The piezoresistive efect of materials can be adopted for a plethora of sensing applications,
including force sensors, structural health monitoring, motion detection in fabrics and wearable,
etc. Although metals are the most widely adopted material for sensors due to their reliability and
afordability, they are signifcantly afected by temperature. This work examines the piezoresistive
performance of carbon nanoparticle (CNP) bulk powders and discusses their potential applications
based on strain-induced changes in their resistance and displacement. The experimental results
are correlated with the characteristics of the nanoparticles, namely, dimensionality and structure.
This report comprehensively characterizes the piezoresistive behavior of carbon black (CB), onionlike carbon (OLC), carbon nanohorns (CNH), carbon nanotubes (CNT), dispersed carbon nanotubes
(CNT-D), graphite fakes (GF), and graphene nanoplatelets (GNP). The characterization includes
assessment of the ohmic range, load-dependent electrical resistance and displacement tracking, a
modifed gauge factor for bulk powders, and morphological evaluation of the CNP. Two-dimensional
nanostructures exhibit promising results for low loads due to their constant compression-todisplacement relationship. Additionally, GF could also be used for high load applications. OLC’s
compression-to-displacement relationship fuctuates, however, for high load it tends to stabilize. CNH
could be applicable for both low and high loading conditions since its compression-to-displacement
relationship fuctuates in the mid-load range. CB and CNT show the most promising results, as
demonstrated by their linear load-resistance curves (logarithmic scale) and constant compression-todisplacement relationship. The dispersion process for CNT is unnecessary, as smaller agglomerates
cause fuctuations in their compression-to-displacement relationship with negligible infuence on its
electrical performance
