ProblemA new type of force was discovered by physicists with the following expression:aFnew+ Be* + 3x4%3Dwhere alpha & beta are constants, and x is the position. The expression above was obtained from the interaction of a massless Higgs Boson(a type of particle) and a black hole.Quantum physicists then decides to design and build a machine that is able to move the Higgs Boson from x2 to x1. How much work shouldthe machine do to achieve this feat? (For simplicity, consider that no energy is lost in the process)SolutionTo determine the work done we apply the followingW =dxEvaluating the above, we getW =| +e+for the limits from x¡ to xfsubstituting x1 and x2 as the limits, the work done is expressed asW =| + BX1( x15 -x25 )

Given force, Fnew=αx+βex+3x4 where, α and β are constants. Now, work done is given by-…

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University Physics Volume 3

17th Edition

ISBN:9781938168185

Author:William Moebs, Jeff Sanny

Publisher:William Moebs, Jeff Sanny

Chapter5: Relativity

Section: Chapter Questions

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Problem
A new type of force was discovered by physicists with the following expression:
a
Fnew
+ Be* + 3x4
%3D
where alpha & beta are constants, and x is the position. The expression above was obtained from the interaction of a massless Higgs Boson
(a type of particle) and a black hole.
Quantum physicists then decides to design and build a machine that is able to move the Higgs Boson from x2 to x1. How much work should
the machine do to achieve this feat? (For simplicity, consider that no energy is lost in the process)
Solution
To determine the work done we apply the following
W =
dx
Evaluating the above, we get
W =
| +
e
+
for the limits from x¡ to xf
substituting x1 and x2 as the limits, the work done is expressed as
W =
| + B
X1
( x15 -
x25 )

Expert Solution

Step 1

Given force,

$F_{n e w} = \frac{α}{x} + β e^{x} + 3 x^{4}$

where,

$α$ and $β$ are constants.

Now, work done is given by-

$W = \int_{x_{i}}^{x_{f}} {\vec{F}}_{n e w} \cdot d \vec{x} W = \int_{x_{i}}^{x_{f}} (\frac{α}{x} + β e^{x} + 3 x^{4}) d x$

Step 2

Evaluating we get,

$W = \int_{x_{i}}^{x_{f}} (\frac{α}{x} + β e^{x} + 3 x^{4}) d x W = α [\ln x] + β [e^{x}] + 3 [\frac{x^{5}}{5}] f o r t h e l i m i t x_{i} t o x_{f}$

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