Apart from the previous answers, I will add some comments.
All these predicates want to define the abstract function of
identity for an object but in different contextes.
EQ? is implementation-dependent and it does not answer the question
are 2 objects the same? only in limited use. From implementation point of view, this predicate just compares 2 numbers (pointer to objects), it does not look at the content of the objects. So, for example, if your implementation does not uniquely keep the strings inside but allocates different memory for each string, then
(eq? "a" "a") will be false.
EQV? -- this looks inside the objects, but with limited use. It is implementation-dependent if it returns true for
(eqv? (lambda(x) x) (lambda(x) x)). Here it's a full philosophy how to define this predicate, as we know nowadays that there are some fast methods to compare the functionality of some functions, with limited use. But
eqv? provides coherent answer for big numbers, strings, etc.
Practically, some of these predicates tries to use the abstract definition of an object (mathematically), while others use the representation of an object (how it's implemented on a real machine). The mathematical definition of identity comes from Leibniz and it says:
X = Y iff for any P, P(X) = P(Y)
X, Y being objects and
P being any property associated with object X and Y.
Ideally it would be to be able to implement this very definition on computer but for reasons of indecidability and/or speed it is not implemented literally. This is why there are lots of operators that try each one to focus on different viewpoints around this definition.
Try to imagine the abstract definition of an identity for a continuation. Even if you can provide a definition of a subset of functions (sigma-recursive class of functions), the language does not impose any predicate to be true or false. It would complicate a lot both the definition of the language and much more the implementation.
The context for the other predicates is easier to analyze.