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Hugelkultur, is an advanced permaculture technique for creating self-sustaining raised garden beds filled with decomposing wood. The technique involves burying a variety of wood materials, including logs, branches, twigs, and even whole trees, under layers of soil, creating a complex and dynamic environment for plant growth. As the wood decomposes, it acts as "a sponge to hold water," reducing the need for irrigation. This decomposition also generates heat, which can extend the growing season, particularly in cooler climates. The shrinking wood creates air pockets, making the beds "self-tilling" and promoting excellent aeration for plant roots. These "parking spaces for water and nutrients," as described by Paul Wheaton, enhance soil fertility, attract beneficial microorganisms, and release nutrients, reducing or eliminating the need for fertilizers. Hugelkultur beds are remarkably adaptable and can be built in various shapes and sizes, as exemplified by Sepp Holzer's large-scale project in Dayton, Montana, which features nearly a kilometer of hugelkultur beds.
The "freaky-cheap" aspect of WOFATI is fundamental to its appeal and accessibility. Inspired by Mike Oehler's pioneering work in earth-sheltered building, WOFATI prioritizes utilizing readily available natural materials, primarily wood and earth, minimizing reliance on expensive, manufactured products. By embracing the "freaky-cheap" ethos, WOFATI construction drastically reduces building costs, making sustainable living a more attainable reality. The emphasis on "soil on wood" construction eliminates the need for a traditional concrete foundation, further reducing expenses. This approach also facilitates rapid building times, as demonstrated by the construction of WOFATI structures at Wheaton Labs, such as Allerton Abbey. The use of recycled or salvaged materials, whenever possible, further contributes to the affordability of WOFATI buildings. By minimizing material costs and construction time, WOFATI empowers individuals to create sustainable and comfortable dwellings without incurring significant financial burdens.
The willow feeder system is a sustainable and "freaky-cheap" method of managing human waste, developed by permaculture innovator Paul Wheaton as an alternative to traditional septic systems and sewage treatment plants. This innovative system transforms human waste into a nutrient-rich fertilizer, called "willow candy," through a process of mummification. Instead of composting the waste, as in composting toilets, the willow feeder system relies on a dry environment within sealed garbage cans to prevent decomposition and the survival of pathogens. A small amount of sawdust is added to the cans, primarily for aesthetics. After two years of aging, the "willow candy" becomes pathogen-free and can be safely used as fertilizer. This material, rich in carbon and nitrogen, is particularly beneficial for "poop beasts," a term used to describe trees like willow, cottonwood, poplar, and bamboo, which can tolerate and thrive on the high nutrient levels. By turning human waste into a valuable resource for growing these beneficial plants, the willow feeder system embodies the core principles of permaculture, promoting a closed-loop cycle that minimizes waste and environmental impact.
HUSP, an acronym for "Horticulture of the United States of Pocahontas," represents an advanced, nature-centric agricultural system envisioned by Paul Wheaton. It goes beyond contemporary permaculture, envisioning a future where food production systems have undergone centuries of optimization, inspired by traditional Indigenous practices that existed before European colonization. HUSP posits a hypothetical United States of Pocahontas (USP), where agriculture prioritizes harmony with nature, rejecting environmentally harmful practices like plowing and the use of petroleum-based fertilizers and pesticides. This system would not only produce abundant, nutritious food, but also lead to improved human health and a thriving health tourism industry within the USP. Achieving HUSP in the real world necessitates collaborative experimentation and knowledge exchange between permaculture, biodynamic farming, and native plant cultivation practitioners. This would involve a 2,000-acre plot divided into smaller sections, where experts can develop and refine HUSP principles, fostering innovation and leading to a future where food production systems are deeply integrated with natural ecosystems. Crucially, this project requires a supportive environment with minimal government regulation to encourage creativity and accelerate progress toward a truly sustainable agricultural future.
Dry outhouses offer a sustainable alternative to conventional flush toilets, aligning with permaculture principles of resource conservation and waste reduction. A well-designed dry outhouse, strategically situated on an elevated point to encourage water runoff, utilizes a pit for waste collection. To mitigate odors and promote composting, sawdust is a crucial element. A "no pee" policy, though challenging for women due to anatomical differences, helps maintain a dry environment, crucial for minimizing pathogen survival and groundwater contamination. This "dry" approach allows the waste to essentially mummify over time, becoming poop-jerky after two years. This aged material, though technically safe for vegetable gardens, is ideally used to nourish "poop beast" trees like willows, poplars, or cottonwoods, as part of a "willow feeder system." For optimal functionality and user comfort, urine diversion mechanisms are essential, particularly in mixed-gender settings. This separation of urine, a valuable fertilizer, further reduces the volume and toxicity of the solid waste, facilitating easier handling and nutrient cycling. The dry outhouse, therefore, presents a low-cost, eco-friendly sanitation solution that embodies the essence of permaculture's closed-loop systems.