Data Analysis

Calculating the amount of water in the soil is critical to many people. Farmers can use soil moisture data to aid in scheduling of crop watering. Firemen use soil moisture data to pinpoint possible areas of danger for wildfires. Soil moisture data can also be included in computer models to improve weather forecasts. Oklahoma has put itself in the forefront of public use and research of soil moisture with the Oklahoma Mesonet’s Soil Moisture Network.

In 1996, soil moisture sensors were installed at 60 Mesonet sites at depths of 5, 25, 60 and 75 cm. Based upon the initial success in using data from this original deployment, soil moisture sensors were installed at 43 additional Mesonet sites during 1998 and 1999 (Figure 1). A key aspect of the network of soil moisture sensors is that estimates of both soil-water potential and water content are collected every 30 minutes.

The sensors measure soil moisture by heating and then taking the temperature of a wire, pausing for a few seconds, and then taking the temperature a second time. Since heat dissipates more slowly in water (high heat capacity), wet soils will have a smaller change in temperature measured by the sensor than dry soils. This temperature difference allows hydrological variables such as soil water content, soil matric potential, and Fractional Water Index (FWI) to be calculated.

Soil water content is the physical amount of water per volume of soil. Different soil types (i.e. sand, clay, etc.) have different sizes of particles, which results in varying amounts of space available for water to fill. Soil matric potential is the force, like pressure, needed to move water vertically. When there is less water in the soil, a larger force is required to move the water. Soil matric potential is useful in agricultural situations, when it is important to know how effective certain plants are at removing water from the soil. However, soil matric potential is an exponential function, which makes it more difficult to implement in real time. Thus, the Oklahoma Mesonet put soil matric potential values into four categories. This allowed statewide plots to be easier to understand.

Since soil water content depends heavily upon soil texture, and soil matric potential is exponentially related to soil wetness, FWI was developed for an easy to use and understandable index. FWI tells us how far between the dry and wet extremes of the sensor a particular sensor reading resides. This unitless value ranges from very dry soil having a value of zero, to saturated soils having a value of one.

Figure 2 shows a typical image of soil moisture at a depth of 5 cm – about the length of your thumb – during the early part of the summer. The darker brown areas show drier soils, while the green areas indicate more moist soils. Maps like these, as well as maps of categorized matric potential, for all four soil depths are updated daily on the Oklahoma Mesonet Interactive Products website for public viewing (select Soil Moisture Maps). Custom maps showing a particular day in the past can also be generated on the website by selecting Custom Maps under Soil Moisture Maps.

In addition to statewide maps of soil moisture, the website allows the user to view a particular site in more detail. Figure 3 shows a 30 day time series of soil moisture at the El Reno Mesonet site. The top plot shows FWI and the bottom plot shows soil water content. Each colored line represents a particular depth within the soil. Here the public can see how the soil moistures values have dropped over the past 30 days. Similar to the statewide plots, custom maps of different time periods can be generated on the website by selecting Custom Graphs under Graphs (Soil Moisture).

This vast network of soil moisture sensors has led to many research opportunities, many of which would not have been possible without the Oklahoma Mesonet. The Oklahoma Climatological Survey has produced a detailed climatology of Oklahoma soil moisture. This climatology allows state water and agriculture officials to better understand what typical values of soil moisture should be, and when they are reaching extreme values for a particular time period. Other studies have focused on the droughts of 1998 and 2000, which seriously impacted the state’s economy. A better understanding of how droughts occur and discovering signals to warn of impending droughts will aid the advanced preparations for those who rely on soil moisture.

Further drought studies indicate fall and winter rainfall may help alleviate near-surface soil moisture problems during severe droughts, but deeper depths may continue to be impacted by the dry conditions. Figure 4 shows the FWI values for the Mesonet station in Hollis during 1998. The drought can clearly be seen during the middle part of the year (summer), but during the fall and winter, when rain has fallen, only the top two depths (red and yellow lines) recover from the drought conditions. This research demonstrated how a drought can impact a location longer than originally thought.

There is still much to learn about soil moisture, and the Oklahoma Mesonet will continue to be an integral part of this process. More products will be made available in order to provide even more detailed soil moisture information to the public. Additional data sets will be produced for researchers to analyze. The discoveries which result will greatly benefit not only Oklahomans, but communities across the globe as well. Just as other portions of the Oklahoma Mesonet have pioneered how weather data is used, the soil moisture network will surely follow in its footsteps.