I agree with that. But this was expected reaction of HN. I will take your comment as a chance to quote the P5 report [1]
> There is a compelling physics case for constructing a 10 TeV or more pCM collider. Such a collider would search for direct evidence and quantum imprints of new particles and forces at unprecedented energies. There are several approaches: a 10 TeV muon collider, a 100 TeV proton-proton collider such as FCC-hh at CERN, or possibly a 10 TeV high-energy e+e– or γ-γ collider based on the wakefield acceleration technology. Any of them would enable a comprehensive physics portfolio that includes ultimate measurements in the Higgs sector, a broad search program providing access to new hidden sectors by producing a substantially higher mediator mass or probing even smaller coupling, and opportunities to produce new particles directly. All options for a 10 TeV pCM collider are new technologies under development and R&D is required before we can embark on building a new collider.
Mind that the original paper is 20 years old. Of course we could construct a more powerful intermediate collider today than the sub-TEV one suggested in this old paper. I think most proposals these days target ~10 TeV to study the Higgs and probe the rest of the weak scale for supersymmetry. But these are just the fancy high-end goals. There's a plethora of other things we could learn simply from building such a machine, because it requires so many new technologies.
> There is a compelling physics case for constructing a 10 TeV or more pCM collider. Such a collider would search for direct evidence and quantum imprints of new particles and forces at unprecedented energies. There are several approaches: a 10 TeV muon collider, a 100 TeV proton-proton collider such as FCC-hh at CERN, or possibly a 10 TeV high-energy e+e– or γ-γ collider based on the wakefield acceleration technology. Any of them would enable a comprehensive physics portfolio that includes ultimate measurements in the Higgs sector, a broad search program providing access to new hidden sectors by producing a substantially higher mediator mass or probing even smaller coupling, and opportunities to produce new particles directly. All options for a 10 TeV pCM collider are new technologies under development and R&D is required before we can embark on building a new collider.
[1] https://www.usparticlephysics.org/2023-p5-report/the-recomme...