On the later evolution of observationally selected protocluster candidates at z\,\,5

Abstract

Recent observations have revealed numerous protocluster candidates at z\,\,5, yet whether these systems will eventually evolve into today's galaxy clusters remains an open question. Using the FLAMINGO simulations -- resolving protocluster cores up to z\,\,10 -- we track the later evolution of observationally selected protocluster candidates, comparing three selection methods against observational samples. The observed number density falls between our mass-selected and abundance-matched samples, implying that current searches pick up both genuine cluster progenitors and significant interlopers that will not reach cluster masses by z\,=\,0. We find that candidates at z5 are heavily clustered, hosting 2-10 neighbors within 10\,cMpc. Consequently, a candidate with a neighbor at 5\,cMpc (10\,cMpc) faces a 50\% (30\%) probability of later merging into a larger system, mostly at z\,\,2. The merger count converges beyond 10\,cMpc, pointing to a fundamental scale in structure formation. Observations show markedly weaker clustering than our simulations predict, suggesting clustering offers a currently overlooked diagnostic. Each candidate undergoes roughly 2-6 later major mergers, mostly with systems too small to be recognized as massive at the selection epoch. Hence, relying solely on high-z mass and galaxy overdensity to forecast a candidate's fate is prone to severe scatter and systematic error. A robust identification of true cluster progenitors demands a total mass sum of galaxies down to the faintest levels within a 10\,cMpc radius. Upcoming surveys with both depth and area will be key to reliably linking high-z protocluster candidates to their ultimate destiny.