Mixer for Producing and Solidifying an Alloy in a Subterranean Reservoir

1 . A downhole tool comprising: a housing configured to be placed into a subterranean environment; and a mixer disposed in the housing, wherein the mixer comprises: a first inlet configured to receive a fusible metal or alloy component; a second inlet configured to receive a solid metal or semi-metal component; a mixing chamber configured to mix the fusible metal or alloy component and the solid metal or semi-metal component to form a liquid or partially liquid alloy; and an outlet configured to discharge the liquid or partially liquid alloy into the subterranean environment, wherein the liquid or partially liquid alloy is configured to harden into a solid alloy over time. 2 . The downhole tool of claim 1 , comprising a heating device configured to provide thermal energy to the fusible metal or alloy component or the solid metal or semi-metal component, or both, before the fusible metal or alloy component or the solid metal or semi-metal component, or both, enter the mixing chamber, wherein the heating device is configured to ensure the fusible metal or alloy component is at least partially liquid in the mixing chamber. 3 . The downhole tool of claim 1 , comprising a crushing device configured to fragment the fusible metal or alloy component or the solid metal or semi-metal component, or both, before the fusible metal or alloy component or the solid metal or semi-metal component, or both, enter the mixing chamber. 4 . The downhole tool of claim 1 , comprising a cooling device configured to remove thermal energy from the liquid or partially liquid alloy before the liquid or partially liquid alloy exits the mixing chamber, after the liquid or partially liquid alloy exits the mixing chamber, or both. 5 . The downhole tool of claim 1 , comprising a shaft having an impeller configured to mix the fusible metal or alloy component and the solid metal or semi-metal component in the mixing chamber. 6 . The downhole tool of claim 5 , wherein at least a portion of the impeller comprises a heating element configured to simultaneously thermal energy and mix the fusible metal or alloy component and the solid metal or semi-metal component in the mixing chamber. 7 . The downhole tool of claim 1 , wherein the mixing chamber is configured to shake or vibrate to mix the fusible metal or alloy component and the solid metal or semi-metal component in the mixing chamber utilizing sonic technology, ultrasonic technology, piezoelectric technology, or a combination thereof. 8 . The downhole tool of claim 1 , comprising a first storage portion configured to store the fusible metal or alloy component and a second storage portion configured to store the solid metal or semi-metal component. 9 . The downhole tool of claim 8 , wherein the fusible metal or alloy component is stored in the first storage portion as a liquid material. 10 . The downhole tool of claim 8 , wherein the fusible metal or alloy component is stored in the first storage portion as a solid material. 11 . The downhole tool of claim 10 , wherein the fusible metal or alloy component is at least partially liquefied by a heater or a grinder before entering the mixing chamber. 12 . The downhole tool of claim 1 , wherein the fusible metal or alloy component is configured to be a liquid metal at a temperature lower than 250° C. and 1 atm. 13 . A method comprising: placing a downhole tool into a subterranean environment; producing a liquid or partially liquid alloy via a mixer of the downhole tool by: contacting a liquid fusible metal or alloy component with a solid metal or semi-metal component within the mixer; mixing the liquid fusible metal or alloy component and the solid metal or semi-metal component to form the liquid or partially liquid alloy, wherein the liquid fusible metal or alloy component and the solid metal or semi-metal component react via metallurgical reactions that produce the liquid or partially liquid alloy; and discharging the liquid or partially liquid alloy into the subterranean environment, wherein the liquid or partially liquid alloy is configured to harden into a solid alloy over time. 14 . The method of claim 13 , wherein producing the liquid or partially liquid alloy via the mixer of the downhole tool comprises melting a solid fusible metal or alloy component via a heat source to form the liquid fusible metal or alloy component. 15 . The method of claim 13 , wherein producing the liquid or partially liquid alloy via the mixer of the downhole tool comprises fragmenting the solid metal or semi-metal component into a powder via a grinder of the mixer to reduce a particle size of the solid metal or semi-metal component. 16 . The method of claim 13 , wherein mixing the liquid fusible metal or alloy component and the solid metal or semi-metal component to form the liquid or partially liquid alloy comprises shaking or vibrating the liquid fusible metal or alloy component and the solid metal or semi-metal component in a mixing chamber of the mixer. 17 . The method of claim 13 , wherein producing the liquid or partially liquid alloy via the mixer of the downhole tool comprises cooling the liquid or partially liquid alloy via a cooler portion of the mixer or the downhole tool to reduce the time by which the liquid or partially liquid alloy is configured to harden into the solid alloy. 18 . A downhole tool comprising: a housing configured to be placed into a subterranean environment; and a mixer disposed in the housing, wherein the mixer comprises: a first inlet configured to receive a fusible metal or alloy component, wherein the fusible metal or alloy component comprises an onset of melting temperature that is within a threshold range of a temperature of the subterranean environment; a second inlet configured to receive a solid metal or semi-metal component, wherein the solid metal or semi-metal component comprises a particle size that is within a particle size threshold; a mixing chamber configured to mix the fusible metal or alloy component and the solid metal or semi-metal component to form a liquid or partially liquid alloy, wherein the liquid or partially liquid alloy is a product of intermetallic reactions between a mixture of the fusible metal or alloy component and the solid metal or semi-metal component, and wherein a specific gravity of the fusible metal or alloy component and the solid metal or semi-metal component are within 20% from one another; and an outlet configured to discharge the liquid or partially liquid alloy into the subterranean environment, wherein the liquid or partially liquid alloy is configured to harden into a solid alloy over time. 19 . The downhole tool of claim 18 , wherein the fusible metal or alloy component comprises mercury, gallium, indium, tin, bismuth, lead, antimony, zinc, copper, or a combination thereof. 20 . The downhole tool of claim 19 , wherein the solid metal or semi-metal component comprises SbSn, InSb, BiSn, CdSb, SbZn, Sb 2 Sn 3 , Cu 2 Sb, Cu 10 Sb 3 or a combination thereof.