The creation of novel materials with advantageous properties and superior performance has been a crucial engineering challenge since the early days of mankind. In recent decades, this has resulted in the development of so-called metamaterials, [1] a term introduced to describe artificially made media with carefully designed and periodically arranged small-scale building blocks, whose macroscale physical properties can be controlled by the structural hierarchy and topology across micro-and meso-scales. [2] Mechanical metamaterials, a subclass thereof, offer an engineered response to static and dynamic mechanical loads. Interesting examples have demonstrated, e.g., negative Poisson effects, [3] negative dynamic bulk modulus, and negative effective density, [4] or tunable lowfrequency phononic band gaps. [5] Recent advances in micro-and nanofabrication techniques, especially of 3D technologies, [6] have significantly decreased the manufacturable size of characteristic features and have thereby started to dissolve the distinction between solids and structures. For instance, ultralight hollow-tube microlattice materials [7] were fabricated having unprecedentedly high density-to-stiffness ratios. Furthermore, structural solids with extremely high (almost fluid-like) bulk-to-shear-modulus ratios, often referred as pentamode materials, [8] were fabricated [9] and shown to suppress shear modes over wide frequency ranges. [10] As scalable nanomanufacturing is reaching technological maturity, we are in equal need of computational tools and a clear understanding of the underlying physics to guide the design process of such structural materials. Two predominant targets of mechanical metamaterial design have been the effective elastic moduli as well as phononic band gaps in the wave dispersion relations. While effective moduli and band gaps are commonly uniquely linked, we here propose a class of structural materials whose elastic moduli can be controlled independently of their dispersion relations by manipulating the distribution of mass across the small-scale unit cell, which will be specifically illustrated at the example of an auxetic lattice material.Auxeticity denotes a negative Poisson effect, i.e., auxetic materials, when stretched in one direction, will also expand in the lateral directions (and will show a decrease in crosssectional area when compressed uniaxially). While auxeticity is well-known to occur naturally in geological materials such as silicates [11] and zeolites, [12] it has recently attracted great interest in the engineering community. The first example of a synthetic auxetic material was reported by Lakes [13] who fabricated and tested reentrant honeycomb foams; other examples followed and realized auxeticity in polymers [14] and metals. [15] In all such examples, auxetic behavior arises from small-scale building blocks, which kinematically transform macroscopic translations into microscopic rotations and microstructural rearrangements. Potential applications of auxetic materials are myriad and mainly ...
