We study, in two space dimensions, the large-scale properties of collections of constant-speed polar point particles interacting locally by nematic alignment in the presence of noise. This minimal approach to self-propelled rods allows one to deal with large numbers of particles, revealing a phenomenology previously unseen in more complicated models, and moreover distinctively different from both that of the purely polar case (e.g. the Vicsek model) and of active nematics.PACS numbers: 05.65.+b, 87.18.Hf, 87.18.Gh Collective motion is an ubiquitous phenomenon observable at all scales, in natural systems [1] as well as human societies [2]. The mechanisms at its origin can be remarkably varied. For instance, they may involve the hydrodynamic interactions mediated by the fluid in which bacteria swim [3], the long-range chemical signaling driving the formation and organization of aggregation centers of Dictyostelium discoideum amoeba cells [4], or the local cannibalistic interactions between marching locusts [5]. In spite of this diversity, one may search for possible universal features of collective motion, a context in which the study of "minimal" models is a crucial step. Recently, the investigation of the simplest cases, where the problem is reduced to the competition between a local aligning interaction and some noise, has revealed a wealth of unexpected collective properties. For example, constant speed, self-propelled, polar point particles with ferromagnetic interactions subjected to noise (as in the Vicsek model [6]) can form a collectively moving fluctuating phase with long-range polar order even in two spatial dimensions [7], with striking properties such as spontaneous segregation into ordered solitary bands moving in a sparse, disordered sea, or anomalous ("giant") density fluctuations [8]. In contrast, active apolar particles with nematic interactions only exhibit quasi-long-range nematic order in two dimensions with segregation taking the form of a single, strongly-fluctuating, dense structure with longitudinal order and even stronger density fluctuations than in the polar-ferromagnetic case [9,10,11].Noting that these differences reflect those in the local symmetry of particles and their interactions, a third situation can be defined, intermediate between the polar ferromagnetic model and the apolar nematic one, that of self-propelled polar particles aligning nematically [12]. Such a mechanism is typically induced by volume exclusion interactions, when elongated particles colliding almost head-on slide past each other, as illustrated schematically in Fig. 1. Thus, self-propelled polar point particles with apolar interactions can be conceived as a minimal model for self-propelled rods interacting by inelastic collisions [13,14,15]. Other relevant situations can be found in a biological context, such as gliding myxobacteria moving on a substrate [16], or microtubules driven by molecular motors grafted on a surface [17].In this Letter, we study collections of constant-speed polar point particles inte...
