Art of Harvesting
Moving from Conversation to Collective Meaning Making
Sharing the harvests and practices of our collective meaning-making that help to make the results of shared experiences useful and sustainable.
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Created: Jan 29, 2008
Updated: Jul 30, 2009
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mia rose maltz
miarose
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YOU are amazing. Thank you for your work in the world. And your heart in the world. |
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Mia Rose ---- In addition to deepening your knowledge and awareness of fungi on mycoremediation at Sonoma State, you might want to consider studying more of the other types of phytoremediation, specifically to include the following (in my book, "Solving Global Water Crises," pages 529-530): ** Phytoextraction --- Using living plants to extract and remove pollutant compounds from teh soil and water. ** Phytoaccumulation --- When plants uptake and accumulate pollutants in their tissues because they are not able to degrade the compounds rapidly or completely. Some plants can hyperaccumulate metals (e.g., nickel, zinc, mercury, chromium, copper) in teh process of remediating contaminated soils and water. *** Phytopumping ---- This process uses plants as biological pumps to suck up large volumes of contaminated water. By using the evapotranspiration process, plants can "pump" large amounts of water from the soil and reduce migration of the contaminants in groundwater (e.g., the willow tree, Salix spp., may uptake up to 200 liters of water daily and, therefore, may be ideal for phytopumping toxic plumes out of the groundwater). *** Phytostabilization --- This process uses plant roots' exudates (which causes metals to precipitate, thus reducing their bioavailability) and ability to change soil environmental conditions (such as pH and soil-moisture content) to minimize contaminant migration in soils. But this process is different from phytopumping because no disposal of the toxics-laden plant materials is necessary, as the pollutants are stabilized in the soil and, therefore, has minimal interaction with surrounding organisms and microorganisms. *** Phytotransformation/Phytodegradation --- Plant enzymes or enzyme cofactors are used to degrade and eliminate contaminant compounds. For example, researchers have found that polychlorinated biphenyls (PCBs) have been metabolized by sterile plant tissues; phenols have been degraded by peroxidase-containing plants such as horseradish, potato, and white radish; and that poplar trees can transform trichloroethylene in soil and groundwater. ..... *** Phytovolatilization ---- This is the mechanism by which plants convert pollutants in soil or water into a volatile form so as to be removed inexpensively from sites. Researchers have found that plants (possibly in combination with microorganisms) can transform selenium into dimethyl selenide, a less toxic and more volatile form of selenium. *** Rhizofiltration and Rhizodegradation --- This process is based on a symbiotic relationship between bacteria and fungal organisms in certain vascular plants' rhizosphere, an area of microbial hyperactivity. By modifying the geochemical environment in the rhizosphere---with roots infiltrating and aerating the soil to stimulate a zone of amplified microbial activity and density at the root surface for the microbial biodegradation of pollutants---leguminous plants provide ideal settings for plant-microbe interactions that facilitate bioremediation. Researchers have found that the mechanism of rhizofiltration can be used to treat heavy metals, organic chemicals, etc., in soils and waters.
Good luck in pursuing your Master's and in completing your thesis. |
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How wonderful that you're getting your Master's in this interdisplinary degree in biology, chemistry, and environmental studies called "Action for a Viable Future"! You might want to check out my book, chapter 9, on mycology and using a variety of fungi to treat toxics-containing wastewater and sewage. Since you're also studying biology and have experience in permaculture design, you might want to look further into how various species of aquatic macrophytes are used in wastewater and water treatment. This following passage is from "Solving Global Water Crises: Ecological Planning, Design, and Engineering": Aquatic macrophyte species can be used in soil- and substrate-bed systems, such as reed beds and constructed wetlands. A brief introduction to these systems is presented in this section; detailed discussions of these systems are presented in Chapter 6. In wastewater-treatment wetlands (commonly called "treatment wetlands"), aquatic plants and macrophytes are known to have the following important functions (Brix, 1997):1. Stabilize the soil and surface of the treatment beds.
2. Provide conditions for physical filtration of wastewater. 3. Prevent clogging in the media (e.g., sand and gravel) in vertical-flow wetlands 4. Insulate the surface of the treatment system against winter frosts and shield thewetland from climatic variations. 5. Furnish substrate and a large surface area for attached-growth treatment by microorganisms and biofilm.
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awaketrain rules!!!! so does mycoremediation, what is the rites project?
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“If all the beasts were gone, men would die from a great loneliness of spirit, for whatever happens to the beasts also happens to the man. All things are connected. Whatever befalls the Earth befalls the sons of the Earth.”
Chief Seattle (1786-1866)