Method and system for regulating cryogenic vapor pressure

What is claimed is: 1. A method for use in regulating vapor pressure within a vessel, said method comprising: receiving, by a controller, one of a predefined pressure value and a predefined pressure range from an input interface; receiving, by the controller, a measurement of the vapor pressure within the vessel; in response to determining that the measurement of the vapor pressure within the vessel is not at the predefined pressure value or within the predefined pressure range, automatically determining, with the controller, whether to cause an operating mode of a thermoelectric temperature adjustment mechanism to change to a heating mode or a cooling mode, wherein the thermoelectric temperature adjustment mechanism is coupled to the vessel; and transmitting, via the controller, a control signal to cause the thermoelectric temperature adjustment mechanism to change to the heating mode from the cooling mode, or to change to the cooling mode from the heating mode, based on the determination of whether to cause the operating mode of the thermoelectric temperature adjustment mechanism to change to the heating mode or to the cooling mode, wherein the heating mode causes heat to transfer to the vessel from a heat source, and wherein the cooling mode causes a transfer of heat from the vessel to a cold source. 2. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a cooling mode; and increasing, with the controller, heat extracted from the vessel when the vapor pressure is higher than a predefined pressure defining a high end of the predefined pressure range. 3. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a heating mode; setting, with the controller, the temperature adjustment mechanism to a cooling mode; and increasing, with the controller, heat extracted from the vessel when the vapor pressure is higher than a predefined pressure defining a high end of the predefined pressure range. 4. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a heating mode; and decreasing, with the controller, heat imparted to the vessel when the vapor pressure is higher than a predefined pressure defining a high end of the predefined pressure range. 5. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a heating mode; and increasing, with the controller, heat imparted to the vessel when the vapor pressure is lower than a predefined pressure defining a low end of the predefined pressure range. 6. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a cooling mode; setting, with the controller, the temperature adjustment mechanism to a heating mode; and increasing, with the controller, heat imparted to the vessel when the vapor pressure is lower than a predefined pressure defining a low end of the predefined pressure range. 7. The method in accordance with claim 1 further comprising: identifying, with the controller, whether the temperature adjustment mechanism is in a cooling mode; and decreasing, with the controller, heat extracted from the vessel when the vapor pressure is lower than a predefined pressure defining a low end of the predefined pressure range. 8. The method in accordance with claim 1 , wherein the thermoelectric temperature adjustment mechanism includes at least two stages that each include a plurality of semiconducting blocks that are electrically coupled in series via a plurality of electric conductors. 9. The method in accordance with claim 1 , wherein the thermoelectric temperature adjustment mechanism is coupled to the vessel, wherein the thermoelectric temperature adjustment mechanism includes a cold plate coupled to a vessel wall and a hot plate coupled to at least one of an ambient environment, a heat sink, and a heat source. 10. The method in accordance with claim 9 , wherein the thermoelectric temperature adjustment mechanism comprises a plurality of thermoelectric elements positioned between the cold plate and the hot plate. 11. The method in accordance with claim 9 , wherein a switch is coupled to the thermoelectric temperature adjustment mechanism, said method further comprising adjusting, with the controller, a heat transfer between the vessel and at least one of the ambient environment, the heat sink, and the heat source when the switch is moved between a first position and a second position. 12. The method in accordance with claim 1 further comprising adjusting, with the controller, an amount of voltage applied to the thermoelectric temperature adjustment mechanism to return the vapor pressure back to within the predefined pressure range, and determining what amount to adjust the amount of voltage applied to the thermoelectric temperature adjustment mechanism. 13. A vapor pressure regulation system comprising: a vessel comprising a vessel wall that defines an enclosure; a thermoelectric temperature adjustment mechanism coupled to said vessel, said temperature adjustment mechanism configured to transfer heat between said vessel and said temperature adjustment mechanism to facilitate regulating a vapor pressure within said vessel; and a controller for use in regulating vapor pressure within the vessel, said controller comprising a memory device and a processor coupled to said memory device and an input interface, said controller programmed to: receive one of a predefined pressure value and a predefined pressure range from an input interface; receive a measurement of the vapor pressure within said vessel; in response to determining that the measurement of the vapor pressure within said vessel is not at the predefined pressure value or within the predefined pressure range, automatically determine whether to cause an operating mode of said thermoelectric temperature adjustment mechanism to change to a heating mode or a cooling mode; and transmit a control signal to cause said thermoelectric temperature adjustment mechanism to change to the heating mode from the cooling mode, or to change to the cooling mode from the heating mode, based on the determination of whether to cause the operating mode of said thermoelectric temperature adjustment mechanism to change to the heating mode or to the cooling mode, wherein the heating mode causes heat to transfer to said vessel from a heat source, and wherein the cooling mode causes a transfer of heat from said vessel to a cold source. 14. The vapor pressure regulation system in accordance with claim 13 , wherein said controller is further programmed to: identify whether the vapor pressure within said vessel is between a lower predefined pressure and a higher predefined pressure; and adjust the heat transfer between said thermoelectric temperature adjustment mechanism and said vessel based on at least the vapor pressure within said vessel. 15. The vapor pressure regulation system in accordance with claim 13 , wherein said thermoelectric temperature adjustment mechanism comprises a cold plate and a hot plate, said cold plate coupled to said vessel wall, said hot plate coupled to a heat sink. 16. The vapor pressure regulation system in accordance with claim 15 , wherein said thermoelectric temperature adjustment mechanism comprises a plurality of thermoelectric elemen