I actually was more interested in functional analytic techniques in finding solutions to PDEs, especially PDEs which arise from problems in kinetic theory/statistical mechanics and fluid dynamics from physics. I'm more interested in analytic techniques, but I'm not opposed to doing numerical simulations to check my theory.homeomorphic said:As long as you did numerical stuff and not existence of solutions in Sobolev space, it's probably somewhat okay. I don't know. I just know pure math sucks for getting non-academic jobs in this job market, unless you are a bit of a wiz at job-searching.
Cool...I really would like to end up as a researcher in a physics group at a national lab (i'm doing a master's in physics), but I find that physics courses and research don't go as deep into the theory and analytic techniques as I would like to go. They tend to sort of derive the equation and go straight into how to solve it approximately on a computer. Only thing is, I'm afraid employers will see a math degree on my CV and automatically dismiss me for physics/engineering jobs even though my research might have been directly related to the field.StatGuy2000 said:Well, I have a good friend who finished his PhD in applied math, specializing in applying graph theoretic methods to build a bridge between quantum information theory and classical statistical mechanics (I assume he has a strong background in PDEs and numerical methods), before doing a postdoc in bioinformatics, and he's now working as a bioinformatics researcher at a major research institute devoted to oncology in Ontario. And I've known others with similar backgrounds find lucrative positions.
So long as you have strong computing skills and take the effort to pursue internships while pursuing both undergraduate and graduate studies, I'm fairly confident that you will find your skills marketable.
Only thing is, I'm afraid employers will see a math degree on my CV and automatically dismiss me for physics/engineering jobs even though my research might have been directly related to the field.
Hercuflea said:I actually was more interested in functional analytic techniques in finding solutions to PDEs, especially PDEs which arise from problems in kinetic theory/statistical mechanics and fluid dynamics from physics. I'm more interested in analytic techniques, but I'm not opposed to doing numerical simulations to check my theory.
homeomorphic said:
There are a lot of positions that will say applied math or engineering or related quantitative discipline or something like that. I'm not sure the degree is such a big issue, although, personally, I would much rather have an engineering degree, if you ask me. What you should worry about is developing a skill set that they will want, even including non-technical skills. If you don't have the skill set, you could end up like me with my topology PhD, not knowing where you fit in. So, I'd start looking at applied math postings now to see what they want and by the time you get a PhD, you could make yourself very marketable.
I didn't really start this process until the end of my PhD, in addition to not getting internships, which wasn't a very marketable degree to begin with, so I'm now having to develop marketable skills under the pressure of being extremely underemployed and having to do a very difficult job search in the mean time, just in case someone out there is willing to hire me as is. The thing is, it's not just out of ignorance that I wasn't prepared. A big part of why I wasn't prepared is that the PhD was very difficult and took all my energy. Granted, if I had known I was headed out of academia, I would have had plenty of time to do things that industry would like, instead of all the things I was doing to prepare myself for academia.
f95toli said:Analytical techniques for PDEs are of very limited practical use so I don't this would be a very marketable skill in industry (or even anywhere outside the math community in academia). However, if you instead were to work numerical methods for solving PDEs (FEM etc) I am pretty sure you would find it much easier to find a job afterwards; for the obvious reason that there are a vast number of practical problems which require those types of skill to solve (fluid dynamics etc) .
I'm more interested in getting a postdoc in a physics/engineering department at a university or national lab, however, I would like to have a more rigorous understanding of the sorts of equations you deal with than just running simulations on a computer, and that's why I'd like to get some background in PDE research and functional analysis.
Why did you choose not to do academia?
Arsenic&Lace said:Hercuflea, if physicists in general do not bother to learn PDE theory, and it has been repeatedly mentioned that it is not relevant to industry, you may want to consider asking whether PDE theory is meaningful at all or if it's the pathological offspring of a bizarre, anachronistic philosophical view of what mathematics actually is.
StatGuy2000 said:Correct me if I'm mistaken, but in order to effectively work on numerical methods for PDEs, wouldn't Hercuflea or others in his/her position (Hercuflea, I believe you are male, but correct me if I'm mistaken) need to have an advanced understanding of PDE theory, such as analytic techniques?
Unfortunately I'm not enough of an expert to really say for sure. However applied math departments, which I considered applying to, actually had flexibility about pure math requirements. My undergraduate institution requires everybody to take theory courses. Numerous institutions had no such requirement. The fact that it is optional is a warning to me that it may be a waste of time. Of course there are details I don't know; maybe if you're in an applied math department and you work on numerical methods in PDE's, your mentor will require you to take functional analysis and PDE theory so it really isn't optional.StatGuy2000 said:Correct me if I'm mistaken, but in order to effectively work on numerical methods for PDEs, wouldn't Hercuflea or others in his/her position (Hercuflea, I believe you are male, but correct me if I'm mistaken) need to have an advanced understanding of PDE theory, such as analytic techniques? So it's not as if in pursuing PDE theoretical research that numerical methods will somehow be neglected. And besides, so long as a solid understanding of PDEs are developed which can then be translated into actionable use for industry, I'm certain that Hercuflea can be very marketable.
There are several types of job opportunities available for individuals with a PhD in PDE research. These include academic positions as a professor or researcher at a university, industrial research positions in fields such as engineering or finance, and government research positions at institutions like national laboratories.
Yes, there is a high demand for individuals with expertise in PDE research. PDEs are a fundamental tool in mathematics and are used in various fields, making individuals with this expertise highly sought after in academia, industry, and government.
To have a successful career in PDE research, individuals should have a strong foundation in mathematics, particularly in analysis and numerical methods. They should also have excellent problem-solving and critical thinking skills, as well as strong programming skills to implement and analyze PDE models.
Yes, individuals with a PhD in PDE research can work in fields outside of mathematics. PDEs are used in a wide range of disciplines, including physics, engineering, finance, and biology. With the right skills and knowledge, individuals can apply their expertise in PDEs to various industries and fields.
Some current and emerging research areas in PDEs include nonlinear and nonlocal PDEs, stochastic PDEs, and PDEs in data science. These areas have applications in various fields and offer exciting research opportunities for individuals with expertise in PDE research.