The qualitatively new concept of dynamic complexity in quantum mechanics is based on a new paradigm appearing within a nonperturbational analysis of the Schrödinger equation for a generic Hamiltonian system. The unreduced problem analysis explicitly provides its complete, consistent solution as a set of many incompatible components ("realisations"), which should permanently and probabilistically replace one another, since each of them is "complete" in the ordinary sense. This discovery leads to the universally applicable concept of dynamic complexity and self-consistent, realistic resolution of the stagnating problems of quantum chaos, quantum measurement, indeterminacy and wave reduction. The peculiar, "mysterious" character of quantum behaviour itself is seen now as a result of a dynamically complex, intrinsically multivalued behaviour of interacting fields at the corresponding lowest levels of the (now completely causal) structure of reality. Incorporating the results of the canonical theories as an over-simplified limiting case, this new approach urgently needs support, since its causality and completeness are directly extendible to arbitrary cases of complex behaviour of real systems, in sharp contrast to the dominating inefficient empiricism of "computer experimentation" with primitive mechanistic (i. e. dynamically single-valued) "models" of the irreducibly multivalued reality.