We present nuclear magnetic resonance (NMR) measurements on the three distinct In sites of CeCoIn5 with magnetic field applied in the [100] direction. We identify the microscopic nature of the long range magnetic order (LRO) stabilized at low temperatures in fields above 10.2 T while still in the superconducting (SC) state. We infer that the ordered moment is oriented along theĉ-axis and map its field evolution. The study of the field dependence of the NMR shift for the different In sites indicates that the LRO likely coexists with a modulated SC phase, possibly that predicted by Fulde, Ferrell, Larkin, and Ovchinnikov. Furthermore, we discern a field region dominated by strong spin fluctuations where static LRO is absent and propose a revised phase diagram.The detrimental effect of an applied magnetic field on a superconductor has nourished the intuitive presumption of a de facto competition between magnetic and superconducting (SC) orders. However, it is now wellestablished, both theoretically and experimentally, that not only can these orders coexist, but in some cases, they may even be essential for each other's stability [1]. Manifestations of coexistence span a rather wide range of materials including several cuprates, ferropnictides, and heavy fermion systems of which CeCoIn 5 is one of the most intriguing examples [2]. In the SC state of this compound application of a magnetic field (H 0 ) induces a long range magnetic order (LRO), restricted to a narrow lowtemperature (T ) region of the phase diagram below H c2 [3,4]. What is more, this particular region of the phase diagram was initially identified as the first realization of the long-sought Fulde, Ferrell, Larkin, and Ovchinnikov (FFLO) state, a superconducting state with a non-zero pair momentum and a spatially modulated order parameter [5,6]. However, important questions regarding the true nature of the low-T high-H 0 SC phase, the details of the magnetic order and its field dependence, and the potential driving mechanisms of their coexistence remain unanswered [7]. Thus, CeCoIn 5 provides a strikingly rich ground to study the complex interplay between exotic SC and magnetism. Experimentally, nuclear magnetic resonance (NMR), as a microscopic probe sensitive to both magnetic and SC degrees of freedom, provides a powerful tool for the investigation of these puzzles.In this letter, detailed low temperature NMR measurements on the three distinct In sites in CeCoIn 5 for H 0 || [100] are presented. We establish that at T ≈ 70 mK a phase with static magnetic LRO is stabilized for fields above ≈ 10.2 T in the SC state. We deduce that the LRO is an incommensurate spin density wave (IC-SDW) with moments oriented along theĉ-axis, independent of the in-plane H 0 orientation. Further, the detailed field evolution of the moment is mapped. The study of the field dependence of the NMR shift implies that this IC-SDW coexists with a novel SC state, characterized by an enhanced spin susceptibility [8]. Finally, we identify a new region in the H 0 -T phase diagram, l...
