How does higher carbon content in steel influence weldability and cracking tendency?

• A. Higher carbon reduces hardness and the risk of hydrogen-induced cracking.
• B. Higher carbon content increases hardness and hydrogen-induced cracking risk in the HAZ.
• C. Carbon content has no effect on weldability.
• D. Lower carbon content makes the weld harder.

Answer: (B)

The main idea is how carbon content controls the hardness of the weld region and its tendency to crack under hydrogen-related conditions. As carbon content increases, steel becomes more hardenable. When welding, the heat-affected zone cools rapidly, promoting the formation of harder, more brittle microstructures like martensite in higher-carbon steels. That brittleness makes the HAZ less able to tolerate tensile stresses, so cracks can initiate and propagate more easily. Hydrogen from the welding process can diffuse into the metal and accumulate at flaws or grain boundaries in these hard zones, leading to hydrogen-induced cracking under restrained conditions. So, higher carbon content raises both hardness and the risk of hydrogen-induced cracking in the HAZ, reducing weldability. Mitigation strategies include preheating to slow cooling, using low-hydrogen consumables, and post-weld heat treatment to relieve stresses and reduce hardness.