A 10 TeV muon collider is the ideal machine to explore the energy frontier. In addition to producing large samples of Standard Model particles, it has the potential to create new, possibly massive states, enabling a broad physics program that includes direct and indirect searches for new physics, precise Standard Model measurements in an unexplored energy regime, and significant advancements in the Higgs sector.
The fulfillment of such physics potential lies in the detector's ability to reconstruct physics objects and measure their properties over a wide range of momenta at high levels of machine-induced background. At 10 TeV collisions, the transverse momenta of Standard Model particles are relatively low, while new heavy states are expected to decay into high-momentum central physics objects. This contribution outlines two detector concepts that are currently under development and presents the first studies on the reconstruction performance of tracks and photons using a detailed detector simulation, including the beam-induced background.