Batch compositions comprising spheroidal pre-reacted inorganic particles and spheroidal pore-formers and methods of manufacture of honeycomb bodies therefrom

What is claimed is: 1. A batch mixture, comprising: pre-reacted inorganic spheroidal particles having a pre-reacted particle size distribution wherein: 10 μm≤DI 50 ≤50 μm, and DIb≤2.0; and pore-former spheroidal particles having a pore-former particle size distribution wherein: 0.40 DI 50 ≤DP 50 ≤0.90 DI 50 , and DPb≤1.32, and wherein each of DI 90 , DI 50 , and DI 10 is a coarse particle diameter, a median particle diameter, or a fine particle diameter, respectively, of the pre-reacted particle size distribution of the pre-reacted inorganic spheroidal particles in which 90%, 50%, or 10%, respectively, of the pre-reacted inorganic spheroidal particles have a diameter that is equal to or less than the coarse particle diameter, the median particle diameter, or the fine particle diameter, each of DP 90 , DP 50 , DP 10 is a coarse particle diameter, a median particle diameter, or a fine particle diameter, respectively, of the pore-former particle size distribution of the pore-former spheroidal particles in which 90%, 50%, or 10%, respectively, of the pore-former spheroidal particles have a diameter that is equal to or less than the coarse particle diameter, the median particle diameter, or the fine particle diameter, respectively, DIb is a breadth factor of the pre-reacted particle size distribution of the pre-reacted inorganic spheroidal particles and DIb={DI 90 -DI 10 }/DI 50 , and DPb is a breadth factor of the pore-former particle size distribution of the pore-former spheroidal particles and DPb={DP 90 -DP 10 }/DP 50 , and wherein the batch mixture comprises less than 20% of fine inorganic particles based on a total weight of the pre-reacted inorganic spheroidal particles, wherein the fine inorganic particles have a median diameter of less than 5 μm. 2. The batch mixture of claim 1 , wherein the batch mixture comprises less than 5% of fine inorganic particles based on a total weight of the pre-reacted inorganic spheroidal particles, wherein the fine inorganic particles have a median diameter of less than 5 μm. 3. The batch mixture of claim 1 , wherein the pore-former spheroidal particles have an ARavg≤1.1, wherein ARavg is an average aspect ratio defined as a largest width dimension divided by a smallest width dimension of the pore-former spheroidal particles, on average. 4. The batch mixture of claim 1 , wherein the pore-former spheroidal particles are non-hydrophilic. 5. The batch mixture of claim 1 , wherein the pore-former spheroidal particles comprise a non-hydrophilic polymer. 6. The batch mixture of claim 1 , wherein the pore-former spheroidal particles comprises a phase change material. 7. The batch mixture of claim 1 , wherein the pore-former spheroidal particles comprise a polymer having MP≥100° C., wherein MP is a melting point of the pore-former spheroidal particles. 8. The batch mixture of claim 1 , wherein the pore-former particle size distribution of the pore-former spheroidal particles comprises DPb≤1.25. 9. The batch mixture of claim 1 , wherein the pore-former particle size distribution of the pore-former spheroidal particles comprises (DP 90 -DP 10 )≤20 μm. 10. The batch mixture of claim 1 , wherein the pore-former spheroidal particles comprise between 5 wt % and 35 wt % by super-addition to a total weight of inorganics in the batch mixture. 11. The batch mixture of claim 1 , comprising a weight of 22 wt %≤LV≤35 wt % by super-addition to inorganics of the batch mixture, wherein LV is liquid vehicle, and the pore-former spheroidal particles are non-hydrophillic. 12. The batch of claim 1 , wherein the pre-reacted inorganic particles comprise one or more crystalline phases and wherein the one or more crystalline phases comprise at least one of (i) aluminum titanate, (ii) feldspar, (iii) mullite, (iv) titania, (v) magnesia, (vi) alumina, (vii) magnesium dititanate, (viii) silicon carbide, (ix) pseudobrookite, (x) cordierite, (xi) cordierite, magnesia, aluminum titatnate composite, and (xii) combinations thereof. 13. The batch mixture of claim 1 , wherein the pre-reacted inorganic particles comprise one or more crystalline phases and wherein the pre-reacted inorganic spheroidal particles comprise a first crystalline phase predominantly of a solid solution of aluminum titanate and magnesium dititanate, and a second crystalline phase comprising cordierite. 14. The batch mixture of claim 1 , wherein the pre-reacted inorganic particles comprise one or more crystalline phases and wherein the pre-reacted inorganic spheroidal particles comprise a pseudobrookite crystalline phase comprising predominately alumina, magnesia, and titania, a second crystalline phase comprising cordierite, and a third crystalline phase comprising mullite. 15. A method of manufacturing a honeycomb body, comprising: mixing a batch mixture comprising pre-reacted inorganic spheroidal particles, fine inorganic particles, organic binder, pore-former spheroidal particles, and a liquid vehicle to form a paste, wherein the pre-reacted inorganic spheroidal particles have a pre-reacted particle size distribution of: 10 μm≤DI 50 ≤50 μm, and DIb≤2.0; and wherein the pore-former spheroidal particles having a pore-former particle size distribution of: 0.40 DI 50 ≤DP 50 ≤0.90 DI 50 , and DPb≤1.32, and wherein each of DI 90 , DI 50 , and DI 10 is a coarse particle diameter, a median particle diameter, or a fine particle diameter, respectively, of the pre-reacted particle size distribution of the pre-reacted inorganic spheroidal particles in which 90%, 50%, or 10%, respectively, of the pre-reacted inorganic spheroidal particles have a diameter that is equal to or less than the coarse particle diameter, the median particle diameter, or the fine particle diameter, each of DP 90 , DP 50 , DP 10 is a coarse particle diameter, a median particle diameter, or a fine particle diameter, respectively, of the pore-former particle size distribution of the pore-former spheroidal particles in which 90%, 50%, or 10%, respectively, of the pore-former spheroidal particles have a diameter that is equal to or less than the coarse particle diameter, the median particle diameter, or the fine particle diameter, respectively, DIb is a breadth factor of the pre-reacted particle size distribution of the pre-reacted inorganic spheroidal particles and DIb={DI 90 -DI 10 }/DI 50 , and DPb is a breadth factor of the pore-former particle size distribution of the pore-former spheroidal particles and DPb={DP 90 -DP 10 }/DP 50 ; and wherein the fine inorganic particles comprise less than 20 wt % having a median particle diameter of less than 5 μm based on a total weight of the pre-reacted inorganic spheroidal particles; and forming the paste into a wet green honeycomb body. 16. The method of manufacturing of claim 15 , comprising: drying the wet green honeycomb body to form a dried green honeycomb body; and firing the dried green honeycomb body to form a porous ceramic honeycomb body.