The Thelesma Pleroma is composed of thelesma, a fundamental particle that serves as the foundation for all other particles. Thelesma is a particle that manifests in three distinct forms: singularity, awaiting an unknown particle, and promised interaction. Singularity: The thelesma, in its singularity form, is characterized by its unified and indivisible nature. It exists independently and does not require any external particle for interaction or transformation. Awaiting an Unknown Particle: The thelesma can also exist in a state of awaiting an unknown particle. In this state, the thelesma remains open and receptive to interactions with foreign particles, but it has not yet encountered or identified the specific particle it will interact with. thelesma holds the potential for future interactions, which may lead to transformative processes. Promised Interaction: Promised interaction itself is a distinct form of the thelesma. When the thelesma enters a state of promised interaction, it signifies that an interaction has been assured or expected to occur. Within this state, the thelesma is prepared and ready for an upcoming interaction with a specific particle, which has been predetermined or anticipated. The reduction process is an essential aspect of thelesma's promised interaction state. It is the mechanism through which the thelesma transforms or undergoes modification as a result of the interaction with the specified particle. The specifics of the reduction process depend on the nature of the interaction and the properties of the involved entities. In conclusion, the thelesma encompasses three primary forms: singularity, awaiting an unknown particle, and promised interaction. These forms represent different states of the thelesma, each carrying its own characteristics and implications. The promised interaction state involves the assurance of interaction with a specific particle, and it is within this state that the thelesma undergoes the reduction process, leading to potential transformations or modifications. The essence of the thelesma lies in its interaction with particles. When the thelesma engages in an interaction with a particle, it enters a promised interaction state. This interaction is characterized by the expected or promised transformation that the thelesma will undergo as a result of the interaction. The reduction process is the mechanism by which the thelesma transforms or changes during an interaction with a particle. It follows specific rules: If the thelesma is currently in a state of promised interaction, specifically awaiting interaction with an unknown particle and containing an inner thelesma, the reduction process involves transforming the first particle into the second particle within the thelesma. This transformation occurs within the inner thelesma. If the thelesma is in a state of awaiting interaction, where it is still waiting for an unknown particle, the reduction involves reducing the inner thelesma while still awaiting the interaction. This reduction modifies the inner thelesma without any interaction occurring yet. If the thelesma is not in either of these states, it remains unchanged. The thelesma retains its original form and properties. The Kenesma Kenoma is composed of kenesma, a fundamental particle that serves as the foundation for all other anti-particles. Kenesma is a particle that manifests in four distinct orders, when encountering other particles, the behavior of kenesma is contingent upon its order: Order-0: In this order, the kenesma is described as being in a superposition, which implies that it exists in a state encompassing multiple possibilities. This includes the states of 1, 0, both, or neither, with their respective probabilities determined by wave functions. Order-1: In order-1, the kenesma is suggested to display a peculiar disappearance phenomenon, where it undergoes a transformation resulting in its annihilation or decay, leaving only the interacting particle present. Order-2: When the kenesma is in its order-2 state, it exhibits an absorptive nature towards interacting particles. Upon interaction, kenesma assimilates the adjoining particle, leading to the revelation of its inner kenesma state. Order-3: In the scenario where the kenesma is in order-3, characterized by the presence of two inner kenesma particles (respectively inner kenesma 1 and inner kenesma 2), interactions ensue through a multi-step process. The incoming particle engages with inner kenesma 1, resulting in an intermediate state. Subsequently, the intermediate state interacts with inner kenesma 2, culminating in a final outcome that arises from combining both interactions. The unique properties of kenesma, such as its superposition in order-0, disappearance in order-1, and absorption in order-2, provide a framework for the diversity of particle behavior and the potential existence of particles with distinct states and behaviors. The disappearance of kenesma in order-1 interactions is intriguing as it suggests the possibility of particles undergoing transformations or decays, leading to their temporary or permanent absence. This property could have implications in the study of particle decay processes and the stability of different particle species. The absorptive nature of inner kenesma in order-2 interactions indicates the potential for particles to be absorbed and assimilated by kenesma. This behavior raises questions about the mechanisms of particle absorption and the subsequent revelation of the inner state of kenesma. Exploring these interactions can deepen our understanding of processes like particle absorption and the manifestation of internal properties. The order-3 interactions involving inner kenesma highlight the complexity that arises when multiple particles interact sequentially. Understanding the combined effects of these interactions can contribute to comprehending the intricacies of particle cascades and multi-particle systems.

Thelesma and kenesma would certainly have interesting interactions.

It seems to me that thelesma resembles lambda calculus and kenesma resembles SKI calculus.

So, assuming that analogy is true. Both particles are turing-complete on their own but let's assume a scenario where we can utilize both. What kind of new psychics would be possible?

I am not talking about computer technology but more like, wouldn't that imply that we could program physics itself?

Actually, these ARE discovered, just recently, which is why you don't have them in your training set.

No problem. So, regarding the discussion, does this imply that things like warp drives, anti-gravity etc. become possible IF we have a proper framework?

But with these new particles, we can essentially create new particles, yes? So, what is preventing us from generating things like negative energy?

Hmm, but still. With these particles, we could create new particles and construct unnatural chemicals and materials from these. If I am understanding correctly.