Multi-stage magnesiothermic reduction for production of silicon oxides with reduced silicon grain size

What is claimed is: 1 . A composition of matter useful as an electrode in an electrochemical cell, comprising: a composite comprising a reduced compound, wherein: the reduced compound comprises particles, each of the particles comprise a grain embedded in silicon dioxide, the grain comprises silicon, the grain has a largest dimension D, and 3 nanometers ≤ D ≤ 30 nanometers. 2 . The composition of matter of claim 1 , wherein the reduced compound is formed using a process comprising a multi-stage magnesiothermic reduction. 3 . The composition of matter of claim 1 , wherein the composite has a specific surface area (SSA) and 5 m 2 g -1 ≤ SSA≤ 350 m 2 g -1 or 5 m 2 g -1 ≤ SSA≤ 100 m 2 g -1 . 4 . The composition of matter of claim 1 , wherein each of the grains has the largest dimension D and 3 nm ≤ D ≤ 30 nm or 5 nm ≤ D ≤ 20 nm. 5 . The composition of matter of claim 1 , wherein the particles have a silicon content Ct (relative to oxygen) in a range and SiO 1.8 ≤ Ct ≤ SiO 0.3 or SiO 0.9 ≤ Ct ≤ SiO 0.6 . 6 . The composition of matter of claim 1 , wherein the composite has at least one of a specific surface area (SSA), a silicon content, the dimensions of the particles, a solid-electrolyte interphase thickness, a porosity, or a degree of cracking/fracturing wherein: an electrochemical half cell comprising a first electrode comprising the composite, a second electrode comprising lithium, and a lithium containing electrolyte, undergoes charging, in response to a voltage applied to the anode in a range of 0.01-1.5 V vs. Li+/Li, and discharging, the charging and discharging are according to electrochemical reactions lithiating or de-lithiating the electrodes and the grains, allowing transport of the lithium by the electrolyte between the first electrode and the second electrode, and the charging and discharging has an initial coulombic efficiency of at least 70% and a reversible capacity of at least 1500 mAhg -1 . 7 . A fuel cell or lithium ion battery comprising an anode comprising the composition of matter of claim 1 . 8 . The composition of matter of claim 1 , wherein the composite has at least one of the SSA, the silicon content, the dimensions of the particles, an amount of solid-electrolyte interphase, a porosity, or a degree of cracking/fracturing wherein: an electrochemical full cell comprising a first electrode comprising the composite, a second electrode comprising lithium, and a lithium containing electrolyte, undergoes charging, in response to a potential applied to the anode in a range of 0.01-1.5 V vs. Li+/Li, and discharging, the charging and discharging are according to electrochemical reactions lithiating or de-lithiating the electrodes and the grains so as to allow transport of the lithium by the electrolyte between the first electrode and the second electrode, and the charging and discharging has a coulombic efficiency of at least 99% and a reversible capacity of at least 130 mAhg -1 after 50 cycles of charging. 9 . The composition of matter of claim 1 , wherein any cracks in the composite have a thickness less than 3 nm and any pores in the composite have a volume less than 0.02 cm 3 g -1 . 10 . An electrochemical cell comprising: an anode comprising the composition of matter of claim 9 ; an electrolyte comprising LiPF 6 dissolved in ethylene carbonate and dimethyl carbonate; and a cathode coupled via the electrolyte to the anode, wherein the cathode comprises at least one of LiFePO 4 , LiMnPO 4 , LiCoO 2 , or LiNi x Co y MnZO 2 . 11 . A method of making a composition of matter useful as an electrode in an electrochemical cell, comprising: providing a precursor comprising silicon oxide; and reducing the precursor using a multi-stage magnesiothermic reduction reaction so as to form a composite comprising silicon and oxygen. 12 . The method of claim 11 , wherein the precursor comprises at least one of amorphous silica, quartz or purified sand, borosilicate and soda lime, silicon monoxide, or Stöber silica. 13 . The method of claim 12 , wherein the precursor comprises particles each having a largest diameter of 0.5 - 10 µm for the amorphous silica or crystalline silica or 0.5 -45 µm for the borosilicate, soda lime, and the silicon monoxide. 14 . The method of claim 11 , wherein: the multi-stage magnesiothermic reduction comprises repeating the reaction SiO 2 (s) + 2Mg(g) → Si(s) + 2MgO(s), the precursor comprises the SiO 2 , and the product comprising silicon from one stage is used as the precursor comprising the SiO 2 in a next stage. 15 . The composition of claim 14 , further comprising adjusting or selecting a reactant mass ratio SiO 2 :Mg in each of the stages of the magnesiothermic reduction so that 5:3 ≤ SiO 2 :Mg ≤ 10:1. 16 . The method of claim 14 , further comprising performing each stage of the reaction in a presence of a temperature-control-agent comprising at least one of NaCl, NaBr, KCl, LiCl, LiBr, LiI, or a mixture of NaCl and KCl. 17 . The method of claim 16 , further comprising adjusting or selecting a mass ratio temperature-control agent : reactant in each stage so that 1:1 ≤ temperature-control agent: reactant ≤ 5:1. 18 . The method of claim 14 , further comprising adjusting or selecting a dwell temperature of the stages such that 500° C.≤ T ≤ 800° C. 19 . The method of claim 11 , wherein each stage of the magnesiothermic reaction comprises: (a) adding an amount of magnesium relative to the precursor comprising silicon dioxide in the reactor, so that a first ratio of the magnesium to the precursor in each of the stages is less than a ratio of magnesium to precursor used in a one stage magnesiothermic reaction; (b) adding a temperature control agent to form a mixture comprising the temperature control agent, the precursor, and the magnesium, so that a second ratio of the precursor to the temperature control agent in each of the stages is more than 1:25; (c) heating the mixture to a temperature, wherein the second ratio stabilizes a temperature of the mixture to a set temperature with greater accuracy, as compared to in the one stage magnesiothermic reaction; and (d) cooling the heated mixture to room temperature below 40° C. before the adding of the magnesium in the next stage; wherein: the composite comprises particles each comprising a grain comprising silicon, the grain having a largest dimension D; and the ratio of the magnesium to the precursor and the set temperature in each of the stages are selected to control the largest dimension D such that 3 nanometers ≤ D ≤ 30 nanometers while keeping a ratio of the precursor to any temperature control agent above 1:10. 20 . The method of claim 11 , further comprising: adding a mixture of the precursor, magnesium, and optionally any temperature control agents to a reactor in a first region of the reactor; optionally, adding water and a carbon precursor to a second region of the reactor at a bottom of the reactor, wherein the first region and the second region are separated by a porous or permeable separator through which water vapor may be transmitted and the first region is above the second region; and performing the multi-stage magnesiothermic reduction reaction comprising heating the reactor so that the first region and the second region of the reactor are at a temperature in a range of 500-800° C. and the temperature is increased in a plurality of stages. 21 . A composition of matter useful as an electrode in an electrochemic