Ibrahim Hany said:I would say that this is the only boundary condition that you have. The symmetry around the center of the source and thus the flux, will lead you to have an even solution of the differential diffusion equation, which would be a Cosine..or a decaying exponential. So, you are left with two more constants to be determined; the constant in the exponential/cosine and the coefficient of the exponential/cosine function (the amplitude).
To get the first one, you will have to apply the boundary condition of the total flux decay at the boundary; which you have already mentioned in your question. This will lead you to numerous possible solutions/harmonics.
To get the second one, you have to know the power of the assumed reactor.
i do not have the power, i am thinking to use laplace transformtionIbrahim Hany said:To design a thermal reactor, you should have a moderator to slow down neutrons to the thermal region where fission cross section for U235 is high enough. So, a reactor, is a source(which is your case has a cosine distribution) and a moderator, at least.
i read the lamarsh(intro to nuclear reactor ) book but in lamarsh(intro to nuclear enginnering ) problem 34 he use laplace transformtionIbrahim Hany said:It is worth mentioning that this may not be the only way to approach the solution, but this is the way that I know and that way followed by Lamarsh in his solutions to the diffusion equation. May be other authors use a different/easier approach...I would be glad to know it!
5Ibrahim Hany said:Problem 34, which chapter?
A diffusion equation is a mathematical equation that describes the spread of a substance or quantity through a medium. It is commonly used in various scientific fields, such as physics, chemistry, and biology, to model the behavior of diffusing substances or quantities over time and space.
In a diffusion equation, the 2nd boundary condition refers to a specific condition that must be satisfied at the boundary or interface between two different media. It is usually expressed as a mathematical relationship between the values of the diffusing substance or quantity at the boundary and its surrounding environment.
To solve a diffusion equation with a given source term, one can use various numerical methods or analytical techniques. One commonly used approach is the Finite Difference Method, where the diffusion equation is discretized and solved iteratively. Another method is the separation of variables technique, which can be used for certain types of diffusion equations with specific boundary conditions.
The source term in a diffusion equation represents a continuous supply or removal of the diffusing substance or quantity at a specific location in the medium. It can significantly influence the behavior of the diffusion process and can result in non-uniform distributions of the diffusing substance or quantity over time and space.
Yes, the source term in a diffusion equation can be time-dependent, which means it can vary with time. This can happen, for example, when the diffusing substance is being continuously added or removed from the medium. In such cases, the diffusion equation must be solved using time-dependent techniques, such as the Method of Lines or the Finite Volume Method.