Fig. 1 Vickers hardness of various HEAs as functions of tensile strengths a and compressive strengths b. The solid lines are plotted based on the three-time relation between hardness and strength

Fig. 2 Relations between tensile strengths and Vickers hardness for FCC HEAs: a σy versus HV and b σUTS versus HV

Fig. 3 Relations between compressive strengths and Vickers hardness for FCC HEAs: a σyc versus HV and b σ10 versus HV

Fig. 4 Relations between tensile strengths and Vickers hardness for BCC HEAs: a σy versus HV and b σUTS versus HV

Fig. 5 Relations between compressive strengths and Vickers hardness for BCC HEAs: a σyc versus HV, b σf versus HV, c σ10 versus HV. The grey shadow in b, c and the cyan shadow in b cover the ductile HEAs with compressive fracture strain ≥ 20% and the brittle HEAs with compressive fracture strain < 20%, respectively

Fig. 6 Compressive strengths a and tensile strengths b of FCC HEAs and compressive strengths c and tensile strengths d of BCC HEAs as functions of Vickers hardness. The solid lines are plotted based on the three-time relation between hardness and strength

Fig. 7 Relations between tensile strengths and Vickers hardness for FCC + BCC dual-phase HEAs: a σy versus HV and b σUTS versus HV

Fig. 8 Relations between compressive strengths and Vickers hardness for FCC + BCC dual-phase HEAs: a σyc versus HV, b σf versus HV, c σ10 versus HV. The grey shadow in a, c and the cyan shadow in a, b cover the ductile HEAs with compressive fracture strain ≥ 20% and brittle HEAs with compressive fracture strain < 20%, respectively

Fig. 9 Relations between tensile strengths and Vickers hardness for FCC + IM-DP HEAs: a σy versus HV, b σUTS versus HV

Fig. 10 Relations between compressive strengths and Vickers hardness for FCC + IM-DP HEAs: a σyc versus HV, b σf versus HV, c σ10 versus HV. The grey shadow in a-c and the cyan shadow in a, b cover the ductile HEAs with compressive fracture strain ≥ 20% and brittle HEAs with compressive fracture strain < 20%, respectively

Fig. 11 Relations between compressive strengths and Vickers hardness for BCC + IM dual-phase HEAs: a σy versus HV, b σUTS versus HV

Fig. 12 Compressive strengths a and tensile strengths b of FCC + BCC - DP HEAs and compressive strengths c and tensile strengths d of FCC + IM-DP HEAs and compressive strengths e of BCC + IM-DP HEAs as functions of Vickers hardness. The solid lines are plotted based on the three-time relation between hardness and strength

Fig. 13 Relations between compressive strengths and Vickers hardness for FCC + BCC + IM - TP HEAs: a σyc versus HV, b σf versus HV, c σ10 versus HV. The grey shadow in a-c and the cyan shadow in a, b cover the ductile HEAs with compressive fracture strain ≥ 20% and brittle HEAs with compressive fracture strain < 20%, respectively

Fig. 14 Effects of plasticity and work-hardening ability on hardness-to-strength ratio of various HEAs. a, b Ratios of hardness to tensile strengths as functions of a tensile elongation and b tensile ultimate-to-yield strength ratio, respectively. c, d Ratios of hardness to compressive strengths as functions of c compressive fracture strain, d Rc (or Rc10), respectively