Fieldwork Ready. Sara E. Vero

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Fieldwork Ready - Sara E. Vero


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2.8 The researchers in this photo are collecting soil, water and ecological information to form a comprehensive characterisation of their case study.

      Source: Jaclyn Fiola.

      Case studies can be representative in nature. In other words, the sites and scenarios examined are selected based on how representative they are of a broader environment and the results and observations derived may be generalized or applied to this wider context. For example, a case study of the changes to fertilizer management on a family farm after removal of milk quotas in Ireland could be used to illustrate changes to the sector as a whole. Representative case studies can be partnered with surveys or controlled studies to demonstrate how their findings translate to reality. Where funding and resources are available, a number of case studies can be collected to provide a more comprehensive representation.

      Conversely, case studies can be used to document and demonstrate outliers, in which an unusual, anomalous, or atypical event or situation occurs. These case studies are vital for identifying knowledge gaps.

Photo depicts an equipment called covariance tower that can be used to monitor atmospheric conditions including temperature, wind speed and direction, carbon dioxide, methane and other gas fluxes.

      Source: Rachael Murphy.

Photo depicts a phenocam at Konza Prairie, Kansas, provides automated recording of plant canopies and is part of a network across the United States and Canada.

      Source: Sara Vero

Photo depicts a livestock-proof fence - essential for preventing damage to the weather station.

      Source: Sara Vero.

      Hydrology is perhaps notable for utilizing long‐term monitoring studies, some spanning over multiple decades. Perhaps this stems from our current and historic reliance on watercourses for abstraction, transport, and fishing and conversely, the potentially catastrophic threat of floods. The River Thames in London, U.K. is an example of long‐term monitoring and provides the longest record of water chemistry in the world. Monthly nitrate concentrations have been recorded for over 140 years, starting in 1868, accompanied by weather records for the same period and discharge since 1884. This remarkable record was investigated and documented by Howden et al. (2010), but the initiation of the monitoring was done by drinking water treatment works supplying the city of London. The engineers who established this likely had no idea that the records they began would provide insight into the environmental consequences of population increases throughout the 20th century, the advent of chemical fertilizers, World War I and II, land‐use changes, the establishment of the European Union and the water and agricultural laws brought in thereafter. While the extensive record allows each of these historical events to be examined, it also informs the design of other monitoring endeavors. For example, by evaluating the rate of hydrochemical change, the authors of that study determined that studies of shorter than 15 years would be vulnerable to error if lacking appropriate historical context. The design of legislation also depends on this evidence to guide expectations of environmental responses, which may not correspond to governance or election cycles. The definition of “long term” research varies between disciplines; however, some general consensus appears to be around 10–15 years. Lindenmayer and Likens (2010) proposed a 10‐yr threshold for ecological monitoring.

      While no strict rule or agreed convention exists, short‐term monitoring may lend itself more to case studies, while increasing length and frequency of monitoring allows application of more statistical analyses.

       Repeated physical sampling of water, soil, or vegetation for analysis at the laboratory. This samples can be obtained directly by a researcher in the field, or by automated samplers.

       Use of sensors at appropriate temporal resolution for measurements such as temperature, river discharge, turbidity, eddy covariance, etc. Sensors often facilitate high‐temporal resolution monitoring up to sub‐hourly frequency.

       In situ measurements (often coupled with electronic sensors and validated against laboratory samples). Monitoring at river outlets may take this approach, in which bankside devices automatically extract samples from the watercourse and analyze them on location for nitrogen and phosphorus.

       Observational monitoring may be used for wildlife studies. This can take the form of GPS tagging of birds, fish, or animals, the use of catch‐and‐release traps, or of field cameras to observe activity and behavior.

      Monitoring can be expensive including the initial outlay for establishment of the experiment, its ongoing maintenance and its high demand for consumables. Large monitoring endeavors often require dedicated staff for maintenance of equipment. However, these challenges can be overcome and increasingly the value of monitoring studies is appreciated, particularly for providing baseline or background data for other research.

      There are a number of groups and consortiums comprising discrete monitoring projects who collaborate across sites or adhere to agreed standards, measurements, and protocols. These programs might focus on one particular field of research or may take an integrative


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