Effect of boron on corrosion resistance of Al-2.5 wt% Cu allov

“…At high temperatures, the boron content increases the ductility and hot flow of the material [6][7][8][9], and promotes the austenitic grain refinement [6,10]. As micro-alloying element, boron segregates at the austenite grain boundaries because of two phenomena: the equilibrium [9] and the non-equilibrium segregation [11][12]. A steel deformed at high temperature allows higher deformations at lower stresses and this process is characterized by three main stages: hardening (by increasing dislocations density) [13], softening (by dynamic recrystallization (DRX)) [14][15][16][17] and stable state (by balance between hardening and recovery) [17].…”

Boron Effect on the Softening Parameter (Ω) of Advanced Ultra-High Strength Steels (A-UHSS) under Uniaxial Hot-Compression Conditions

“…At high temperatures, the boron content increases the ductility and hot flow of the material [6][7][8][9], and promotes the austenitic grain refinement [6,10]. As micro-alloying element, boron segregates at the austenite grain boundaries because of two phenomena: the equilibrium [9] and the non-equilibrium segregation [11][12]. A steel deformed at high temperature allows higher deformations at lower stresses and this process is characterized by three main stages: hardening (by increasing dislocations density) [13], softening (by dynamic recrystallization (DRX)) [14][15][16][17] and stable state (by balance between hardening and recovery) [17].…”

Boron Effect on the Softening Parameter (Ω) of Advanced Ultra-High Strength Steels (A-UHSS) under Uniaxial Hot-Compression Conditions

The opposing nanoscale and macroscale effects of selected nanoparticle addition to AZ91/ZK60A hybrid magnesium alloy

Structural and electrochemical study of resorbable Ca32Mg12Zn38Yb18-xBx (x=1, 2, 3) metallic glasses in Ringer's solution