In the process of renormalization, regularization is usually cited as indispensable in taming infinities encountered in quantum field theory. Is explicit regularization really necessary?
Let's take for example the fermion propagator $$ G = \frac{i}{\not{p}-m_0 - \Sigma(\not{p})+i\epsilon} = \frac{i}{(1-b(p^2))\not{p}-(m_0 + a(p^2)) + i\epsilon}, $$ where self energy is expressed as $$ \Sigma(p) = a(p^2) + b(p^2)\not{p}. $$ The propagator has a pole at $$ (1-b(p^2))^2p^2-(m_0 + a(p^2))^2 = 0 $$ that is $$ p = m_p = \frac{m_0 + a(m_p^2)}{1-b(m_p^2)}, $$ where $m_0$ is bare mass (infinite) and $m_p$ is the physical mass (finite).
One may rearrange the above Fermion propagator via introducing modified self energy $\hat{\Sigma}(\not{p})$ so that $$ G = \frac{iZ}{\not{p}-m_p - \hat{\Sigma}(\not{p})+i\epsilon}, $$ where $\hat{\Sigma}(\not{p})$ is defined as $$ Z^{-1}\hat{\Sigma}(\not{p}) = [a(p^2)-a(m_p^2)] + [b(p^2)-b(m_p^2)]\not{p}, $$ and $$ Z = \frac{1}{1-b(m_p^2)}. $$
Note that the difference $a(p^2)-a(m_p^2)$ is finite, even though $a(p^2)$ and $a(m_p^2)$ are individually infinite. If we follow the regime of sticking with finite differences (i.e. $a(p^2)-a(m_p^2)$) and measurable quantities (i.e. $m_p$) only, then the explicit regularization schemes (such as the widely used dimensional regularization) are not needed at all.
Of course, one can follow the same procedure at a different energy scale (renormalization scale $\mu$), rather than at the physical mass scale ($m_{p}$).
An added note on the difference between two infinite quantities. Take the following example, $$ \int_{0}^r \frac{1}{x}dx - \int_{0}^{r_0} \frac{1}{x}dx = \int_{r_0}^r \frac{1}{x}dx = \ln(\frac{r}{r_0}). $$ Hard core mathematicians will be leery of the first step and demand some form of regularization. Do physicists, while not fazed by the lack of mathematical rigor with things like path integral, really need a formal explicit regularization to arrive at the final result?
One may call the above procedure implicit regularization. Similar idea has already been picked up by some researchers (see Jackiw's approach, approach of the Australian school, and approach of the Brazilian school) though in a different fashion as framed here. The merit of implicit regularization is that it circumvents various pitfalls besieging explicit regularization, e.g. violation of gauge invariance in cutoff regularization or the $\gamma^5$ issue in dimensional regularization.
So my question is:
- In light of the vice of explicit regularization mentioned above (moreover, given the intricacies and pitfalls, explicit regularization is often perplexing rather than elucidating when renormalization is taught in text books), shall we skip it in the process of renormalization?
- How do the different implicit regularization schemes (Jackiw, the Australian school, and the Brazilian school) stack against each other?
