The Bennett-Hassani Cross-Planar Energy and Interaction Theory represents a theoretical approach to understanding how energies, entities, and identities behave when interacting across different planes of existence within the multiverse. This theory attempts to explain the dynamics that govern how beings and forces transition between planes, how identities are preserved, and how planes themselves are created or collapse under certain conditions. While the full practical realization of these ideas remains out of reach, the theory provides a foundation for exploring cross-planar interaction and energy flow.
A fundamental aspect of the Bennett-Hassani Theory is the concept of planar energy divergence, which posits that each plane of existence operates according to distinct energy laws. These laws define the nature of magic, physics, and metaphysical forces within a given plane. When entities or energies cross from one plane to another, they must adapt or be transformed by the divergent energy systems that govern their new environment.
This divergence can result in a variety of interactions. For instance, an entity from a magic-rich plane might find their abilities weakened or altered in a plane governed by more rigid physical laws. Conversely, technological devices operating under the rules of one plane may malfunction or become entirely inert when transferred to a plane with fundamentally different energy principles. The degree to which these transformations occur depends on the stability of the receiving plane and its specific energy makeup.
Building on the concept of planar energy divergence, the theory introduces the idea of identity conservation, which suggests that a being’s core essence—its consciousness, soul, or metaphysical identity—remains consistent even when traversing between planes with differing laws. The theory posits that this identity is anchored by a form of metaphysical inertia, allowing entities to retain their sense of self and essential abilities despite the shifting laws of the plane they enter.
However, the degree of conservation is not absolute. The interaction between the being's inherent identity and the plane’s laws can result in minor alterations to physical or magical attributes. In extreme cases, prolonged exposure to a radically different plane might lead to a gradual erosion of certain traits, though the core identity remains intact. This principle attempts to explain how beings can operate across multiple planes without losing their essential nature.
The Bennett-Hassani Theory also explores the processes by which planes are created and decay. According to the theory, planes are not static but instead arise from the interplay of cosmic forces, including the balance of order and chaos. A plane's stability depends on its energy equilibrium; disruptions to this balance can lead to the decay or collapse of a plane.
The creation of a new plane is believed to occur when certain cosmic forces converge, leading to the formation of a distinct energy system capable of supporting its own set of laws. Conversely, when the energy within a plane becomes too unstable—whether through external interference, a breakdown of internal coherence, or imbalances in divine or metaphysical influence—planes may deteriorate and collapse back into the multiverse. This principle explains why some planes remain stable for eons while others exist only briefly before disintegrating.
The Bennett-Hassani Theory outlines potential pathways by which such travel might one day be achieved. The theory suggests that understanding the specific energy laws of both the origin and destination planes would be crucial for creating safe passages between them. This would require not only identifying stable points of connection between planes but also developing ways to mitigate the effects of planar energy divergence. A key challenge to cross-planar travel is the risk of dimensional distortion, where the mismatched energies between planes create unpredictable results during the transition.
The Bennett-Hassani Theory suggests that identifying the underlying cause of energy imbalance might allow scholars to devise temporary solutions to prolong the life of the plane. By understanding how planar energy equilibrium is maintained, it may be possible to create temporary structures or fields that reinforce a plane’s stability, preventing further degradation. This application could prove vital in scenarios where a plane is at risk of collapse due to external forces or internal decay.