As a quantum-informative window into quantum many-body physics, the concept
and application of entanglement renormalization group (ERG) have been playing a
vital role in the study of novel quantum phases of matter, especially
long-range entangled (LRE) states in topologically ordered systems. For
instance, by recursively applying local unitaries as well as adding/removing
qubits that form product states, the 2D toric code ground states, i.e., fixed
point of Z_2 topological order, are efficiently coarse-grained with respect to
the system size. As a further improvement, the addition/removal of 2D toric
codes into/from the ground states of the 3D X-cube model, is shown to be
indispensable and remarkably leads to well-defined fixed points of a large
class of fracton orders that are non-liquid-like. Here, we present a
substantially unified ERG framework in which general degrees of freedom are
allowed to be recursively added/removed. Specifically, we establish an exotic
hierarchy of ERG and LRE states in Pauli stabilizer codes, where the 2D toric
code and 3D X-cube models are naturally included. In the hierarchy, LRE states
like 3D X-cube and 3D toric code ground states can be added/removed in ERG
processes of more complex LRE states. In this way, a large group of Pauli
stabilizer codes are categorized into a series of ``state towers''; with each
tower, in addition to local unitaries including CNOT gates, lower LRE states of
level-n are added/removed in the level-n ERG process of an upper LRE state
of level-(n+1), connecting LRE states of different levels and unveiling
complex relations among LRE states. As future directions, we expect this
hierarchy can be applied to more general LRE states, leading to a unified ERG
scenario of LRE states and exact tensor-network representations in the form of
more generalized branching MERA.Comment: v