Accurate three-dimensional printing

What is claimed is: 1. A system for printing a three-dimensional object comprising: an enclosure configured to enclose, at least during printing of the three-dimensional object, an atmosphere at a pressure that is an ambient atmospheric pressure or a positive pressure above the ambient atmospheric pressure; an energy source that is configured to generate an energy beam that transforms a pre-transformed material to a transformed material as at least a portion of the three-dimensional object comprising a plurality of layers, which pre-transformed material is transformed over time to yield a plurality of physical attribute oscillations of a change in at least one physical attribute over time, wherein the transformed material comprises a plurality of melt pools that correspond to the plurality of physical attribute oscillations, wherein a layer of the plurality of layers comprises the plurality of melt pools; a detector that is configured to detect the plurality of physical attribute oscillations; and one or more controllers operatively coupled to the enclosure, the energy source and the detector, wherein the one or more controllers are configured to: (i) at least during printing the three-dimensional object, direct maintaining an interior of the enclosure at the ambient atmospheric pressure or at a positive pressure; (ii) direct the energy source to generate the energy beam that transforms the pre-transformed material to the transformed material as a first portion of the three-dimensional object, wherein transformation of the pre-transformed material over time generates the plurality of melt pools that yields the plurality of physical attribute oscillations; (iii) evaluate, or direct evaluation of, an oscillation of the plurality of physical attribute oscillations detected by the detector to generate a result; and (iv) use the result to alter at least one characteristic of the energy beam to form a melt pool as part of the three-dimensional object. 2. The system of claim 1 , wherein the plurality of physical attribute oscillations comprises (I) a first temperature of the plurality of melt pools, (II) a second temperature adjacent to the plurality of melt pools, (III) a power of the energy source that generates the energy beam, (IV) a power density of the energy beam, or (V) any combination of (I), (II), (III) and (IV), wherein the detector is configured to detect a measurement of the physical attribute oscillations over time. 3. The system of claim 1 , wherein the one or more controllers are configured to direct alteration of at least one characteristic of the energy beam at least in part by directing maintenance of substantially identical physical attribute oscillations within the plurality of physical attribute oscillations. 4. The system of claim 1 , wherein the plurality of physical attribute oscillations comprises one or more wavelengths that are emitted from the first portion, wherein the detector is configured to detect a measurement of the physical attribute oscillations over time. 5. The system of claim 1 , wherein the plurality of physical attribute oscillations comprises a wavelength of a radiation or an intensity of the radiation, which radiation is emitted (I) from a first area occupied by a footprint of the energy beam on the first portion, (II) from a second area adjacent to the first area occupied by a footprint of the energy beam on the first portion, or (III) from any combination of (I) and (II), wherein the detector is configured to detect a measurement of the physical attribute oscillations over time. 6. The system of claim 5 , wherein the detector further corresponds to, or directs a correlation to a temperature value, which correlation is of (A) the intensity of the radiation, (B) the wavelength of the radiation, or (C) both the intensity and the wavelength of the radiation. 7. The system of claim 1 , wherein the plurality of physical attribute oscillations comprises a wavelength, specularity, or an intensity of a radiation, which radiation is emitted from (I) from at least one melt pool of the plurality of the melt pools, (II) from an area adjacent to the at least one melt pool, or (III) a combination of (I) and (II), wherein the detector is configured to detect a measurement of the physical attribute oscillations over time. 8. The system of claim 1 , further comprising a layer dispensing mechanism that includes a cyclonic separator, which layer dispensing mechanism is configured to planarize a material bed that comprises the pre-transformed material. 9. The system of claim 1 , wherein the one or more controllers are configured to direct the energy source to generate the energy beam that generates a melt pool of the plurality of melt pools thus generating the plurality of physical attribute oscillations. 10. The system of claim 1 , wherein the one or more controllers are configured to direct the energy source to generate the energy beam that transforms the pre-transformed material to the transformed material thus yielding an oscillation having an asymmetric intensity profile over time, wherein the plurality of physical attribute oscillations comprises the oscillation. 11. The system of claim 1 , wherein the one or more controllers are configured to direct the energy source to generate the energy beam to transform the pre-transformed material to a transformed material in a stepwise sequence to form the plurality of melt pools. 12. A method for printing a three-dimensional object comprising: (a) providing a system comprising: an enclosure configured to enclose, at least during printing of the three-dimensional object, an atmosphere at a pressure that is an ambient atmospheric pressure or a positive pressure above the ambient atmospheric pressure; an energy source that is configured to generate an energy beam that transforms a pre-transformed material to a transformed material as at least a portion of the three-dimensional object comprising a plurality of layers, which pre-transformed material is transformed over time to yield a plurality of physical attribute oscillations of a change in at least one physical attribute over time, wherein the transformed material comprises a plurality of melt pools that correspond to the plurality of physical attribute oscillations, wherein a layer of the plurality of layers comprises the plurality of melt pools; a detector that is configured to detect the plurality of physical attribute oscillations; and one or more controllers operatively coupled to the enclosure, the energy source and the detector, wherein the one or more controllers are configured to: (i) at least during printing the three-dimensional object, direct maintaining an interior of the enclosure at the ambient atmospheric pressure or at a positive pressure; (ii) direct the energy source to generate the energy beam that transforms the pre-transformed material to the transformed material as a first portion of the three-dimensional object, wherein transformation of the pre-transformed material over time generates the plurality of melt pools that yields the plurality of physical attribute oscillations; (iii) evaluate, or direct evaluation of, an oscillation of the plurality of physical attribute oscillations detected by the detector to generate a result; and (iv) use the result to alter at least one characteristic of the energy beam to form a melt pool as part of the three-dimensional object; and (b) using the system to print the three-dimensional object. 13. The method of claim 12 , wherein a physical attribute oscillation of the plurality of physical attribute oscillations correlate to a first temperature of at least one melt pool of the plurality of mel