Three-dimensional printing of three-dimensional objects

What is claimed is: 1 . A three-dimensional object, comprising: a plurality of layers of hard material stacked layerwise and bonded together to form a shape of the three-dimensional object, wherein a layer of the plurality of layers defines a layering plane, which plurality of layers comprises: a first section comprising a first microstructure associated with being formed at a first solidification rate; and a second section is at least a portion of an overhang comprising: (i) a second microstructure associated with being formed at a second solidification rate that is different from the first solidification rate, and (ii) an exterior surface corresponding to at least a fraction of an exterior surface of the three-dimensional object, wherein an overhang vector at a point on the exterior surface of the second section is normal to a surface at the point in a direction towards an interior of the overhang, wherein a stacking vector corresponds to a stacking direction of the plurality of layers, which stacking vector is normal to the layering plane, wherein the overhang vector has a positive projection onto the stacking vector, wherein the stacking direction of the plurality of layers is indicative from (1) any directional melt pool that is included in the plurality of layers, (2) a direction opposite from any auxiliary supports or auxiliary support marks, (3) a direction of a surface comprising hatch decomposition marking, (4) any asymmetric surface roughness, or (5) any directionality in grain orientation, indicative of print orientation. 2 . The three-dimensional object of claim 1 , wherein the first section is characterized as comprising the first microstructure and wherein the second section is characterized as comprising the second microstructure. 3 . The three-dimensional object of claim 1 , wherein the first and second sections are coupled with each other. 4 . The three-dimensional object of claim 1 , wherein the second solidification rate is slower than the first solidification rate. 5 . The three-dimensional object of claim 1 , wherein the first microstructure and second microstructure each comprise a melt pool, or a grain structures. 6 . The three-dimensional object of claim 5 , wherein the grain structure comprises a crystal. 7 . The three-dimensional object of claim 1 , wherein the second section corresponds to a skin of the three-dimensional object. 8 . The three-dimensional object of claim 7 , wherein the skin has a thickness ranging from about 20 micrometers to about 1000 micrometers. 9 . The three-dimensional object of claim 7 , wherein the skin has corresponding to a fundamental length scale of a melt pool. 10 . The three-dimensional object of claim 1 , wherein the second section is characterized by an alignment line that runs through a central portion of the melt pool and/or along the exterior surface of the second section, wherein the second microstructure comprises grain structures that are aligned with respect to the alignment line. 11 . The three-dimensional object of claim 10 , wherein the grain structures are aligned at a non-zero angle relative to the alignment line. 12 . The three-dimensional object of claim 1 , wherein the first section comprises a first set of grains, wherein the second section comprises a second set of grains, wherein grains of the second set have on average a different property than the first set comprising: a fundamental length scale, a chemical makeup, a crystal structure, a coherence length, a morphology, a metallurgical microstructure, or an alignment. 13 . The three-dimensional object of claim 11 , wherein the grains of the second set have a fundamental length scale that is on average about 1.5 times thicker than the grains of the first set. 14 . The three-dimensional object of claim 11 , wherein the grains of the second set have a greater coherence length, fundamental length scale, and/or alignment. 15 . The three-dimensional object of claim 1 , wherein the overhang vector forms an angle with the stacking vector that is at most about forty-five degrees, and at least about zero degrees. 16 . The three-dimensional object of claim 1 , wherein the overhang vector forms an angle with the stacking vector that is at most about thirty degrees, and at least about zero degrees. 17 . The three-dimensional object of claim 1 , wherein the overhang vector forms an angle with the stacking vector that is at most about ten degrees, and at least about zero degrees. 18 . The three-dimensional object of claim 1 , wherein the first and second sections are bonded with each other. 19 . The three-dimensional object of claim 1 , wherein the first section has a first surface roughness and the second surface has a second surface roughness, wherein the first surface roughness and the second surface roughness have an arithmetic average of a roughness profile (Ra) value of at most about 20 micrometers. 20 . The three-dimensional object of claim 19 , wherein the first surface roughness and/or the second surface roughness have an arithmetic average of a roughness profile (Ra) value of at most 10 micrometers. 21 . The three-dimensional object of claim 1 , wherein the first section has a first surface roughness and the second surface has a second surface roughness that is detectably different from the first surface roughness. 22 . The three-dimensional object of claim 21 , wherein the first roughness is at least 2 times rougher than the second roughness. 23 . The three-dimensional object of claim 1 , wherein the overhang is a three-dimensional plane. 24 . The three-dimensional object of claim 1 , wherein the overhang is a ledge. 25 . The three-dimensional object of claim 1 , wherein the melt pool comprises a narrow bottom portion and a broader top portion, wherein the auxiliary support marks comprise a point of discontinuity of layer structure akin a foreign object, wherein the hatch decomposition marking relates to a hatch strategy that divides a top surface into segments, wherein to directly adjacent segments differ at least a hatching direction from one another, wherein the asymmetric surface roughness indicative of print orientation is caused by a print process in which the bottom surface has a different roughness than the top surface.