Focal Fusion Laser Collider (FFLC)
What happens when you combine as many different types of lasers as possible into a single coherent beam – or focus them all simultaneously onto a single target point?
This seemingly absurd question is, in fact, quite serious. No existing laser system has ever been designed to create such a convergence of disparate beam sources – simply because no immediate or practical benefit can be expected from it.
And this is precisely where our approach begins. This project is not about application, but about the systematic search for nonlinear or unknown interactions that may remain undiscovered under ordinary conditions. We therefore place particular emphasis on high-precision measurement technology.
Approximately 85% of the entire setup consists of multisensor detection systems that record even the slightest deviations. The entire experimental environment is tracked, measured, and recorded – with the goal of making even the smallest anomalies visible.
A project in the spirit of the Pointless Science Center: “If you don’t know what you’re looking for, you have to look very closely.”
Short Description
The Focal Fusion Laser Collider (FFLC) outlines a conceptual experiment in which various types of lasers – from diode lasers and HeNe to CO₂ and femtosecond lasers – would theoretically be merged into a single beam or focused onto a common target point.
The goal of this proposal is not practical application, but the observation of possible interactions under highly unusual conditions.
At the core lies the question of how fundamentally different laser systems might influence one another – and whether unknown effects could emerge when they are forced into convergence. A particular focus is placed on the theoretical possibility of combining multiple laser systems and wavelengths into a coherent multilaser beam.
Conceptual Experimental Design:
Laser Coalition (Beam Convergence):
Theoretical combination of multiple laser types with different wavelengths
Use of dichroic mirrors and precision alignment systems
Goal: conceptual creation of a coherent or chaotic multi-beam structure
Singular Focal Point:
Alignment of all beams to a single shared target
Use of various materials as impact surfaces (e.g. glass, metal, ceramics, biological gels)
Goal: visualizing interference effects, material responses, and unpredictable interactions – as part of a conceptual study
Planned Observation Focus:
Thermal effects and melting points
Spectral interference and overlaps
Formation of plasma zones or light anomalie
Unexpected or nonlinear interactions