Using waste heat from a data center cooling system to facilitate low-temperature desalination

What is claimed is: 1. A low-temperature desalination system, comprising: an inlet configured to receive cold saline water, wherein the cold saline water is ocean water; a liquid-cooling system for a computer data center, which is coupled to the inlet, wherein the liquid-cooling system uses the cold saline water as a coolant, thereby causing the cold saline water to become heated saline water; a vacuum evaporator configured to receive the heated saline water and produce water vapor, wherein the vacuum evaporator comprises a water column having a headspace, which is under a negative pressure due to gravity pulling on the heated saline water in the water column; a condenser coupled to the vacuum evaporator, which condenses the water vapor to produce desalinated water; a telemetry harness, which receives telemetry data from the data center; a control unit, which uses the received telemetry data to optimize a desalination efficiency of the vacuum evaporator and a computational performance of the computer data center by scheduling jobs having different priorities in the computer data center to control variations in an aggregate thermal load of the computer data center, thereby indirectly controlling variations in a temperature of the heated saline water, which affects the desalination efficiency of the vacuum evaporator; and wherein while scheduling the different priority jobs, the control unit makes a tradeoff between the desalination efficiency and computational performance for the different priority jobs. 2. The low-temperature desalination system of claim 1 , wherein the cold saline water feeds through the condenser prior to feeding into the liquid cooling-system, wherein the condenser uses the cold saline water to condense the water vapor. 3. The low-temperature desalination system of claim 2 , further comprising an inlet heat exchanger, wherein after the cold saline water feeds through the condenser and becomes warmed saline water, the warmed saline water feeds through the inlet heat exchanger, which uses unevaporated heated saline water obtained from the vacuum evaporator to preheat the warmed saline water prior to feeding the preheated saline water into the liquid-cooling system. 4. The low-temperature desalination system of claim 1 , wherein the control unit enables a user to adjust the tradeoff between the desalination efficiency and the computational performance. 5. The low-temperature desalination system of claim 1 , wherein while optimizing the desalination efficiency and the computational performance, the control unit additionally controls a flow rate through the liquid-cooling system in the computer data center. 6. The low-temperature desalination system of claim 1 , wherein while optimizing the desalination efficiency and the computational performance, the control unit uses a multiple-input, multiple-output (MIMO) control strategy based on a multivariate state estimation technique (MSET) to optimize the tradeoff between the desalination efficiency and the computational performance. 7. The low-temperature desalination system of claim 1 , wherein the desalination efficiency is optimized by minimizing peaks and valleys in an aggregate computational load for the different priority jobs in the computer data center. 8. The low-temperature desalination system of claim 1 , wherein the telemetry data includes one or more of the following measured values for processors in the computer data center: power consumption parameters; temperatures; and processor performance parameters.