Battery electrode composition comprising carbon and silicon with specific properties for superior performance

1 . A lithium-ion battery anode composition, comprising: a porous composite particle comprising carbon (C) and an active material comprising silicon (Si), wherein the carbon is characterized by a domain size (r), as estimated from an atomic pair distribution function G(r) obtained from a synchrotron x-ray diffraction measurement of the porous composite particle, ranging from around 10 Å (1 nm) to around 60 Å (6 nm). 2 . The lithium-ion battery anode composition of claim 1 , wherein the carbon is characterized by one or more of the following: (1) a domain size ranging between around 15 Å and around 19 Å, (2) a domain size ranging between around 19 Å and around 22 Å, (3) a domain size ranging between around 24 Å and around 28 Å, and (4) a domain size ranging between around 28 Å and 55 Å, and wherein the domain sizes are as estimated from the atomic pair distribution function G(r). 3 . The lithium-ion battery anode composition of claim 1 , wherein the carbon comprises porous carbon. 4 . The lithium-ion battery anode composition of claim 1 , wherein G(r=r 1 ) is a value of the atomic pair distribution function at a real space position of a first coordination sphere of the carbon, wherein G(r=r 2 ) is a value of the atomic pair distribution function at a real space position of a second coordination sphere of the carbon, and wherein a ratio G(r=r 1 )/G(r=r 2 ) is in a range of around 0.700 to around 0.590. 5 . The lithium-ion battery anode composition of claim 1 , wherein W(r=r 1 ) is a value of a full width at half maximum of the atomic pair distribution function at a real space position of a first coordination sphere of the carbon, wherein W(r=r 2 ) is a value of a full width at half maximum of the atomic pair distribution function at a real space position of a second coordination sphere of the carbon; and wherein a ratio W(r=r 1 )/W(r=r 2 ) is in a range of around 0.700 to around 0.850. 6 . The lithium-ion battery anode composition of claim 1 , wherein G(r=r 1 ) is a value of the atomic pair distribution function at a real space position of a first coordination sphere of the carbon, wherein G(r=r 3 ) is a value of the atomic pair distribution function at a real space position of a third coordination sphere of the carbon, and wherein a ratio G(r=r 1 )/G(r=r 3 ) is in a range of around 1.100 to around 1.300. 7 . The lithium-ion battery anode composition of claim 1 , wherein W(r=r 1 ) is a value of a full width at half maximum of the atomic pair distribution function at a real space position of a first coordination sphere of the carbon, wherein W(r=r 3 ) is a value of a full width at half maximum of the atomic pair distribution function at a real space position of a third coordination sphere of the carbon, and wherein a ratio W(r=r 1 )/W(r=r 3 ) is in a range of around 0.600 to around 0.850. 8 . The lithium-ion battery anode composition of claim 1 , wherein an anode comprising the anode composition exhibits an areal capacity loading that ranges from around 2 mAh/cm 2 to around 16 mAh/cm 2 . 9 . The lithium-ion battery anode composition of claim 8 , wherein from around 10% to around 100% of the areal capacity loading of the anode is provided by composite particles that are each configured as the porous composite particle. 10 . The lithium-ion battery anode composition of claim 8 , wherein the composite particles on average exhibit a silicon (Si) to carbon (C) weight ratio in the range from around 5:1 to 1:5. 11 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle is characterized by an average scattering domain size (r), as estimated from the atomic pair distribution function G(r), ranging from around 1 nm to around 40 nm. 12 . The lithium-ion battery anode composition of claim 11 , wherein the porous composite particle is characterized by the average scattering domain size (r) ranging from around 1 nm to around 10 nm. 13 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle on average comprises less than about 1 wt. % hydrogen (H), less than about 5 wt. % nitrogen (N) and less than about 2 wt. % oxygen (O). 14 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle on average exhibits uptake from around 1.5 wt. % to around 25 wt. % nitrogen (N) when heated in a nitrogen gas (N 2 ) at 1050° C. for a period of 2 hours, as measured on a powder that comprises the porous composite particle. 15 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle exhibits average uptake from around 0.5 wt. % to around 10 wt. % nitrogen (N) when heated in a nitrogen gas (N 2 ) at 850° C. for a period of 2 hours, as measured on a powder that comprises the porous composite particle. 16 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle forms from around 1 wt. % to around 100 wt. % silicon carbide (SiC) when heated in a nitrogen gas (N 2 ) or in an argon gas (Ar) in a temperature range from around 750° C. to around 950° C. for a period of 2 hours or more, as detected by X-ray diffraction (XRD) or Fourier Transform Infrared Spectroscopy (FTIR). 17 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle exhibits an average Brunauer-Emmett-Teller (BET) specific surface area in the range from around 1 to around 40 m 2 /g, as measured using nitrogen sorption isotherm on a powder that comprises the porous composite particle. 18 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle exhibits average density in the range from around 0.9 g/cm 3 to around 2.2 g/cm 3 , as measured using nitrogen or argon pycnometry on a powder that comprises the porous composite particle. 19 . The lithium-ion battery anode composition of claim 1 , wherein the porous composite particle exhibits volume-average particle size in the range from around 0.2 micron to around 20 microns, as measured using scanning electron microscope (SEM) image analysis or particle scattering techniques on a powder that comprises the porous composite particle. 20 . The lithium-ion battery anode composition of claim 1 , wherein Raman spectra of the porous composite particle exhibits carbon D and G peaks, wherein a ratio of average intensities of the D to G peaks (I D /I G ) ranges from around 0.7 to around 2.7. 21 . A Li-ion battery comprising: an anode comprising the lithium-ion battery anode composition of claim 1 ; a cathode that is electrically separated from the anode; and an electrolyte ionically coupling the anode and the cathode. 22 . The Li-ion battery of claim 21 , wherein the battery capacity ranges from around 0.2 Ah to around 400 Ah. 23 . The Li-ion battery of claim 21 , wherein R(r=r Si—C ) is a value of a radial distribution function R(r) at a real space position of a first coordination sphere of a Si—C pair in the porous composite particle, wherein R(r=r C—C ) is a value of the radial distribution function R(r) at a real space position of a first coordination sphere of a C—C pair in the porous composite particle, wherein the radial distribution function R(r) and the atomic pair distribution function are related by R(r)=G(r)r+4πr 2 ρ 0 , ρ 0 being a constant relating to a number density of scatterers, and wherein a ratio R(r=r Si—C )/R(r=r C—C ) is in a range of 0.050 to around 1.000.