Environment-controlled cooling mode selection for a modular data center based on detection of contaminants and particulates in outside air

What is claimed is: 1. A cooling system that circulates cooling aft through information technology (IT) modules within a large scale information handling system (IHS), the cooling system comprising: an air handling unit (AHU) to direct cooling air through an IT module; an ambient condition interface in communication with at least one outside contamination sensor to determine a level of a contaminant in outside air; a controller in communication with the ambient condition interface and the AHU and which causes the cooling system to selectively operate in one of four modes from among a normal mode, a mixed mode, a mechanical trimmed mode, and a closed mode, wherein an intake damper is open in each of the normal mode, mixed mode, and trim mode, and is closed in the closed mode and a recirculation damper is open in the closed mode, closed in the open mode, and modulated between open and closed in each of the mixed mode and trim mode, the controller causing the cooling system to: determine a level of a contaminant in the outside air; determine whether the level of the contaminant exceeds a threshold; and in response to determining that the level of the contaminant exceeds the threshold, place the cooling system in the closed mode and trigger the AHU to perform cooling via a mechanical cooling mode that includes closing an intake for outside air into the AHU, recirculating air within an IT module via the AHU, closing an exhaust damper, and turning on a chiller; and in response to the level of contaminants not exceeding the threshold and other detected ambient conditions being favorable to using outside air to cool the IHS, configure the AHU to perform cooling using the outside air in one of the normal mode, mixed mode, and trim mode based on ambient/outside air conditions of temperature and humidity. 2. The cooling system of claim 1 , wherein: the AHU further comprises a contaminant filter to filter air in the AHU to remove at least a portion of the contaminant; and the controller further determines the threshold based at least in part upon a determined effectiveness of the filtering by the contaminant filter. 3. The cooling system of claim 2 , further comprising an air contamination sensor to measure an internal level of contamination within the AHU that is not removed by the contaminant filter. 4. The cooling system of claim 1 , wherein the contaminant causes a negative effect on one or more of the IT components within the IHS, the negative effect being one of a group comprising corrosion. 5. The cooling system of claim 1 , wherein: the contaminant is one or more of a gas, a liquid and a solid contaminant; and the controller further determines the level of the contaminant by performing a corresponding one or more of: determining a first level of a solid contaminant; determining a second level of a liquid contaminant; and determining a third level of a gaseous contaminant. 6. The cooling system of claim 5 , wherein: the controller further determines whether the level of the contaminant exceeds the threshold by performing at least one of: determining whether the first level of the solid contaminant exceeds a first threshold; determining whether the second level of the liquid contaminant exceeds a second threshold; and determining whether the third level of the gaseous contaminant exceeds a third threshold. 7. The cooling system of claim 1 , wherein: the ambient condition interface is further in communication with an outside temperature sensor and an outside humidity sensor that respectively detect an ambient condition outside of the IHS comprising at least one of an outside temperature value and an outside humidity value; the controller is in communication with the ambient condition interface and the AHU to cause the cooling system to: detect the outside ambient condition that includes both the outside temperature value and the outside humidity value; determine whether the outside ambient condition is within a first range of condition values that include a first range of temperature values and a first range of humidity values that requires normal cooling mode; in response to determining that the outside ambient condition falls within the first range of condition values and that level of the contaminant does not exceed the threshold, configure the AHU to circulate cooling air through the IHS by: intaking outside air; and circulating the outside air through the IHS operating space; determine whether the outside ambient condition is within a second range of condition values that include a second range of temperature values and a second range of humidity values that requires hybrid cooling mode; in response to determining that the outside ambient condition falls within the second range of condition values and that level of the contaminant does not exceed the threshold, configure the AHU to circulate cooling air through the IHS by: intaking outside air; performing a hybrid cooling mode mixing of the outside air with recirculated air to moderate the outside air and bring a condition value of the moderated outside air into the first range of condition values; and circulating the moderated outside air through the IHS operating space; and when the ambient condition includes only one of the outside temperature and the outside humidity being outside of a respective second range of values, the hybrid cooling mode accounts for only the one condition that falls outside of the respective second range of values. 8. The cooling system of claim 7 , further comprising: a humidifier that controllably increases humidity of air within the AHU; a de-humidifier that controllably reduces humidity from within the air in the AHU; wherein the controller further triggers the AHU to implement the hybrid cooling mode to moderate the outside air by: triggering the AHU to change the outside temperature value of the outside air to a moderated temperature value that is in the first temperature range; determining a moderated humidity value of the moderated outside air that results from changing the outside air to the moderated temperature value; in response to the moderated humidity value being greater than the normal operating space, activating the de-humidifier to dehumidify the moderated outside air; and in response to the moderated humidity value being less than the first range of humidity values activating the humidifier to humidify the moderated outside air. 9. The cooling system of claim 1 , wherein the AHU further comprises: a direct expansion cooling unit to cool air in the AHU; a hot air return plenum in fluid communication with a hot aisle of the IT module and having an exhaust portal; an air intake chamber in fluid communication with the hot air return plenum and having an air intake and air outlet; an outlet chamber in fluid communication with the air intake chamber via the air outlet and with a cold aisle of the IT module; a recirculation damper between the hot air return plenum and the air intake chamber; an outside air intake damper between the outside air intake and the air intake chamber; an exhaust damper between the hot air return plenum and the exhaust portal; and an air mover positioned to move air from the outlet chamber to the cold aisle of the IT module; and wherein the controller further triggers the AHU to close the intake for outside air into the AHU and recirculating air within the IT module via the AHU by opening the recirculation damper, closing the exhaust damper, closing the outside air intake damper, activating the air mover, and activating the direct expansion cooling unit. 10. The cooling system of claim 9 , wherein the controller is further to: det