As a chance for a bit of extra credit, you may write a short paper, due the second class period...

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As a chance for a bit of extra credit, you may write a short paper, due the second class period after Spring Break. For this paper, you will choose your own topic and sources, but the theme of the paper must be how your chosen field of study is impacted by quantum physics. You may also choose to write about your minor field of study if this seems more appropriate. The paper must include proper citations (at least one source other than your textbook), though the format of the citations is up to you. Example sources include, but are not limited to books, popular science magazine/web site articles, newspaper articles, documentaries (not sci-fi movies), academic journals, or reputable web sites (e.g., wikipedia). You need not necessarily choose a source from the categories above, so long as you deem the source reputable and informative. If you are unable to find compelling sources, I will assist you in your selection. The paper is due by the Thursday class following the Spring holidays, viz., 4 April 2013. Submission may be either by hard copy, or electronically via email (PDF preferred, MS Word/ other acceptable). The maximum extra credit possible is equivalent to 25% of a single exam score. Your paper must adhere to the following basic requirements: • Five double-spaced 8.5 x 11 inch pages, single sided • Page count does not include citations or figures • Figures are allowed, though they do not count toward the page limit • Font size no larger than 12pt • Margins no greater than 1.5 inches (3.8 cm) • submitted in hard or soft copy (PDF strongly preferred, other formats acceptable) The content of this paper is somewhat open. The main ideas are these: • recognize key scientific concepts involved in quantum physics • relate these key concepts to the world around you and your field of study • discriminate between reliable and less reliable information given in sources • critically evaluate the information and how it relates to your field of study More concretely, you must touch on the following: • what you learned from your source • are there ideas which are, in your opinion, more or less tenable based on the evidence provided? • how the material presented relates to what you have learned in PH253 • how it may or may not be relevant to your major field of study • how it explains aspects of everyday phenomena around you You will be graded according to • whether the length requirement has been met • whether you addressed the points above • your overall description of the source material • the quality and appropriateness of the source material • the quality of your narrative and ease of written communication You can use figures/diagrams/tables, so long as they are essential to your arguments and do not take up excessive space. They will not count toward the length requirement, so please place any such item on separate pages at the end of your paper.

David · Accepted Answer

SOLUTION  
 
Quantum mechanics is  that part of physics related with phenomena in which  the action is based on  
Planck constant. The Planck constant is a very tiny amount and so this part of physics is  on the distance 
and momentum scale of atoms and elementary particles  . Action is a  physical concept related to 
dynamics and is most easily recognized in the form of angular momentum. The most appropriate way of 
expressing    quantum mechanics is that we live in a universe of quantized angular momentum and the 
Planck constant is the quantum. 
And the electric engineering is a field of engineering that generally deals with the study and application 
of electricity, electronics, and electromagnetism 
Now we will discuss the relationship between the both quantum mechanics and electrical engineering. 
quantum mechanics in relation with electrical engineering mainly focus on Maxwell's equations. But  
engineering focuses more on application of physics to solve problems. This doesn't involve much  
physics. For example, the wave-particle duality of electromagnetics. Physics studies this problem 
carefully but  Engineers don't care as long as they have useful approximations that can be used to design 
antennas, radars, etc.  
 Engineers , they tend to believe that the laws of physics and the laws of engineering are in combined 
and  engineering represents the sum total of our knowledge  .  Further, most engineers believe that   
quantum mechanics is something that they can  ignore when developing their systems.   This  may be 
true in many cases but   if you really wish to make perfect  designs, a good grasp of quantum mechanics 
can show world of possibilities for it. 
 
But only the  combination of   formulas of electronic and electrical engineering, to the  formulas  of the 
quantum mechanics is required.  From here, we should be able to develop more accurate part  of 
classical formulas and the processes .  This will provide engineers with a deeper view  into the laws that 
help in  their circuit design and     factors that they can consider in precision designs.  
 
 
We can understand it by using example of  Volt as  We all know classical definition of voltage: 
 
A single volt is defined as the difference in electric potential across a wire when an electric current of 
one ampere dissipates one watt of power.it is also equal to the potential difference between two 
parallel, infinite planes spaced 1 meter apart that create an electric field of 1 newton per coulomb.  it is 
the potential difference between two points that will impart one joule of energy per coulomb of charge 
that passes through it. 
From above we can say that volt is a singular entity but it is not the truth .in real it is a complex.  Voltage 
can be generated by a variety of mechanisms and each is based on different  factors that result to 
change the formula.  To demonstrate this, we will look at an Voltage generated by a pure E-field 
mechanism of relative charges between protons and electrons. Further it is elaborated as follows:- 
Voltage(C) = Proton Charge  +  Electron Charge 
Elementary Charge (e) =  1.602176565 ×10^−19 C 
Proton Charge = 1.602176565×10−19 C 
Proton Charge = e 
Electron Charge = −1.602176565×10−19 C  
Electron Charge = -e 
 
Proof 
Voltage (0C) =  1.602176565×10−19 C  +  −1.602176565×10−19 C 
 
Derived Formula 
                                  SOLUTION  
 
Voltage (e) = (Xe) + (Y(-e)) 
 
New Derived Unit 
e (Elementary Charge) 
 
Definition   
Voltage is the difference between positive and negative charge .  Thus Voltage is a Electrical Charge. 
But  voltage can exist when the overall charge is neutral.And in a capacitor for example we have seen 
the same mechanism of charge separation, and the effect of charge imbalance (or polarity).  In classical 
engineering this is also observed while  working with Capacitive Matrix, or mutual capacitance. 
Further in case of capacitor banks or microelectronics 
 
 
For  this equation is simple, it does not take   the distance between those charges and uncertainty in 
their locations.  Thus, measuring a voltage accurately is not possible and must be defined in terms of 
probability. 
  It is mathematically possible for protons (or electrons)  to generate a voltage (and even a current) and 
not move. 
  Further, due to conservation of energy, it is not possible to produce useful energy . 
  The equation also shows that if you increase the number of electrons,

As a chance for a bit of extra credit, you may write a short paper, due the second class period after Spring Break. For this paper, you will choose your own topic and sources, but the theme of the...

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