Micro-alloyed steels are being increasingly accepted by industry in various fields of application and are available with a wide variety of microstructures. Extensive literature is available on processing routes of Micro-alloyed steels. However, experimental information on their suitability to fracture mechanics based approaches towards design and manufacture is found to be relatively scarce in two distinct areas:

1)      Alteration of fundamental fracture mechanics properties of Micro-alloyed steels in presence of structural restraints in the form of  pre-stress and pre-strain.

2)       Comparative study of the effect of heat treatment practice on fracture mechanics properties of Micro-alloyed steels relative to their as-rolled conditions. 

It is in this context that the present work explores experimental determination of quasi-static initiation fracture toughness (J_IC) (as per ASTM E-1820) of a low carbon (0.19%) micro-alloyed steel in as-rolled condition without any heat treatment.  The study also explores the effect of normalizing, shot-peening, and cyaniding followed by shot-peening on fracture toughness parameter so obtained. The normalizing heat treatment, shot-peening and cyaniding followed by shot-peening indicate a positive influence on initiation fracture toughness of this Micro-alloyed steel.  Results, when compared with as-rolled condition, show that cyaniding followed by shot-peening have led to a 2.7 times increase in J_IC of the Micro-alloyed Steel under study. Thus the surface hardening followed by shot-peening of (CT) specimens appears to have most positive influence in terms of enhancement of qualified J_1c values.  Although fracture initiation toughness is in general known to decrease with increase in yield strength, the Micro-alloyed steel under study when normalized displayed simultaneous improvement in yield strength and J_IC. An attempt was also made to explain these observed effects of heat treatment, mechanical pre-stress and chemical surface hardening on the initiation fracture toughness in elastic-plastic regime.