Laboratory analysis of a water quality sample links a lot of data to a singular point in time and space.
However, the objectives for monitoring may span scales from point (e.g. at an outfall) to watershed (e.g. to characterize waters; identify trends; assess threats; inform pollution control; guide environmental emergency response; and support the development, implementation, and assessment of policies and regulations).
Reconciling data- and metadata-dense analytical results with watershed-scale outcomes is a work-in-progress for many monitoring agencies.
Strategic design of water quality monitoring program networks can facilitate inference about the vast un-sampled space from the sparsely sampled points. Sites can be chosen as “index” sites where the condition of water at that site is indicative of the condition of interest of one, or more, management objectives.
Direct sharing of data is one mechanism that works well for some end-uses.
The client “merely” needs to choose exactly which samples, of exactly which parameters (there can be dozens), at exactly which locations, created by exactly which methods (for inter-comparability), and download the data for further analysis. A sophisticated end-user who has specific questions, about specific parameters, at specific places and times can find the answers they need in discoverable, searchable, and accessible online data.
However, for the end-user who merely wants to find water that is swimmable, fishable, or drinkable, the prospect of reviewing every parameter at every location for all recent samples and putting that data in the context of relevant guidelines and thresholds is far too onerous a task. For these users, water quality indices are a very good solution.
A water quality index (WQI) is equivalent to the grade on a school report card.
On some scale (often 0 to 100), all of the relevant data within an area of interest can be reduced into a single, easy to interpret number. There are a plethora of different water quality indices to choose from, each one tuned to locally relevant issues, priorities, regulations, and guidelines. Some are tuned to monitoring the natural environment (i.e. base state and influence of human activity), some to human health (i.e. consumption and recreation), and others to competitiveness (i.e. water fitness for purpose for industrial and agricultural uses).
Data sharing and WQI are like bookends to the problem of connecting water quality data to the many and varied societal objectives that demand timely, relevant, and reliable information about the condition of the water resource.
At one end you have onerous granularity of information and at the other end you have a smearing of valuable precision in time, space, and parameter-specific dynamics.
Somewhere between these extremes must be a solution that is “just right.”
In recent decades, water resource managers around the world have embraced real-time reporting of continuous records of water level and discharge. The timeliness of these data has enabled many changes in how water resources are managed. Highly responsive and adaptive decisions based on what is happening as opposed to what has happened, or what could happen, is widely attributed with many improved outcomes for water supply management.
We know that flow and water quality are highly correlated as a result of integration of sources of varying water constituents (i.e. dilution and concentration). The integration of all contributing water into flow at a specified location inherently connects point-scale observations to watershed-scale events.
Continuous monitoring and real-time communication from multi-probe water quality sensors is starting to bridge the considerable gap between observation-scale data and watershed-scale-outcomes.
For example, specific conductance is a parameter that varies in accordance to the concentration of dissolved ions such as calcium, chloride, fluoride, magnesium, potassium, sodium, and sulphate. Synchronization of discrete laboratory analyses with specific conductivity and discharge can reveal which ions are influential at which flow regimes, providing real insight into not only what is happening, but why. This improved understanding of spatial and temporal dynamics of water quality parameters improves the inference that can be made across all relevant time and space scales.
However, multi-probe sensors are not enough.
Better integration of laboratory data management with continuous monitoring data management is needed to reconcile the problem of how sparse and dense information can better inform watershed-scale objectives.
You understand the value of water monitoring but need additional, sustainable funding. Know that you are not alone. The gap between water monitoring capability and the rapidly evolving need for evidence-based policies, planning, and engineering design is growing. Learn how to form persuasive arguments that are sensitive to local politics and priorities to address this global deficit in funding. The benefits of hydrological information DO vastly outweigh investments in water monitoring.