K = QL/A∆T

Q= Amount of heat transferred through the material in watts = 75W

L= Distance between two isothermal planes = 0.740mm

A= Area of the surface in square metres = 2m^2

∆T= Temperature change = (37-30) °C.

Solving this : K =( 75 x 0.740 x 10^-3)/ 2 x (37-30)

K = 3.964x 10 ^-3 W/m.k

The question pertains to calculating the thermal conductivity of human skin, a Physics concept linked to heat transfer. By using Fourier's Law of heat conduction, and rearranging the formula to solve for thermal conductivity using given data, an approximate thermal conductivity can be obtained.

The query is related to the determination of thermal conductivity of human skin based on the known parameters. This phenonmenon belongs to the domain of Physics, specifically heat transfer. Here, thermal conductivity is the measure of a material's ability to conduct heat. In this scenario, you have to consider the heat conduction through the skin, which relies on Fourier's Law of heat conduction. It can be represented as:

Q = (k*A*(T1 - T2))/d

Where, Q is the heat transfer rate, k is the thermal conductivity, A is the area of heat transfer, T1 and T2 are the initial and final temperatures, and d is the thickness of the material, in this case, the skin.

From the given data, you can plug in the values into this formula. However, our primary objective is to find out 'k'. Rearranging the formula to find k gives us:

k = (Q * d) / (A * (T1 - T2))

Now, if we put all the given values into the formula, we get:

k = (75 W * 0.00074 m) / (2 m^2 * (37°C - 30°C))

Solving this would provide us with the estimate of thermal conductivity of the skin.

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Answer:

1) [tex]\Delta L= 0.612\ m[/tex]

2) a. [tex]\Delta V_G=0.57\ L[/tex]

   b. [tex]\Delta V_S=0.021\ L[/tex]

   c. [tex]V_0=0.549\ L[/tex]

Explanation:

1)

∴Change in temperature:

[tex]\Delta T=T_f-T_i[/tex]

[tex]\Delta T=25-(-15)[/tex]

We have the equation for change in length as:

[tex]\Delta L= L.\alpha. \Delta T[/tex]

[tex]\Delta L= 1275\times 12\times 10^{-6}\times 40[/tex]

[tex]\Delta L= 0.612\ m[/tex]

2)

Given relation:

[tex]\Delta V=V.\beta.\Delta T[/tex]

where:

[tex]\Delta V[/tex]= change in volume

V= initial volume

[tex]\Delta T[/tex]=change in temperature

a)

final temperature of gasoline, [tex]T_{Gf}=25^{\circ}C[/tex]

∴Change in temperature of gasoline,

[tex]\Delta T_G=T_{Gf}-T_{Gi}[/tex]

[tex]\Delta T_G=25-15[/tex]

[tex]\Delta T_G=10^{\circ}C[/tex]

Now,

[tex]\Delta V_G= V_G.\beta_G.\Delta T_G[/tex]

[tex]\Delta V_G=60\times 950\times 10^{-6}\times 10[/tex]

[tex]\Delta V_G=0.57\ L[/tex]

b)

final temperature of tank, [tex]T_{Sf}=25^{\circ}C[/tex]

∴Change in temperature of tank,

[tex]\Delta T_S=T_{Sf}-T_{Si}[/tex]

[tex]\Delta T_S=25-15[/tex]

[tex]\Delta T_S=10^{\circ}C[/tex]

Now,

[tex]\Delta V_S= V_S.\beta_S.\Delta T_S[/tex]

[tex]\Delta V_S=60\times 35\times 10^{-6}\times 10[/tex]

[tex]\Delta V_S=0.021\ L[/tex]

c)

Quantity of gasoline spilled after the given temperature change:

[tex]V_0=\Delta V_G-\Delta V_S[/tex]

[tex]V_0=0.57-0.021[/tex]

[tex]V_0=0.549\ L[/tex]

Explanation:

A radio galaxy is a galaxy with a powerful radio luminance relative to the stars'  visible and infrared luminosity. Radio galaxies can emit strong and  speedy particle jets. They inject in their surroundings high amounts of kinetic energy. Many radio galaxies have jets of  plasma shooting out in opposite direction. Thus they ionize the gases surrounding them.

Answer:

Explanation:

To find out the angular velocity of merry-go-round after person jumps on it , we shall apply law of conservation of ANGULAR momentum

I₁ ω₁ + I₂ ω₂ = ( I₁  + I₂ ) ω

I₁ is moment of inertia of disk , I₂ moment of inertia of running person , I is the moment of inertia of disk -man system , ω₁ and ω₂ are angular velocity of disc and man .

I₁ = 1/2 mr²

= .5 x 175 x 2.13²

= 396.97 kgm²

I₂ = m r²

= 55.4 x 2.13²

= 251.34 mgm²

ω₁ = .651 rev /s

= .651 x 2π rad /s

ω₂ = tangential velocity of man / radius of disc

= 3.51 / 2.13

= 1.65 rad/s

I₁ ω₁ + I₂ ω₂ = ( I₁  + I₂ ) ω

396.97 x  .651 x 2π + 251.34 x 1.65 = ( 396.97 + 251.34 ) ω

ω = 3.14 rad /s

kinetic energy = 1/2 I ω²

= 3196 J

Answer:

112.06 kg - Thats heavy !

Explanation:

Let's do force balance here. Let the object of our interest be George. The forces acting on him are the tension in  the upward direction, his weight in the downward direction and the centrifugal force in the downward direction. Considering the upward and downward directions on the y-axis and f=given the fact that George doesn't move up or down, the forces are balanced along the y-axis. Hence doing force balance:

magnitude of forces upward =magnitude of forces downward

i.e., Tension(T) = Weight(mg) + Centrifugal force (mv²/r)

where: 'm' is the mass of George, g is the acceleration due to gravity (9.8 m/s²). v is the speed with which George moves (14.1 m/s) and r is the radius of the circle in which he's moving at the instant (Here since he's swinging on the rope, he moves in a circle with radius as the length of the rope and hence r=7.3m).

therefore, T = m (9.8 + (14.1)²/7.3) = 4150 N

Therefore, m = 112.06 kg

Answer:

the initial speed of the object is 6.26 m/s

Explanation:

given information:

distance, s = 10 m

the coefficient of kinetic friction, μ = 0.2

we use the equation where the kinetic energy is equal to the friction force.

kinetic energy, KE = [tex]\frac{1}{2} mv^{2}[/tex]

friction work,  W = F(friction) s

KE = W

[tex]\frac{1}{2} mv^{2}[/tex] = F(friction) s

where, F(friction) = μ N, N is normal force (N = m g)

                            = μ m g

so,

[tex]\frac{1}{2} mv^{2}[/tex] = μ m g s

[tex]\frac{1}{2} v^{2}[/tex] = μ g s

[tex]v^{2}[/tex] = 2 μ g s

  = 2 (0.2) (9.8) (10)

  = 39.2

hence,

v = [tex]\sqrt{3.92}[/tex]

  = 6.26 m/s

The initial speed [tex]\( v_i \)[/tex] of the sled was approximately[tex]\( 6.26 \, \text{m/s} \).[/tex]

The initial speed of the object can be found using the work-energy principle, which states that the work done by friction will be equal to the change in kinetic energy of the sled.

First, let's calculate the work done by friction. The force of friction [tex]\( F_{\text{friction}} \)[/tex] is given by the product of the normal force \( N \) and the coefficient of kinetic friction [tex]\( \mu_k \):[/tex]

[tex]\[ F_{\text{friction}} = \mu_k N \][/tex]

[tex]\[ W = F_{\text{friction}} d = \mu_k m g d \][/tex]

[tex]\[ \Delta KE = 0 - \frac{1}{2} m v_i^2 = -\frac{1}{2} m v_i^2 \][/tex]

 According to the work-energy principle, the work done by friction is equal to the change in kinetic energy:

[tex]\[ \mu_k m g d = -\frac{1}{2} m v_i^2 \][/tex]

Solving for \( v_i \), we get:

[tex]\[ v_i^2 = -2 \mu_k g d \][/tex]

[tex]\[ v_i = \sqrt{-2 \mu_k g d} \][/tex]

 Given that [tex]\( \mu_k = 0.20 \), \( g = 9.81 \, \text{m/s}^2 \), and \( d = 10 \, \text{m} \),[/tex] we can plug in these values:

[tex]\[ v_i = \sqrt{-2 \times 0.20 \times 9.81 \times 10} \][/tex]

[tex]\[ v_i = \sqrt{39.24} \][/tex]

[tex]\[ v_i \approx 6.26 \, \text{m/s} \][/tex]

Therefore, the initial speed \( v_i \) of the sled was approximately[tex]\( 6.26 \, \text{m/s} \).[/tex]

The answer is: [tex]6.26 \, \text{m/s}.[/tex]