LISAmax: improving the low-frequency gravitational-wave sensitivity by two orders of magnitude

Abstract

Within its Voyage 2050 planning cycle, the European Space Agency is considering long-term large class science mission themes. Gravitational-wave astronomy is among the topics under study. Building on previous work by other authors (Folkner 2011 (NNH11ZDA019L); Ni 2010 Mod. Phys. Lett. A 25 922–35; Sesana et al 2021 Exp. Astron. 51 1333–83), this paper studies a gravitational-wave interferometer concept, dubbed ‘LISAmax’, consisting of three spacecraft, each located close to one of the Sun–Earth libration points L3, L4 and L5, forming a triangular constellation with an arm length of 259 million kilometers (to be compared to LISA’s 2.5 million kilometer arms). We argue that this is the largest triangular formation that can be reached from Earth without a major leap in mission complexity and cost (hence the name). The sensitivity curve of such a detector is at least two orders of magnitude lower in amplitude than that of LISA, at frequencies below 1 mHz. This makes the observatory sensitive to gravitational waves in the µHz range and opens a new window for gravitational-wave astronomy, not covered by any other planned detector concept. We analyze in detail the constellation stability for a 10 year mission in the full numerical model including insertion dispersion, and self-gravity-induced accelerations. We compute the orbit transfers using a European launcher and chemical propulsion. Different orbit options, such as precessing, inclined orbits, the use of flybys for the transfer, and the launch strategy, are discussed. The payload design parameters are assessed, and the expected sensitivity curve is compared with a number of potential gravitational-wave sources. No show stoppers are identified at this point of the analysis.