Microalloyed linepipe steels were first introduced in 1959 at strength levels around 52-60 ksi [1] [2].The steels were generally strengthened by niobium or vanadium used singly.As strengths levels increased to X-70 in the early 1970’s niobium and vanadium were used in combination and controlled rolling was introduced on a broad basis.Higher strengths decrease tolerance for impurities and non-metallic inclusions which required improved steelmaking practices.Sulfur,carbon,and nitrogen were reduced and continuous casting was increasingly applied which required improved ladle refining and deoxidation practices.Niobium-molybdenum steels were introduced by IPSCO in 1972 [3] and by Italsider in 1974 [4].Steels with higher niobium contents were also introduced in the early 1970’s but available steelmaking technologies limited the use of optimum niobium to carbon ratios,i.e.those approaching stoichiometry.Nevertheless the steels benefited from the effect of niobium in retarding austenite recrystallization at relatively high rolling temperatures and they developed attractive combinations of strength and toughness in old manufacturing facilities using simple (relaxed) rolling schedules.Fluctuations in the price of molybdenum and vanadium in the past decade and expanded application of API Grade X-80 linepipe,have led to more widespread use of niobium contents up to 0.11 percent,in combination with 0.02-0.03 percent carbon (near stoichiometry) thus maximizing the effects of solute niobium during rolling,in lowering transformation temperature,and thereby reducing reliance on other alloying,often expensive,elements.The history of these developments will be presented and applications of the concept will be summarized. Microalloyed linepipe steels were first introduced in 1959 at strength levels around 52-60 ksi [1] [2]. The steels were generally strengthened by niobium or vanadium used singly. As strengths levels increased to X-70 in the early 1970’s niobium and vanadium were used in combination and controlled rolling was introduced on a broad basis .Higher strengths decrease tolerance for impurities and non-metallic inclusions which required improved steelmaking practices. sulfur, carbon, and nitrogen were reduced and continuous casting was increasingly applied which required improved ladle refining and deoxidation practices. Niobium-molybdenum steels were introduced by IPSCO in 1972 [3] and by Italsider in 1974 [4]. Steels with higher niobium contents were also introduced in the early 1970’s but available steelmaking technologies limited the use of optimum niobium to carbon ratios, iethose approaching stoichiometry.Nevertheless the steels benefited from the effect of niobium in retarding austenite recrys tallization at relatively high rolling temperatures and they developed attractive combinations of strength and toughness in old manufacturing facilities using simple (relaxed) rolling schedules. Fluctuations in the price of molybdenum and vanadium in the past decade and expanded application of API Grade X-80 linepipe, have led to more widespread use of niobium contents up to 0.11 percent, in combination with 0.02-0.03 percent carbon (near stoichiometry) thus maximizing the effects of solute niobium during rolling, in lowering transformation temperature, and thereby reducing reliance on other alloying, often expensive, elements. The history of these developments will be presented and applications of the concept will be summarized.