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2 years ago

Calculate ∆U for each of the following cases:

Physics

2 answers:

Art [367]2 years ago

7 0

$\bold{\huge{\red{\underline{ Solution }}}}$

Here, We have to, 

Calucate change in internal energy ΔU for the following cases

We know that,

Change in internal energy = heat required + Work done

That is,

$\bold{\pink{ ΔU = Q + W }}$

Here, we have, 

$\sf{Q ( heat\: required) = + 53 kJ}$
$\sf{W ( Work\: done) = - 15 kJ}$

[ Here, + sign of Q denotes that heat is absorbed in the given chemical reaction and - sign of W denotes work done by the system ]

Subsitute the required values in the given formula :-

$\sf{ ΔU = + 53 + ( -15) }$

$\sf{ ΔU = 53 - 15 }$

$\sf{ ΔU = 38kJ }$

Hence, The change in internal energy is 38kJ and work done is by the system on the surroundings

We know that,

$\bold{\pink{ ΔU = Q + W }}$

Here, we have 

$\sf{Q ( heat\: required) = + 100 kJ}$
$\sf{W ( Work\: done) = - 62 kJ}$

[ Here, + sign of Q denotes that heat is absorbed in the given chemical reaction and - sign of W denotes work done by the system ]

Subsitute the required values in the above formula :-

$\sf{ ΔU = + 100 + ( -62) }$

$\sf{ ΔU = 100 - 62 }$

$\sf{ ΔU = 38kJ }$

Hence, The change in internal energy is 38kJ and work done is by the system on the surroundings .

We know that,

$\bold{\pink{ ΔU = Q + W }}$

Here, we have 

$\sf{Q ( heat\: required) = - 65 kJ}$
$\sf{W ( Work\: done) = - 30 kJ}$

[ Here, - sign of Q denotes that heat is evolved in the given chemical reaction and - sign of W denotes work done by the system ]

Subsitute the required values in the above formula :-

$\sf{ ΔU = - 65 +(-30) }$

$\sf{ ΔU = -65 - 30 }$

$\sf{ ΔU = - 95kJ }$

Hence, The change in internal energy is -95 kJ and work done is by the system on the surroundings .

<h3>In which of this cases does the system do work on the surroundings? </h3>

From above answer, we can conclude that ,

In all the three cases the work done is done by the system that is work is done on the surroundings by the system because work done is negative in all the three cases

Whereas, If work done is positive then work is done on the system not by the system.

dusya [7]2 years ago

3 0

Answer:

Q=+100kj,w=-15kj,Q=100kj,w=-62kj

Explanation:

when energy is exerted into a system work done is equal to zero .hence the system does work to the surrounding.

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The coefficient of static friction between the object and the disk is 0.087.

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$\Sigma F_{r} = \mu_{s}\cdot N = m\cdot \frac{v^{2}}{R}$ (1)

$\Sigma F_{y} = N - m\cdot g = 0$ (2)

Where:

$N$ - Normal force from the ground on the object, measured in newtons.

$m$ - Mass of the object, measured in newtons.

$g$ - Gravitational acceleration, measured in meters per square second.

$v$ - Linear speed of rotation of the disk, measured in meters per second.

$R$ - Distance of the object from the center of the disk, measured in meters.

By applying (2) on (1), we obtain the following formula:

$\mu_{s}\cdot m\cdot g = m\cdot \frac{v^{2}}{R}$

$\mu_{s} = \frac{v^{2}}{g\cdot R}$

If we know that $v = 0.8\,\frac{m}{s}$ , $g = 9.807\,\frac{m}{s^{2}}$ and $R = 0.75\,m$ , then the coefficient of static friction between the object and the disk is: