Disclosed herein are magnesium alloy based objects and methods of making and use thereof. For example, disclosed herein are methods of making a magnesium alloy based object, the methods comprising: heating an object comprising a preliminary magnesium alloy at a first temperature for a first amount of time, the preliminary magnesium alloy comprising a first intermetallic phase, a second intermetallic phase, and an alloy phase, to thereby substantially dissolving the first intermetallic phase into the alloy phase to form an object comprising an intermediate magnesium alloy, the intermediate magnesium alloy comprising the second intermetallic phase and the alloy phase; and heating the object comprising the intermediate magnesium alloy at a second temperature for a second amount of time to thereby substantially dissolving the second intermetallic phase into the alloy phase and minimizing incipient melting of the alloy phase to form the magnesium alloy based object.

The present invention discloses magnesium alloys, bicycle rims made of magnesium alloys, and methods of preparing the alloys and bicycle components made of the alloys. The alloys may include the following components in percentage by weight: 5.5-6.0% of Zn, 0.3-0.6% of Zr, 0.5-2.0% of lanthanum-rich mixed rare earth and the balance of Mg.

The present disclosure provides a fast-dissolved high-plasticity soluble magnesium alloy material and a preparation method thereof, including 1) making preparations, 2) smelting, 3) refining, 4) casting, 5) homogenizing treatment, 6) hot extrusion and 7) ageing treatment. The soluble magnesium material produced by the present disclosure is high in mechanical strength, good in plasticity and capable of being fast dissolved in a salt solution, and exhibits very excellent tensile strength and plastic extension strength and obvious percentage elongation after fracture during property testing, proving that the soluble magnesium of the present disclosure has good plasticity.

The present disclosure provides a fast-dissolved high-plasticity soluble magnesium alloy material and a preparation method thereof, including 1) making preparations, 2) smelting, 3) refining, 4) casting, 5) homogenizing treatment, 6) hot extrusion and 7) ageing treatment. The soluble magnesium material produced by the present disclosure is high in mechanical strength, good in plasticity and capable of being fast dissolved in a salt solution, and exhibits very excellent tensile strength and plastic extension strength and obvious percentage elongation after fracture during property testing, proving that the soluble magnesium of the present disclosure has good plasticity.

A magnesium alloy matrix having an alloy composition including aluminum at a concentration of between 0.5 wt. % to 2.5 wt. %, manganese at a concentration of between 0.3 wt. % to 1.0 wt. %, the concentration of manganese is greater than or equal to a value of [Mn] determined by a linear function [Mn]=x[Al], where x is at least 0.6 when [Al]=0.5 and is at least 0.14 when [Al]=2.5, zinc at a concentration of between 0 wt. % to 3 wt. %, tin at a concentration of between 0 wt. % to 3 wt. %, calcium at a concentration of between 0 wt. % to 0.5%, rare earth metals at a concentration of between 0 wt. % to 5 wt. %, and a balance of the alloy composition being magnesium.

The invention relates to a method for increasing a corrosion resistance of a component formed with a magnesium-based alloy against galvanic corrosion, in particular micro-galvanic corrosion. According to the invention, an increase in a corrosion resistance against galvanic corrosion is achieved in a simple manner in that a surface layer of the component having a predefined thickness, which surface layer is formed with the magnesium-based alloy, is heated in order to configure the surface layer with a homogenized solid solution phase, whereupon the surface layer is cooled such that the surface layer is formed with a supersaturated solid solution phase. The invention furthermore relates to a corrosion-resistant component which is obtainable by a method of this type.

A calcium-bearing magnesium and rare earth element alloy consists essentially of, in mass percent, zinc (Zn): 1-3%; aluminum (Al): 1-3%; calcium (Ca): 0.1-0.4%; gadolinium (Gd): 0.1-0.4%; yttrium (Y): 0-0.4%; manganese (Mn): 0-0.2%; and balance magnesium (Mg).

A calcium-bearing magnesium and rare earth element alloy consists essentially of, in mass percent, zinc (Zn): 1-3%; aluminum (Al): 1-3%; calcium (Ca): 0.1-0.4%; gadolinium (Gd): 0.1-0.4%; yttrium (Y): 0-0.4%; manganese (Mn): 0-0.2%; and balance magnesium (Mg).

Provided are a copper-containing, high-toughness and rapidly degradable magnesium alloy, a preparation method therefor and the use thereof, wherein same relate to the field of materials for oil and gas exploitation. When the magnesium alloy is in an as-cast state, an extrusion state or an aging state, a strengthening phase thereof mainly includes an Mg.sub.12CuRE-type long-period phase and an Mg.sub.5RE phase and an Mg.sub.2Cu phase, the Mg.sub.12CuRE-type long-period phase has a volume fraction of 3-60%, the Mg.sub.5RE phase has a volume fraction of 0.5-20%, and the Mg.sub.2Cu phase has a volume fraction of 0.5-15%, wherein RE is a rare-earth metal element.

Provided are a copper-containing, high-toughness and rapidly degradable magnesium alloy, a preparation method therefor and the use thereof, wherein same relate to the field of materials for oil and gas exploitation. When the magnesium alloy is in an as-cast state, an extrusion state or an aging state, a strengthening phase thereof mainly includes an Mg.sub.12CuRE-type long-period phase and an Mg.sub.5RE phase and an Mg.sub.2Cu phase, the Mg.sub.12CuRE-type long-period phase has a volume fraction of 3-60%, the Mg.sub.5RE phase has a volume fraction of 0.5-20%, and the Mg.sub.2Cu phase has a volume fraction of 0.5-15%, wherein RE is a rare-earth metal element.