Applications of computational physics?

In summary, computational physics has a wide range of practical applications, thanks to advancements in computing power and algorithms. It is used in materials research, condensed matter physics, and various other fields of physics. The American Physical Society website is a good resource for finding links to specific areas of study. Additionally, computational physicists can also find jobs in finance, using their skills to model complex systems.
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What are some of the more practical applications, if there are any, of computational physics?
 
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  • #2
Actually I can think of quite a lot - and this is mostly possible due to the increases in computing power and better algorithms over the last 2 decades.

Here is a good overview from Caltech - http://library.caltech.edu/sherman/collections.htm

Science and engineering memebers of the Materials Research Society publish quite a lot about computational physics as applied to materials - e.g. http://www.mrs.org/meetings/spring2000/program/updsym/ProgramBookO.html

I am sure ZapperZ and Gokul could add quite a bit on this subject.
 
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  • #3
Computational physics has applications to pretty much all research going on in physics. Typically you can use more complex models to compare with experiment by using computer simulations. I'm doing stuff like this right now involving some probes on a tokamak. The situation in the vicinity of the probe is just too complicated to come up with any sort of decent analytical solution, so it turns out that it is better to use what is called a particle-in-cell (PIC) simulation to model the situation in order to interpret the data collected by the probe.
 
  • #4
There's huge amount of computational work done in condensed matter physics. Electron structures, dielectric constants and so on..
 
  • #5
My standard answer in something like this is to to go the American Physical Society website (www.aps.org) and look at the specific division/units under the APS. Practically all branches of physics are represented here. If you go to each of the division/units page, you'll find a wealth of links for that particular field of study.

For example, you'll find this for the Divisionn of Computational Physics

http://www.aps.org/units/dcomp/

Zz.
 
  • #6
A reasonable number of computational physicists switch fields and work in Wall-Street (or elsewhere in the finance sector) modeling extremely complex, non-linear behavior.

http://guava.physics.uiuc.edu/~nigel/finance.html

http://www.google.com/search?hl=en&q=physicist+finance+modeling&btnG=Google+Search

The point is that, as a computational physicist, you learn to model very tricky stuff. For instance, there's a grad student in my dept. (Physics) using Ising Models and related statistical mechanics methods to simulate and predict geographical variations in socio-economic behavior.
 

1. What is computational physics?

Computational physics is a branch of physics that uses computer simulations and numerical analysis techniques to solve and study physical problems. It combines elements of physics, mathematics, and computer science to create models and simulations that help us understand complex physical phenomena.

2. How is computational physics used in real-world applications?

Computational physics has a wide range of applications in various fields, including astrophysics, materials science, fluid dynamics, and quantum mechanics. It is used to study and predict the behavior of complex systems, design new materials, simulate fluid flows in engineering applications, and even model the evolution of the universe.

3. What are some advantages of using computational physics?

One of the main advantages of computational physics is its ability to solve complex problems that are either impossible or very difficult to solve analytically. It also allows for the simulation of physical systems that are not easily accessible in the real world, and it can provide insights and predictions that would be difficult to obtain through experiments alone.

4. What are the limitations of computational physics?

Although computational physics has many advantages, it also has some limitations. One of the main limitations is that the accuracy of the results depends on the accuracy of the input parameters and the quality of the algorithms used. In addition, some physical phenomena are still too complex to be accurately simulated using current computational methods.

5. What skills are needed to work in the field of computational physics?

To work in the field of computational physics, one needs to have a strong background in physics, mathematics, and computer science. Proficiency in programming languages and numerical analysis techniques is also essential. Problem-solving skills, attention to detail, and the ability to think critically and creatively are also important qualities for a computational physicist.

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