Soil Sampling Methods: Difference between revisions
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[[File:Rhizotron.jpg|thumb| Underground rhizotron]] | [[File:Rhizotron.jpg|thumb| Underground rhizotron]] | ||
Rhizotrons come in various sizes, which allow for study at multiple scales | Rhizotrons come in various sizes, which allow for study at multiple scales. The largest example of a rhizotron is a tunnel built underground with windows placed all around the tunnel, allowing for non-destructive study of the roots and rhizosphere. Smaller rhizotrons can be built with a sturdy, clear material for study of individual plants and smaller systems. The roots grow up to the windows which allows us to see the way the roots grow. We can see the roots along with the [[root hairs]] that grow off the roots. Using this method we can see how thick roots are, how deep they go and how wide spread the roots grow for different plants in different [[soil|soil]] types. Using a rhizotron is very useful in a forest for research as scientists can measure and observe the interactions that occur on and [[rhizosphere]]. From the roots holding down the tree or other plants, to the interactions with the micro organisms living next to the root hairs. Scientists can learn a lot for using a rhizotron in a way that they do not have to dig up all the roots to see how they look and work. | ||
== References == | == References == |
Revision as of 14:58, 5 May 2021
Soil sampling gives is useful for determining the structure and function of the soil community. Study subjects include type of organisms living in the soil, the plant roots structure, leaf litter break down and decomposition. There are different methods of soil sampling, for measurement of different target organisms and variables.
Baermann Funnel
Baermann funnels are useful for measurement of microfauna and microorganism abundance and richness in a soil sample. A funnel with a small mesh or muslin lining on the inside is attached via tube to the bottom of the funnel, which is clamped shut at the bottom. When the soil is placed in the funnel, it is then filled with water. Organisms like nematodes will move down through the soil and water, through the mesh and into the bottom of the tube. After 24 to 48 hours, the clamp is opened, allowing the organisms to drain into a petri dish. Samples can then be identified via microscopy.
Berlese/Tullgren Funnel
Leaf litter samples are typically placed in Berlese-Tullgren funnels to sample for soil micro- and mesofauna.The Berlese-Tullgren apparatus consists of a funnel, a light source, a screen, and a receptacle into which the animals fall. The sample is placed in a funnel that is lined with a screen with the light source above; the extraction process works by desiccating the soil from above via heat lamp, forcing the fauna downward through the funnel into the sampling liquid below. Organisms one may capture via this method include arthropods like, insects, myriapoda, and crustaceans.
Leaf Litter Pack
Leaf litter packs consist of a mesh bag, usually with 1/4 inch openings, with leaves and lettuce. The size in the mesh is varied based on the size of target organisms. The mesh is large enough so target organisms can crawl into the bag, and small enough so they generally can not leave. Leaf packs should be placed on a low spot on the ground in order to maximize capture: this is where soil is most fertile, and where moisture content is highest. You dig a small hole in the ground, place the bag in the hole and cover it up with the soil and surrounding leaves. Then, place a flag sticking out of the ground next to the bag so you can find it later. Let the leaf pack sit for a couple days to allow organisms to get into the bag before you remove it. Next, you dump the leaves out of the bag onto a plate and start looking for organisms like slugs, worms, centipedes, mites, and smaller organisms. You can put them on a petri dish and observe the soil organisms closer under the microscope to allow you to properly identify them.
Rhizotron
Rhizotrons come in various sizes, which allow for study at multiple scales. The largest example of a rhizotron is a tunnel built underground with windows placed all around the tunnel, allowing for non-destructive study of the roots and rhizosphere. Smaller rhizotrons can be built with a sturdy, clear material for study of individual plants and smaller systems. The roots grow up to the windows which allows us to see the way the roots grow. We can see the roots along with the root hairs that grow off the roots. Using this method we can see how thick roots are, how deep they go and how wide spread the roots grow for different plants in different soil types. Using a rhizotron is very useful in a forest for research as scientists can measure and observe the interactions that occur on and rhizosphere. From the roots holding down the tree or other plants, to the interactions with the micro organisms living next to the root hairs. Scientists can learn a lot for using a rhizotron in a way that they do not have to dig up all the roots to see how they look and work.
References
Bug Hunter, bughunter.tamu.edu/collection/collectionequipment/berlese-funnel/.
“What Is a Rhizotron?” Effects of Emerald Ash Borer on Forest Ecosystems - Emerald Ash Borer - Forest Disturbance Processes - Northern Research Station - USDA Forest Service, www.nrs.fs.fed.us/research/facilities/rhizotron/.
“Berlese Funnels - Collecting Methods - Mississippi Entomological Museum Home.” Camponotus(Tanaemyrmex) Castaneus (Latreille) , mississippientomologicalmuseum.org.msstate.edu/collecting.preparation.methods/Berlesefunnel.htm#.WvLuxUxFzIV.
“Proper Soil Sampling Techniques.” Volusia County, www.volusia.org/services/community-services/extension/agriculture/proper-soil-sampling-techniques.stml.
“Leaf Pack Study (Department of Ecosystem Science and Management).” Department of Ecosystem Science and Management (Penn State University), ecosystems.psu.edu/youth/sftrc/lesson-plans/water/6-8/leafpack.
Animal Diversity Web, animaldiversity.org/accounts/Arthropoda/classification/.
Mohamed, Awaz, et al. “An Evaluation of Inexpensive Methods for Root Image Acquisition When Using Rhizotrons.” Plant Methods, BioMed Central, 7 Mar. 2017, plantmethods.biomedcentral.com/articles/10.1186/s13007-017-0160-z.