I dont understand what is that it makes it so much faster.
People often assume Julia is fast due to some sort of superior JIT compiler and that Python could be optimized in the same way since they are both dynamic languages.
However it is actually all due to clever language design choices. All functions in Julia are multiple dispatch unlike Python functions. That means at runtime Julia can pick one particular code implementation for every possible combination of arguments. Since types are immutable in Julia the compiled machine code handling a particular case of argument combinations can be cached.
In Julia all libraries have also been designed with type stability in mind, meaning for a given set of argument types a function will always return objects of the same type. E.g. so if you do a mathematical operation on two integers and it returns and integers, then most of the time the JIT compiler will know that it ALWAYS returns an integer and thus don't have to create lots of code to check for every possible case.
If you are uncertain about the performance of Julia, I suggest you actually look at some small code examples and play with the code generator. With
@code_native, you can see the assembly code Julia generates for a function. You will find it is possible to emit basically the same code as a C compiler would do. Quite dynamic and complex looking code in Julia surprisingly often just turns into a few assembly code instructions.
The thing with Julia is that you can't just look at the performance of some random library existing doing what you want. It could be a quick port or not well optimized. It is easy to write slow Julia code if you have no idea what you are doing. The key thing is that Julia gives you quite good tools for writing highly optimized code.
If you need to you can typically manage to get performance close to C. But of course you have to spend some time optimizing your code. Julia has functions which allows you to analyze your functions and tell you were you did something causing potential performance problems.
Fortunately Julia performance benefits from lots of small functions, so you can typically analyze performance issues in very small isolated cases.