- Barklow, Tim;
- Gessner, Spencer;
- Hogan, Mark;
- Ng, Cho-Kuen;
- Peskin, Michael;
- Raubenheimer, Tor;
- White, Glen;
- Adli, Erik;
- Cao, Gevy Jiawei;
- Lindstrøm, Carl A;
- Sjobak, Kyrre;
- Barber, Sam;
- Geddes, Cameron;
- Formenti, Arianna;
- Lehe, Remi;
- Schroeder, Carl;
- Terzani, Davide;
- van Tilborg, Jeroen;
- Vay, Jean-Luc;
- Zoni, Edoardo;
- Doss, Christopher;
- Litos, Michael;
- Lobach, Ihar;
- Power, John;
- Swiatlowski, Maximilian;
- Fedeli, Luca;
- Vincenti, Henri;
- Grismayer, Thomas;
- Vranic, Marija;
- Zhang, Wenlong
As part of the Snowmass'21 community planning excercise, the Advanced Accelerator Concepts (AAC) community proposed future linear colliders with center-of-mass energies up to 15 TeV and luminosities up to 50 × 1034 cm-2 s-1 in a compact footprint. In addition to being compact, these machines must also be energy efficient. We identify two challenges that must be addressed in the design of these machines. First, the Beam Delivery System (BDS) must not add significant length to the accelerator complex. Second, beam parameters must be chosen to mitigate beamstrahlung effects and maximize the luminosity-per-power of the machine. In this paper, we review advances in plasma lens technology that will help to reduce the length of the BDS system and we detail new Particle-in-Cell simulation studies that will provide insight into beamstrahlung mitigation techniques. We apply our analysis to both e + e - and γγ colliders. The challenges and solutions described in this paper are considered independently. A unified, self-consistent concept for a BDS system for a 15 TeV linear collider will be the subject of future work.