Climate-friendly gardening

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Climate-friendly_gardening 

Climate-friendly gardening is gardening in ways which reduce emissions of greenhouse gases from gardens and encourage the absorption of carbon dioxide by soils and plants in order to aid the reduction of global warming. To be a climate-friendly gardener means considering both what happens in a garden and the materials brought into it and the impact they have on land use and climate. It can also include garden features or activities in the garden that help to reduce greenhouse gas emissions elsewhere.

Orchard garden showing orchard trees, herbaceous perennials and ground-cover plants, at Hergest Croft Gardens, Herefordshire, Britain.

Land use and greenhouse gases

Most of the excess greenhouse gases causing climate change have come from burning fossil fuel. But a special report from the Intergovernmental Panel on Climate Change (IPCC) estimated that in the last 150 years fossil fuels and cement production were responsible for only about two-thirds of climate change: the other third has been caused by human land use.

The three main greenhouse gases produced by unsustainable land use are carbon dioxide, methane, and nitrous oxide. Black carbon or soot can also be caused by unsustainable land use, and, although not a gas, can behave like greenhouse gases and contribute to climate change.

Carbon dioxide

Carbon dioxide, CO
2, is a natural part of the carbon cycle, but human land uses often add more, especially from habitat destruction and the cultivation of soil. When woodlands, wetlands, and other natural habitats are turned into pasture, arable fields, buildings and roads, the carbon held in the soil and vegetation becomes extra carbon dioxide and methane to trap more heat in the atmosphere.

Gardeners may cause extra carbon dioxide to be added to the atmosphere in several ways:

• Using peat or potting compost containing peat;
• Buying garden furniture or other wooden products made from woodland which has been destroyed rather than taken as a renewable crop from sustainably managed woodland;
• Digging soil and leaving it bare so that the carbon in soil organic matter is oxidised;
• Using power tools which burn fossil fuel or electricity generated by burning fossil fuel;
• Using patio heaters;
• Heating greenhouses by burning fossil fuel or electricity generated by burning fossil fuel;
• Burning garden prunings and weeds on a bonfire;
• Buying tools, pesticides, synthetic nitrogen fertilizers (over 2 kilograms of carbon dioxide equivalent is produced in the manufacture of each kilogram of ammonium nitrate), and other materials which have been manufactured using fossil fuel;
• Heating and treating swimming pools by burning fossil fuel or electricity generated by burning fossil fuel;
• Watering their gardens with tapwater, which has been treated and pumped by burning fossil fuel, with a greenhouse gas impact of about 1 kg CO₂e/m³ water.

Gardeners will also be responsible for extra carbon dioxide when they buy garden products which have been transported by vehicles powered by fossil fuel.

Methane

Methane, CH₄, is a natural part of the carbon cycle, but human land uses often add more, especially from anaerobic soil, artificial wetlands such as rice fields, and from the guts of farm animals, especially ruminants such as cattle and sheep.

Gardeners may cause extra methane to be added to the atmosphere in several ways:

• Compacting soil so that it becomes anaerobic, for example by treading on soil when it is wet;
• Allowing compost heaps to become compacted and anaerobic;
• Creating homemade liquid feed by putting the leaves of plants such as comfrey under water, with the unintended consequence that the plants may release methane as they decay;
• Killing pernicious weeds by covering them with water, with the unintended consequence that the plants may release methane as they decay;
• Allowing ponds to become anaerobic, for example by adding unsuitable fish species which stir up sediment that then blocks light from and kills submerged oxygenating plants.

Nitrous oxide

Nitrous oxide, N₂O, is a natural part of the nitrogen cycle, but human land uses often add more.

Gardeners may cause extra nitrous oxide to be added to the atmosphere by:

• Using synthetic nitrogen fertilizer, for example "weed and feed" on lawns, especially if it is applied when plants are not actively growing, the soil is compacted, or when other factors are limiting so that the plants cannot make use of the nitrogen;
• Compacting the soil (for example by working in the garden when the soil is wet) which will increase the conversion of nitrates to nitrous oxide by soil bacteria;
• Burning garden waste on bonfires.

Black carbon

Black carbon is not a gas, but it acts like a greenhouse gas because it can be suspended in the atmosphere and absorb heat.

Gardeners may cause extra black carbon to be added to the atmosphere by burning garden prunings and weeds on bonfires, especially if the waste is wet and becomes black carbon in the form of soot. Gardeners will also be responsible for extra black carbon produced when they buy garden products which have been transported by vehicles powered by fossil fuel especially the diesel used in most lorries.

Gardening to reduce greenhouse gas emissions and absorb carbon dioxide

There are many ways in which climate-friendly gardeners may reduce their contribution to climate change and help their gardens absorb carbon dioxide from the atmosphere.

Climate-friendly gardeners can find good ideas in many other sustainable approaches:

• Agroforestry;
• Forest gardening;
• Orchards;
• Organic gardening;
• Permaculture;
• Rain garden;
• Vegan organic gardening;
• Water-wise gardening;
• Wildlife garden.

Protecting and enhancing carbon stores

Protecting carbon stores in land beyond gardens

Woodland and wetland in the New Forest, Hampshire

 

Woodland and trees in Herefordshire

 

Kitchen garden at Charles Darwin's home, Down House, Kent, showing greenhouse, waterbutt, box hedging and vegetable beds.

 

Alliums, lavender, box and other water-thrifty plants in the dry garden at Cambridge Botanic Garden

Climate-friendly gardening includes actions which protect carbon stores beyond gardens. The biggest carbon stores in land are in soil; the two habitat types with the biggest carbon stores per hectare are woods and wetlands; and woods absorb more carbon dioxide per hectare per year than most other habitats. Climate-friendly gardeners therefore aim to ensure that nothing they do will harm these habitats.

According to Morison and Morecroft (eds.)'s Plant Growth and Climate Change, the net primary productivity (the net amount of carbon absorbed each year) of various habitats is:

• Tropical forests: 12.5 tonnes of carbon per hectare per year;
• Temperate forests: 7.7 tonnes of carbon per hectare per year;
• Temperate grasslands: 3.7 tonnes of carbon per hectare per year;
• Croplands: 3.1 tonnes of carbon per hectare per year.

The Intergovernmental Panel on Climate Change's Special Report Land use, land-use change, and forestry lists the carbon contained in different global habitats as:

• Wetlands: 643 tonnes carbon per hectare in soil + 43 tonnes carbon per hectare in vegetation = total 686 tonnes carbon per hectare;
• Tropical forests: 123 tonnes carbon per hectare in soil + 120 tonnes carbon per hectare in vegetation = total 243 tonnes carbon per hectare;
• Temperate forests: 96 tonnes carbon per hectare in soil + 57 tonnes carbon per hectare in vegetation = total 153 tonnes carbon per hectare;
• Temperate grasslands: 164 tonnes carbon per hectare in soil + 7 tonnes carbon per hectare in vegetation = total 171 tonnes carbon per hectare;
• Croplands: 80 tonnes carbon per hectare in soil + 2 tonnes carbon per hectare in vegetation = total 82 tonnes carbon per hectare.

The figures quoted above are global averages. More recent research in 2009 has found that the habitat with the world's highest known total carbon density - 1,867 tonnes of carbon per hectare - is temperate moist forest of Eucalyptus regnans in the Central Highlands of south-east Australia; and, in general, that temperate forests contain more carbon than either boreal forests or tropical forests.

Carbon stores in Britain

According to Milne and Brown's 1997 paper "Carbon in the vegetation and soils of Great Britain", Britain's vegetation and soil are estimated to contain 9952 million tonnes of carbon, of which almost all is in the soil, and most in Scottish peatland soil:

• Soils in Scotland: 6948 million tonnes carbon;
• Soils in England and Wales: 2890 million tonnes carbon;
• Vegetation in British woods and plantations (which cover only 11% of Britain's land area): 91 million tonnes carbon;
• Other vegetation: 23 million tonnes carbon.

A 2005 report suggested that British woodland soil may contain as much as 250 tonnes of carbon per hectare.

Many studies of soil carbon only study the carbon in the top 30 centimetres, but soil is often much deeper than that, especially below woodland. One 2009 study of the United Kingdom's carbon stores by Keith Dyson and others gives figures for soil carbon down to 100 cm below the habitats, including "Forestland", "Cropland" and "Grassland", covered by the Kyoto Protocol reporting requirements.

• Forestland soils: average figures in tonnes carbon per hectare are 160 (England), 428 (Scotland), 203 (Wales), and 366 (Northern Ireland).
• Grassland soils: average figures in tonnes carbon per hectare are 148 (England), 386 (Scotland), 171 (Wales), and 304 (Northern Ireland).
• Cropland soils: average figures in tonnes carbon per hectare are 110 (England), 159 (Scotland), 108 (Wales), and 222 (Northern Ireland).

Protecting carbon stores in wetland

Permeable paving of wood chip with birch-log edging at the Royal Horticultural Society garden at Wisley

 

A ground-cover and rain-garden plant - Symphytum grandiflorum, creeping comfrey (with Cotinus coggygria)

Climate-friendly gardeners choose peat-free composts because some of the planet's biggest carbon stores are in soil, and especially in the peatland soil of wetlands.

The Intergovernmental Panel on Climate Change's Special Report Land Use, Land-Use Change and Forestry gives a figure of 2011 gigatonnes of carbon for global carbon stocks in the top 1 metre of soils, much more than the carbon stores in the vegetation or the atmosphere.

Climate-friendly gardeners also avoid using tapwater not only because of the greenhouse gases emitted when fossil fuels are burnt to treat and pump water, but because if water is taken from wetlands then carbon stores are more likely to be oxidised to carbon dioxide.

A climate-friendly garden therefore does not contain large irrigated lawns, but instead includes water-butts to collect rainwater; water-thrifty plants which survive on rainwater and do not need watering after they are established; trees, shrubs and hedges to shelter gardens from the drying effects of sun and wind; and groundcover plants and organic mulch to protect the soil and keep it moist.

Climate-friendly gardeners will ensure that any paved surfaces in their gardens (which are kept to a minimum to increase carbon stores) are permeable, and may also make rain gardens, sunken areas into which rainwater from buildings and paving is directed, so that the rain can then be fed back into groundwater rather than going into storm drains. The plants in rain gardens must be able to grow in both dry and wet soils.

Protecting carbon stores in woodland

Wetlands may store the most carbon in their soils, but woods store more carbon in their living biomass than any other type of vegetation, and their soils store the most carbon after wetlands. Climate-friendly gardeners therefore ensure that any wooden products they buy, such as garden furniture, have been made of wood from sustainably managed woodland.

Protecting and increasing carbon stores in gardens

Juglans elaeopyren, an American walnut, at Cambridge Botanic Garden

After rocks containing carbonate compounds, soil is the biggest store of carbon on land. Carbon is found in soil organic matter, including living organisms (plant roots, fungi, animals, protists, bacteria), dead organisms, and humus. One study of the environmental benefits of gardens estimates that 86% of carbon stores in gardens is in the soil.

Wild strawberries in flower below a British hedge.

The first priorities for climate-friendly gardeners are, therefore, to:

• Protect the soil's existing carbon stores;
• Increase the soil's carbon stores.

To protect the soil, climate-friendly gardens:

• Are based on plants rather than buildings and paving;
• Have soil that is kept at a relatively stable temperature by shelter from trees, shrubs and/or hedges;
• Have soil that is always kept covered and therefore moist and at a relatively stable temperature by groundcover plants, fast-growing green manures (which can be used as an intercrop in kitchen gardens of annual vegetables) and/or organic mulches.

Mulch of woodchips protecting soil at the Royal Horticultural Society garden at Wisley in Surrey.

Climate-friendly gardeners avoid things which may harm soil. They do not tread on the soil when it is wet, because it is then most vulnerable to compaction. They dig as little is possible, and only when the soil is moist rather than wet, because cultivation increases the oxidation of soil organic matter and produces carbon dioxide.

To increase soil carbon stores, climate-friendly gardeners ensure that their gardens create optimal conditions for vigorous healthy growth of plants, and other garden organisms above and below ground, and reduce the impact of any limiting factors.

In general, the more biomass that the plants can create each year, the more carbon will be added to the soil. However, only some biomass each year becomes long-term soil carbon or humus. In Soil Carbon and Organic Farming, a 2009 report for the Soil Association, Gundula Azeez discusses several factors which increase how much biomass is turned into humus. These include good soil structure, soil organisms such as fine root hairs, microorganisms, mycorrhizas and earthworms which increase soil aggregation, residues from plants (such as trees and shrubs) which have a high content of resistant chemicals such as lignin, and plant residues with a carbon to nitrogen ratio lower than about 32:1.

Nitrogen-fixing nodules on Wisteria roots (hazelnut for scale)

Climate-friendly gardens therefore include:

• Hedges for shelter from wind;
• A light canopy of late-leafing deciduous trees to let in enough sunlight for growth but not so much that the garden becomes too hot and dry (this is one of the principles behind many agroforestry systems, such as Paulownia's use in China partly because it is late-leafing and its canopy is sparse so that crops below it get shelter but also enough light);
• Groundcover plants and organic mulches (such as woodchips over compost made from kitchen and garden "waste") to keep soil moist and at relatively stable temperatures;
• Nitrogen-fixing plants, because soil nitrogen may be a limiting factor (but climate-friendly gardeners avoid synthetic nitrogen fertilizers, because these may cause mycorrhizal associations to break down);
• Many layers of plants, including woody plants such as trees and shrubs, other perennials, groundcover plants, deep-rooted plants, all chosen according to 'right plant, right place', so that they are suited to their growing conditions and will grow well;
• A wide diversity of disease-resistant, vigorous plants for resilience and to make the most of all available ecological niches;
• Plants to feed and shelter wildlife, to increase total biomass, and to ensure biological control of pests and diseases.
• Compost made from garden and kitchen "waste".

Lawns, like other grasslands, can build up good levels of soil carbon, but they will grow more vigorously and store more carbon if besides grasses they also contain nitrogen-fixing plants such as clover, and if they are cut using a mulching mower which returns finely-chopped mowings to the lawn. More carbon, however, may be stored by other perennial plants such as trees and shrubs. They also do not need to be maintained using power tools.

Climate-friendly gardeners will also aim to increase biodiversity not only for the sake of the wildlife itself, but so that the garden ecosystem is resilient and more likely to store as much carbon as possible as long as possible. They will therefore avoid pesticides, and increase the diversity of the habitats within their gardens.

Reducing greenhouse gas emissions

Climate-friendly gardeners can directly reduce the greenhouse gas emissions from their own gardens, but can also use their gardens to indirectly reduce greenhouse gas emissions elsewhere.

Using gardens to reduce greenhouse gas emissions

Climate-friendly gardeners can use their gardens in ways which reduce greenhouse gases elsewhere, for example by using the sun and wind to dry washing on washing lines in the garden instead of using electricity generated by fossil fuel to dry washing in tumble dryers.

From farmland

Walnut, Juglans regia, with ripening walnuts

Food is a major contributor to climate change. In the United Kingdom, according to Tara Garnett of the Food Climate Research Network, food contributes 19% of the country's greenhouse gas emissions.

Soil is the biggest store of carbon on land. It is therefore important to protect the soil organic matter in farmland. Farm animals, however, especially free-range pigs, may cause erosion, and cultivation of the soil increases the oxidation of soil organic matter into carbon dioxide. Other sources of greenhouse gases from farmland include: compaction caused by farm machinery or overgrazing by farm animals can make soil anaerobic and produce methane; farm animals produce methane; and nitrogen fertilizers can be converted to nitrous oxide.

Most farmland consists of fields growing annual arable crops which are eaten directly by people or fed to farm animals, and grassland used as pasture, hay or silage to feed farm animals. Some perennial food plants are also grown, such as fruits and nuts in orchards, and watercress grown in water.

Although all cultivation of the soil in arable fields produces carbon dioxide, some arable crops cause more damage to soil than others. Root crops such as potatoes and sugar-beet, and crops which are harvested not just once a year but over a long period such as green vegetables and salads, are considered "high risk" in catchment-sensitive farming.

Climate-friendly gardeners therefore grow at least some of their food, and may choose food crops which therefore help to keep carbon in farmland soils if they grow such high-risk crops in small vegetable plots in their gardens, where it is easier to protect the soil than in large fields under commercial pressures. Climate-friendly gardeners may grow and eat plants such as sweet cicely which sweeten food, and so reduce the land area needed for sugar-beet. They may also choose to grow perennial food plants to not only reduce their indirect greenhouse gas emissions from farmland, but also to increase carbon stores in their own gardens.

Grassland contains more carbon per hectare than arable fields, but farm animals, especially ruminants such as cattle or sheep, produce large amounts of methane, directly and from manure heaps and slurry. Slurry and manure may also produce nitrous oxide. Gardeners who want to reduce their greenhouse gas emissions can help themselves to eat less meat and dairy produce by growing nut trees which are a good source of tasty, protein-rich food, including walnuts which are an excellent source of the omega-3 fatty acid alpha-linolenic acid.

Researchers and farmers are investigating and improving ways of farming which are more sustainable, such as agroforestry, forest farming, wildlife-friendly farming, soil management, catchment-sensitive farming (or water-friendly farming). For example, the organisation Farming Futures assists farmers in the United Kingdom to reduce their farms' greenhouse gas emissions.

Farmers are aware that consumers are increasingly asking for "green credentials". Gardeners who understand climate-friendly practices can advocate their use by farmers.

From industry

Nitrogen-fixing and edible - Elaeagnus umbellatus at the Agroforestry Research Trust forest garden in Devon

Climate-friendly gardeners aim to reduce their consumption in general. In particular, they try to avoid or reduce their consumption of tapwater because of the greenhouse gases emitted when fossil fuels are burnt to supply the energy needed to treat and pump it to them. Instead, gardeners can garden using only rainwater.

Greenhouse gases are produced in the manufacture of many materials and products used by gardeners. For example, it takes a lot of energy to produce synthetic fertilizers, especially nitrogen fertilizers. Ammonium nitrate, for example, has an embodied energy of 67000 kilojoules/kilogramme, so climate-friendly gardeners will choose alternative ways of ensuring the soil in their gardens has optimal levels of nitrogen by alternative means such as nitrogen-fixing plants.

Climate-friendly gardeners will also aim to follow "cradle-to-cradle design" and "circular economy" principles: when they choose to buy or make something, it should be possible to take it apart again and recycle or compost every part, so that there is no waste, only raw materials to be made into something else. This will reduce the greenhouse gases otherwise produced when extracting raw materials.

From transport

Gardeners can reduce not only their food miles by growing some of their own food, but also their "gardening miles" by reducing the amount of plants and other materials they import, obtaining them as locally as possible and with as little packaging as possible. This might include ordering plants by mail order from a specialist nursery if the plants are sent out bare-root, reducing transport demand and the use of peat-based composts; or growing plants from seed, which will also increase genetic diversity and therefore resilience; or growing plants vegetatively from cuttings or offsets from other local gardeners; or buying reclaimed materials from salvage firms.

From houses

Climbers as insulation - Boston ivy, Parthenocissus tricuspidata, Boston ivy, in autumn

Climate-friendly gardeners can use their gardens in ways which reduce greenhouse gas emissions from homes by:

• Using sunlight and wind to dry washing on washing lines instead of fossil fuel-generated electricity to run tumble dryers;
• Planting deciduous climbers on houses and planting deciduous trees at suitable distances from the house to provide shade during the summer, reducing the consumption of electricity for air conditioning, but also such that at cooler times of year, sunlight can reach and warm a house, reducing heating costs and consumption;
• Planting hedges, trees, shrubs and climbers to shelter houses from wind, reducing heating costs and consumption during the winter (as long as any planting does not create a wind-tunnel effect).

Climate-friendly gardeners may also choose to reduce their own personal greenhouse gas emissions by growing and eating carminative plants such as fennel and garlic which reduce intestinal gases such as methane.

Reducing greenhouse gas emissions from gardens

Slow-growing yew, Taxus baccata, as hedge at Charles Darwin's home, Down House, Kent

 

Nitrogen-fixing red and white clover (Trifolium) as lawn plants

 

Leaf cage, compost heap and wormery at the Royal Horticultural Society garden at Wisley

There are some patent sources of greenhouse gas emissions in gardens and some more latent.

Power tools which are powered by diesel or petrol, or electricity generated by burning other fossil fuels, emit carbon dioxide. Climate-friendly gardeners may therefore choose to use hand tools rather than power tools, or power tools powered by renewable electricity, or design their gardens to reduce or remove a need to use power tools. For example, they may choose dense, slow-growing species for hedges so that the hedges only need to be cut once a year.

Lawns need[?] to be cut by lawn mowers and, in drier parts of the world, are often irrigated by tapwater. Climate-friendly gardeners will therefore do what they can to reduce this consumption by:

• Replacing part of or all lawns with other perennial planting such as trees and shrubs with less ecologically demanding maintenance requirements;
• Cut some or all lawns only once or twice a year, i.e. convert them into meadows;
• Make lawn shapes simple so that they may be cut quickly;
• Increase the cutting height of mower blades;
• Use a mulching mower to return organic matter to the soil;
• Sow clover to increase vigour (without the need for synthetic fertilisers) and resilience in dry periods;
• Cut lawns with electric mowers using electricity from renewable energy;
• Cut lawns with hand tools such as push mowers or scythes.

Greenhouses can be used to grow crops which might otherwise be imported from warmer climates, but if they are heated by fossil fuel then they may cause more greenhouse gas emissions than they save. Climate-friendly gardeners will therefore use their greenhouses carefully by:

• Choosing only annual plants which will only be in the greenhouse during warmer months, or perennial plants which do not need any extra heat during winter;
• Using water tanks as heat stores and compost heaps as heat sources inside greenhouses so that they stay frost-free in winter.

Climate-friendly gardeners will not put woody prunings on bonfires, which will emit carbon dioxide and black carbon, but instead burn them indoors in a wood-burning stove and therefore cut emissions from fossil fuel, or cut them up to use as mulch and increase soil carbon stores, or add the smaller prunings to compost heaps to keep them aerated, reducing methane emissions. To reduce the risk of fire, they will also choose fire-resistant plants from habitats which are not prone to wildfires and which do not catch fire easily, rather than fire-adapted plants from fire-prone habitats which are flammable and adapted to encourage fires and then gain a competitive advantage over less resistant species.

Climate-friendly gardeners may use deep-rooted plants such as comfrey to bring nutrients closer to the surface topsoil, but will do so without making the leaves into a liquid feed, because the rotting leaves in the anaerobic conditions under water may emit methane.

Nitrogen fertilizers may be oxidised to nitrous oxide, especially if fertilizer is applied in excess, or when plants are not actively growing. Climate-friendly gardeners may choose instead to use nitrogen-fixing plants which will add nitrogen to the soil without increasing nitrous oxide emissions.

Permaculture

From Wikipedia, the free encyclopedia

https://en.wikipedia.org/wiki/Permaculture 

 

Agriculture

Permaculture is an approach to land management and philosophy that adopts arrangements observed in flourishing natural ecosystems. It includes a set of design principles derived using whole systems thinking. It uses these principles in fields such as regenerative agriculture, rewilding, and community resilience. Permaculture was originally a portmanteau of "permanent agriculture", but was later adjusted to "permanent culture", to incorporate necessary social aspects as inspired by Masanobu Fukuoka's natural farming. The term was coined by Bill Mollison and David Holmgren in 1978, who formulated the concept in opposition to Western industrialized methods and in congruence with Indigenous or traditional knowledge.

Permaculture has many branches including ecological design, ecological engineering, regenerative design, environmental design, and construction. It also includes integrated water resources management that develops sustainable architecture, and regenerative and self-maintained habitat and agricultural systems modeled from natural ecosystems. Permaculture has been implemented and gained widespread visibility throughout the world as an agricultural and architectural design system and as a guiding life principle or philosophy. Much of its success has been attributed to the role of Indigenous knowledge and traditions, which the practice itself is rooted in. In turn, the rise of permaculture has revalidated Indigenous knowledge in circles where it was previously devalued.

History

In 1929, Joseph Russell Smith added an antecedent term as the subtitle for Tree Crops: A Permanent Agriculture, which sums up his experience experimenting with fruits and nuts as human food and animal food crops. Smith saw the world as an inter-related whole and suggested mixed systems of trees with other crops underneath. This book inspired individuals such as Toyohiko Kagawa who pioneered forest farming in Japan in the 1930s.

In his 1964 book Water for Every Farm, Australian P. A. Yeomans advanced a definition of permanent agriculture as one that can be sustained indefinitely. Yeomans introduced both an observation-based approach to land use in Australia in the 1940s and the Keyline Design as a way of managing the supply and distribution of water in the 1950s. Other early influences include Stewart Brand's works, Ruth Stout and Esther Deans, who pioneered no-dig gardening, and Masanobu Fukuoka who, in the late 1930s in Japan, began advocating no-till orchards and gardens and natural farming.

Bill Mollison, who has been described as the "father of permaculture," cites Indigenous belief systems as an inspiration of the practice.

In the late 1960s, Bill Mollison, senior lecturer in Environmental Psychology at University of Tasmania, and David Holmgren, graduate student at the then Tasmanian College of Advanced Education started developing ideas about stable agricultural systems on the southern Australian island of Tasmania. Their recognition of the unsustainable nature of Western industrialized methods and their appreciation of Indigenous worldviews were critical to their formulation of permaculture. In their view, industrialized methods were highly dependent on non-renewable resources, and were additionally poisoning land and water, reducing biodiversity, and removing billions of tons of topsoil from previously fertile landscapes. They responded with permaculture. This term was first made public with their publication of their 1978 book Permaculture One.

Permaculture is a philosophy of working with, rather than against nature; of protracted and thoughtful observation rather than protracted and thoughtless labor; and of looking at plants and animals in all their functions, rather than treating any area as a single product system.

— Bill Mollison

Students of Mollison's Permaculture Design Course (PDC) included Lawton and Hemenway. Simon J. Fjell met Mollison and became a teacher of the first Permaculture Design Course in 1976. By the early 1980s, the concept had broadened from agricultural systems towards sustainable human habitats. After Permaculture One, Mollison further refined and developed the ideas while designing hundreds of permaculture sites and writing more detailed books, such as Permaculture: A Designers Manual. Mollison lectured in over 80 countries and taught his two-week PDC to hundreds of students. Mollison encouraged graduates to become teachers and set up their own institutes and demonstration sites. Critics suggest that this success weakened permaculture's social aspirations of moving away from industrial social forms. They argue that the self-help model (akin to franchising) has had the effect of creating market-focused social relationships that the originators initially opposed.

The permaculture movement spread throughout Asia and Central America. In Hong Kong the Asian Institute of Sustainable Architecture (AISA) was established. The Mesoamerican Permaculture Institute (IMAP) flourished in Guatemala. The Permaculture Institute of El Salvador is another example.

Foundational ethics

The ethics on which permaculture builds are:

• Earth care: Provision for all life systems to continue and multiply.
• People care: Provision for people to access those resources necessary for their existence.
• Fair share: Setting limits to population and consumption so that people do not take more than what is needed. By governing our own needs, we can set resources aside to further the above principles. This principle is also described as share the surplus.

Permaculture emphasizes patterns of landscape, function, and species assemblies. It determines where these elements should be placed so they can provide maximum benefit to the local environment. Permaculture maximizes useful connections between components and synergy of the final design. The focus of permaculture, therefore, is not on individual elements, but rather on the relationships among them. Properly done, the whole becomes greater than the sum of its parts. Permaculture seeks to minimize waste, human labor, and energy input and maximize benefits through synergy.

Permaculture design is founded in replicating or imitating natural patterns found in ecosystems because these solutions have emerged through evolution over thousands of years and have proven to be effective. As a result, the implementation of permaculture design will vary widely depending on the region of the Earth it is located in. Design principles derive from the science of systems ecology and the study of pre-industrial examples of sustainable land use. Permaculture draws from disciplines including organic farming, agroforestry, integrated farming, sustainable development, physics, meteorology, sociology, anthropology, biochemistry, engineering, and applied ecology.

Theory

Design principles

The viewpoint of a chicken through the eyes of Permaculture design.

Holmgren articulated twelve permaculture design principles in his Permaculture: Principles and Pathways Beyond Sustainability:

• Observe and interact: Take time to engage with nature to design solutions that suit a particular situation.
• Catch and store energy: Develop systems that collect resources at peak abundance for use in times of need.
• Obtain a yield: Emphasize projects that generate meaningful rewards.
• Apply self-regulation and accept feedback: Discourage inappropriate activity to ensure that systems function well.
• Use and value renewable resources and services: Make the best use of nature's abundance: reduce consumption and dependence on non-renewable resources.
• Produce no waste: Value and employ all available resources: waste nothing.
• Design from patterns to details: Observe patterns in nature and society and use them to inform designs, later adding details.
• Integrate rather than segregate: Proper designs allow relationships to develop between design elements, allowing them to work together to support each other.
• Use small and slow solutions: Small and slow systems are easier to maintain, make better use of local resources and produce more sustainable outcomes.
• Use and value diversity: Diversity reduces system-level vulnerability to threats and fully exploits its environment.
• Use edges and value the marginal: The border between things is where the most interesting events take place. These are often the system's most valuable, diverse and productive elements.
• Creatively use and respond to change: A positive impact on inevitable change comes from careful observation, followed by well-timed intervention.

Layers

Suburban permaculture garden in Sheffield, UK with different layers of vegetation

Layers are a tool used to design sustainable ecosystems that directly benefit humans. A mature ecosystem has many relationships between its constituent parts such as trees, understory, ground cover, soil, fungi, insects, and animals. Because plants grow to different heights, a diverse community of organisms can occupy a relatively small space, each at a different layer. Forests offer seven basic layers, although there can be many more, such as fungi.

• The canopy: the tallest trees. Large trees dominate, but typically do not saturate the area, i.e., some patches are devoid of trees.
• Understory layer: trees that flourish under the canopy.
• Shrub layer: woody perennials of limited height. Includes most berry bushes.
• Herbaceous layer: Plants that die back to the ground every winter, if cold enough. No woody stems. Many beneficial plants such as culinary and medicinal herbs are in this layer. Annuals, biennials and perennials.
• Soil surface/groundcover: Overlaps with the herbaceous layer and the groundcover layer; however plants in this layer grow much closer to the ground, densely fill bare patches, and typically can tolerate some foot traffic. Cover crops retain soil and lessen erosion, along with green manures that add nutrients and organic matter, especially nitrogen.
• Rhizosphere: Root layers within the soil. The major components of this layer are the soil and the organisms that live within it such as plant roots and zomes (including root crops such as potatoes and other edible tubers), fungi, insects, nematodes, worms, etc.
• Vertical layer: climbers or vines, such as runner beans and lima beans (vine varieties).

Guilds

Mycorrhizal fungi usually function in a mutualistic symbiotic relationship with plants.

 

Ladybugs are seen as beneficial insects in permaculture because of their help with aphid control

A guild is a mutually beneficial group of species that form a part of the larger ecosystem. Within a guild each species provides a unique set of diverse services that work in harmony. Guilds include compatible animals, insects, and plants that form symbiotic relationships which produce healthier plants and ecosystems as well as useful resources for humans. Plants may be grown for food production, drawing nutrients from deep in the soil through tap roots, balancing nitrogen levels in the soil (legumes), for attracting beneficial insects to the garden, and repelling undesirable insects or pests. There are several types of guilds, such as community function guilds, mutual support guilds, and resource partitioning guilds.

• Community function guilds group species based on a specific function or niche that they fill in the garden. Examples of this type of guild include plants that attract a particular beneficial insect or plants that restore nitrogen to the soil. These types of guilds are aimed at solving specific problems which may arise in a garden, such as infestations of harmful insects and poor nutrition in the soil.
• Mutual support guilds group species together that are complementary by working together and supporting each other. This guild may include a plant that fixes nitrogen, a plant that hosts insects that are predators to pests, and another plant that attract pollinators. An example of a mutual support guild is mycorrhizal fungi's symbiotic relationship with plants by providing minerals and nitrogen to plant roots and receiving sugars in return has been cited as an example of mutualistic guild. Permaculturalists take advantage of this beneficial relationship when designing their garden layouts.
• Resource partitioning guilds group species based on their abilities to share essential resources with one another through a process of niche differentiation. A potential example of this type of guild includes placing a fibrous- or shallow-rooted plant next to a tap-rooted plant so that they draw from different levels of soil nutrients.
• Establishment guilds are commonly used when working to establish target species (the primary vegetables, fruits, herbs, etc. you want established in your garden) with the support of pioneer species (plants that will help the target species succeed). For example, in temperate climates, plants such as comfrey (as a weed barrier and dynamic accumulator), lupine (as a nitrogen fixer), and daffodil (as a gopher deterrent) can together form a guild for a fruit tree. As the tree matures, the support plants will likely eventually be shaded out and can be used as compost.
• Mature guilds form once your target species are established. For example, if the tree layer of your landscape closes its canopy, sun-loving support plants will be shaded out and die. Shade loving medicinal herbs such as ginseng, black cohosh, and goldenseal can be planted as an understory.

Edge effect

The edge effect in ecology is the effect of juxtaposing contrasting environments in an ecosystem. Permaculturists argue that where differing systems meet can become highly productive and offer useful connections. An example of this is a coast. Where land and sea meet is a rich area that meets a disproportionate percentage of human and animal needs. This idea is reflected in permacultural designs by using spirals in herb gardens, or creating ponds that have wavy undulating shorelines rather than a simple circle or oval (thereby increasing the amount of edge for a given area).

Zones

Permaculture zones 0-5

Zones intelligently organize design elements in a human environment based on the frequency of human use and plant or animal needs. Frequently manipulated or harvested elements of the design are located close to the house in zones 1 and 2. Manipulated elements located further away are used less frequently. Zones are numbered from 0 to 5 based on positioning.

Zone 0

The house, or home center. Here permaculture principles aim to reduce energy and water needs, harnessing natural resources such as sunlight, to create a harmonious, sustainable environment in which to live and work. Zone 0 is an informal designation, which is not specifically defined in Mollison's book.

Zone 1

The zone nearest to the house, the location for those elements in the system that require frequent attention, or that need to be visited often, such as salad crops, herb plants, soft fruit like strawberries or raspberries, greenhouse and cold frames, propagation area, worm compost bin for kitchen waste, etc. Raised beds are often used in Zone 1 in urban areas.

Zone 2

This area is used for siting perennial plants that require less frequent maintenance, such as occasional weed control or pruning, including currant bushes and orchards, pumpkins, sweet potato, etc. Also a good place for beehives, larger scale composting bins, etc.

Zone 3

The area where main-crops are grown, both for domestic use and for trade purposes. After establishment, care and maintenance required are fairly minimal (provided mulches and similar things are used), such as watering or weed control maybe once a week.

Zone 4

A semi-wild area, mainly used for forage and collecting wild plants as well as production of timber for construction or firewood.

Zone 5

A wilderness area. Humans do not intervene in zone 5 apart from observing natural ecosystems and cycles. This zone hosts a natural reserve of bacteria, moulds and insects that can aid the zones above it.

People care

Photos of the Village Building Convergence event (2020)

Permaculture emphasizes a "sharing and caring" approach built on respect and reciprocity in human relationships rather than a competitive approach. The people care ethic needs attention firstly because of the importance of interpersonal dynamics in permaculture and secondly because the principles of permaculture can be used to effectively create vibrant, healthy, and productive communities through reconnecting humans to nature in regenerative ways. Bill Mollison describes how reconnecting with the Earth is necessary for many people because of ancestral separation:

Tribal peoples are very much aware of, and tied to, their soil and landscapes, so that their mental and physical health depend on these ties being maintained. The rest of us have suffered forcible, historic dislocations from home sites, and many no longer know where their home is, although there are new and conscious moves to reinhabit the earth and to identify with a bioregion as "home."

Implementing permaculture principles may create possibilities for self-healing as well as family and community healing. Permaculture teaches practitioners the lessons of interconnectedness and sustainability. Learning these lessons may increase one's mindfulness; a realization that nothing exists or functions in isolation. Permaculture has been described as a peacebuilding tool for communities that are steeped in conflict.

Discussions of Indigenous ethics in regard to permaculture have concluded that the people care ethic of permaculture is "often missing in Eurocolonialist capitalist societies." A permaculture program in Pembroke, Illinois devised an Indigenous permaculture curriculum to address people care, integrating the Mayan concept of in lak'ech ("I am because you are"), the Lakota concept of mitakuye oyasin ("all my relations"), and the Nguni Bantu concept of ubuntu ("I am because we all are") in their classes.

Cultural change

Permaculture Action Day in Denver (2016)

More than an approach to land management, permaculture is also a worldview or philosophy that emphasizes holistic approaches to life and works to create a wider culture based on these values. The ethics of earth care, people care, and fair share are applied to all facets of life, including areas such as education and administration. David Holmgren writes that permaculture is inherently based in the acknowledgement that an environmental crisis threatening humanity and life as we know it is on the horizon and that, as a result, a cultural change is needed to address this crisis: "the process of providing for people’s needs within ecological limits requires a cultural revolution." Permaculture aims to make people and local communities self-reliant from the industrialized political economy that is responsible for much of the ecological damage on Earth. Holmgren writes:

The fact is that our own comfort is based on the rape of planetary wealth, depriving other people (and future generations) of their own local resources. Our own ‘‘hard work’’ and the so-called ‘‘creativity’’ of our economy and ‘‘fairness’’ of our system of government are all secondary factors in creating our privilege. Once we understand the massive structural inequities between rich and poor nations, urban and rural communities and human resources and natural resources, the emphasis on providing for one’s own needs is seen in a different light. As we reduce our dependence on the global economy and replace it with household and local economies, we reduce the demand that drives current inequities. Thus ‘‘look after yourself first’’ is not an invitation to greed but a challenge to grow up through self-reliance and personal responsibility.

Permaculture involves taking action locally while being conscious of larger global issues. As described by Craig Gibsone and Jan Martin Bang, "we may rail at distant miscarriages of justice, but if we can't do very much about them, we may well be better off doing something about our local situation. That old worn-out phrase, 'think globally, act locally' sits very well with permaculture." Research has found that subsistence farmers practicing permaculture methods are more autonomous than those who rely on the global economy for their essential needs and are therefore less apt to view economic collapse as 'the end of the world'. June Brawner writes, "those who practice subsistence—though often associated with rurality, poverty, and backwardness—are more immune to these threats." The self-reliance of subsistence farmers in the face of economic downturn illustrates that what is commonly interpreted as 'wealthy' is socially constructed. While money is often interpreted as wealth in 'modern' society, this can shift suddenly in times of economic collapse.

Individuals who attempt to adhere to permaculture philosophy may confront obstacles because of modern structural barriers, such as landlessness and private property, as well as ideological barriers, such as the prevalence of opposing worldviews that directly conflict with permaculture principles. For example, permaculture research in San Lucas Tolimán, Guatemala suggested that the land deprivation of local Kaqchikel residents coupled with the indoctrination of evangelicalism obstructed the embrace of permaculture philosophy. In Indigenous or traditional communities, what is referred to as permaculture may already be culturally familiar. For example, a researcher found that in the Bulgarian town of Shipka, permaculture principles were widely viewed as "nothing new." This was because "their ancestors had practiced similar agricultural methods long before the term ‘permaculture’ was invented." Protecting Indigenous traditions from marginalization and destruction is important to permaculture.

Common practices

Agroforestry

Agroforestry in Burkina Faso, with maize under trees

Agroforestry uses the interactive benefits from combining trees and shrubs with crops or livestock. It combines agricultural and forestry technologies to create more diverse, productive, profitable, healthy and sustainable land-use systems. Trees or shrubs are intentionally used within agricultural systems, or non-timber forest products are cultured in forest settings.

Forest gardening/food forests involve systems designed to mimic natural forests. Forest gardens, like other permaculture designs, incorporate processes and relationships that the designers understand to be valuable in natural ecosystems. The Charter of the Forest makes extended use of permaculture ideals and techniques such as forest gardening as they are related to the philosophy of anarchism. It also employs permaculture issues as metaphorical commentary on real-life events, such as referencing the 2020 COVID-19 pandemic timeline in the scene "Pale Rust and An Albino Hawk".

Proponents of forest gardens include Graham Bell, Patrick Whitefield, Dave Jacke, Eric Toensmeier and Geoff Lawton. Bell started building his forest garden in 1991 and wrote The Permaculture Garden in 1995, Whitefield wrote the book How to Make a Forest Garden in 2002, Jacke and Toensmeier co-authored the two volume book set Edible Forest Gardening in 2005, and Lawton presented the film Establishing a Food Forest in 2008.

Tree Gardens, such as Kandyan tree gardens, in South and Southeast Asia, are often hundreds of years old. It is not evident whether they came from agroforestry, or permaculture. Many studies of these systems, especially those that predate the term permaculture, consider these systems to be forms of agroforestry.

Suburban and urban permaculture

South Central Farm was one of the largest urban gardens in the United States before its demolition in 2006.

The fundamental element of suburban and urban permaculture is the efficient utilization of space. Maximizing the space for food production and minimizing wasted space is important. Wildfire journal suggests using methods such as the keyhole garden to address this issue of space. Neighbors can also collaborate with each other to increase the scale of transformation. Sites such as recreation centers, neighborhood associations, city program, faith groups, and schools can become part of a larger social and economic movement. Columbia, an ecovillage in Portland, Oregon consisting of 37 apartment condominiums, influenced surrounding neighbors to implement similar green-minded principals or permaculture, including front-yard gardens. Suburban permaculture sites such as one in Eugene, Oregon include rainwater catchment, edible landscaping, removing paved driveways, turning a garage into living space, changing a south side patio into passive solar, aesthetic features, detached structures.

Transforming vacant lots in suburban and urban settings is a common practice of creating community-managed agriculture or farm sites. However, some of these farm sites are perceived by those in power as temporary or informal solutions to the vacant lot rather than as permanent fixtures of the city. This threatens the fundamental principal of permaculture: permanence. For example, Los Angeles' South Central Farm (1994-2006), which was one of the largest urban gardens in the United States, was bulldozed with approval from property owner Ralph Horowitz, despite large-scale protest from the majority Latino community who had developed deep bonds with the site. Over 40 farmers were arrested and evicted. The land sat empty for over a decade until, in 2019, the city council approved the lot for offices and warehouses.

The possibilities and challenges for developing suburban or urban permaculture differ greatly as a result of how the built environment is designed and property is treated in particular areas of the world. For example, a study comparing the built environment in Jaisalmer, India and Los Angeles, United States concluded that the American planned city is ecologically disastrous:

the application of universal rules regarding set-backs from roads and property lines systematically creates unused and purposeless space as an integral part of the built landscape, well beyond the classic image of the vacant lot. [...] Because these spaces are created in accordance with a general pattern, rather than responding to any local need or desire, many if not most are underutilized, unproductive, and generally maintained as ecologically disastrous lawns by unenthusiastic owners. In this broadest understanding of wasted land, the concept is opened to reveal how our system of urban design gives rise to a ubiquitous pattern of land that, while not usually conceived as vacant, is in fact largely without ecological or social value.

Hügelkultur

Sketch of a Hügelkultur bed.

Hügelkultur is the practice of burying wood to increase soil water retention. The porous structure of wood acts as a sponge when decomposing underground. During the rainy season, sufficient buried wood can absorb enough water to sustain crops through the dry season. This technique is a traditional practice that has been developed over centuries in Europe and has been recently adopted by permaculturalists. The Hügelkultur technique can be implemented through building mounds on the ground as well as in raised garden beds. In raised beds, the practice "imitates natural nutrient cycling found in wood decomposition and the high water holding capacities of organic detritus, while also improving bed structure and drainage properties." This is done by placing wood material (e.g. logs and sticks) in the bottom of the bed before piling organic soil and compost on top. A study comparing the water retention capacities of Hügel raised beds to non-Hügel beds determined that Hügel beds are both lower maintenance and more efficient in the long term by requiring less irrigation.

Vermicomposting

Healthy population of red wigglers in a vermicomposting bin.

Vermicomposting is a common practice in permaculture. The practice involves using earthworms, such as red wigglers, to break down green and brown waste. The worms produce worm castings, which can be used to organically fertilize the garden. Worm castings have been noted to increase plant growth and decrease heavy-metals in the soil. Worms are also introduced to garden beds, helping to aerate the soil and improve water retention. Worms may multiply quickly if provided conditions which are ideal. For example, a permaculture farm in Cuba began with 9 tiger worms in 2001 and 15 years later had a population of over 500,000. The worm castings are particularly useful as part of a seed starting mix and regular fertilizer. Worm castings are reportedly more successful than conventional compost for seed starting.

Natural building

Small cob building with a living roof.

Natural building involves using a range of building systems and materials that apply permaculture principals. The focus is on durability and the use of minimally processed, plentiful or renewable resources, as well as those that, while recycled or salvaged, produce healthy living environments and maintain indoor air quality. For example, cement, a common building material, emits carbon dioxide and is harmful to the environment while natural building works with the environment, using materials that are biodegradable, such as cob, adobe, rammed earth (unburnt clay), and straw bale (which insulates as well as modern synthetic materials).

Natural building attempts to lessen environmental impacts of buildings without sacrificing comfort, health, or aesthetics. Natural building employs abundantly available natural materials (e.g., clay, rock, sand, straw, wood, reeds), and draws heavily on traditional architectural strategies found in various climates. Building compactly and minimizing the ecological footprint is common, as are on-site handling of energy acquisition, on-site water capture, alternate sewage treatment, and water reuse. Most materials are sourced regionally, locally, or even on-site. Roofing coverings often include sod or 'living roofs', thatch, and wooden shakes or shingles. Rubble trench foundations are popular, as they do not require concrete. Likewise, dry-stacked or lime mortared stem walls are common. Natural builders also regularly combine wall systems in a single building, making best use of for example each material's thermal or water resistant properties.

Rainwater harvesting

Rainwater collection is a common practice of permaculture.

Rainwater harvesting is the accumulation and storage of rainwater for reuse before it runs off or reaches the aquifer. It has been used to provide drinking water, water for livestock, and water for irrigation, as well as other typical uses. Rainwater collected from the roofs of houses and local institutions can make an important contribution to the availability of drinking water. It can supplement the water table and increase urban greenery. Water collected from the ground, sometimes from areas which are especially prepared for this purpose, is called stormwater harvesting.

Greywater is wastewater generated from domestic activities such as laundry, dishwashing, and bathing, which can be recycled for uses such as landscape irrigation and constructed wetlands. Greywater is largely sterile, but not potable (drinkable). Greywater differs from water from sewage or blackwater that contains human or animal waste. A permaculture approach to blackwater is composting through a process known as humanure; a portmanteau of human and manure. The methane in humanure can be collected and used similar to natural gas as a fuel, such as for heating or cooking, and is commonly referred to as biogas. Biogas can be harvested from human waste and the remainder used as humanure. The simplest forms of humanure include a composting toilet or an outhouse or dry bog surrounded by trees that are heavy feeders that can be coppiced for wood fuel. This process eliminates the use of a plumbed toilet.

Domesticated animals

A backyard chicken coop.

 

Chicken roaming in an herb garden.

Domesticated animals are often incorporated into site design. Animals are a critical component of any sustainable ecosystem. Research indicates that without animals' contribution, ecological integrity is diminished or lost. Activities that contribute to the system include: foraging to cycle nutrients, clearing fallen fruit, weed maintenance, spreading seeds, and pest maintenance. Nutrients are cycled by animals, transformed from their less digestible form (such as grass or twigs) into more nutrient-dense manure.

Multiple animals can contribute, including cows, goats, chickens, geese, turkey, rabbits, and worms. An example is chickens who can be used to scratch over the soil, thus breaking down the topsoil and using fecal matter as manure. Factors such as timing and habits are critical. For example, animals require much more daily attention than plants.

Vegan permaculture

Vegan permaculture (also known as veganic permaculture, veganiculture, or vegaculture) avoids the use of domesticated animals. It is essentially the same as permaculture except for the addition of a fourth core value; "Animal Care." Zalan Glen, a raw vegan, proposes that vegaculture emerge from permaculture in the same way veganism split from vegetarianism in the 1940s. Vegan permaculture recognizes the importance of free-living animals, rather than domesticated animals, to create a balanced ecosystem. Soil fertility is maintained by the use of green manures, cover crops, green wastes, composted vegetable matter in place of manure.

Sheet mulching

Mulch is a protective cover placed over soil. Mulch material includes stones, leaves, cardboard, wood chips and gravel, although in permaculture mulches of organic material are preferred because they perform more functions. These include absorbing rainfall, reducing evaporation, providing nutrients, increasing soil organic matter, creating habitat for soil organisms, suppressing weed growth and seed germination, moderating diurnal temperature swings, protecting against frost, and reducing erosion. Sheet mulching is a gardening technique that attempts to mimic natural forest processes. Sheet mulching mimics the leaf cover that is found on forest floors. When deployed properly and in combination with other permaculture principles, it can generate healthy, productive and low maintenance ecosystems.

Sheet mulch serves as a "nutrient bank," storing nutrients contained in organic matter and slowly making these nutrients available to plants as the organic matter slowly and naturally breaks down. It also improves the soil by attracting and feeding earthworms, slaters and many other soil micro-organisms, as well as adding humus. Earthworms "till" the soil, and their worm castings are among the best fertilizers and soil conditioners. Sheet mulching can be used to reduce or eliminate non-desired plants by starving them of light, and can surpass herbicide or other methods of control.

Grazing

Conservation grazing Longhorn Cattle manage national nature reserve at Ruislip Lido

Grazing is blamed for much destruction. However, when grazing is modeled after nature, it can have the opposite effect. Cell grazing is a system of grazing in which herds or flocks are regularly and systematically moved to fresh range with the intent to maximize forage quality and quantity. Sepp Holzer and Joel Salatin have shown how grazing can start ecological succession or prepare ground for planting. Allan Savory's holistic management technique has been likened to "a permaculture approach to rangeland management". One variation is conservation grazing, were the primary purpose of the animals is to benefit the environment and the animals are not necessarily used for meat, milk or fiber. Sheep can replace lawn mowers. Goats and sheep can eat invasive plants.

Keyline design

Keyline design is a technique for maximizing the beneficial use of water resources. It was developed in Australia by farmer and engineer P. A. Yeomans. Keyline refers to a contour line extending in both directions from a keypoint. Plowing above and below the keyline provides a watercourse that directs water away from a purely downhill course to reduce erosion and encourage infiltration. It is used in designing drainage systems.

Fruit tree management

Some proponents of permaculture advocate heavily restricted pruning. Holzer used the method in connection with Hügelkultur berms. He has grew fruiting trees at altitudes (approximately 9,000 feet (2,700 m)) far above their normal altitude, temperature, and snow load ranges. The Hügelkultur berms kept or generated enough heat to allow the roots to survive during alpine winter conditions. The point of having unpruned branches, he notes, was that the longer (more naturally formed) branches bend over under the snow load until they touched the ground, thus forming a natural arch against snow loads that would break a shorter, pruned, branch.

Masanobu Fukuoka, as part of early experiments on his family farm in Japan, experimented with no-pruning methods, noting that he ended up killing many fruit trees by simply letting them go, which made them become convoluted and tangled, and thus unhealthy. He learned that this is the difference between natural-form trees and previously-pruned fruit trees. He concluded that trees should be raised entirely without pruning, allowing them to form healthy and efficient natural branch patterns. This reflects the Tao-philosophy of Wú wéi translated in part as no-action (against nature). He interpreted this as no unnecessary pruning, nature farming or "do-nothing" farming, of fruit trees, distinct from non-intervention or literal no-pruning. He ultimately achieved yields comparable to or exceeding standard/intensive practices of using pruning and chemical fertilisation.

Marine systems

Harvesting of seaweed in Jambiani, Tanzania.

Permaculture derives its origin from agriculture, although the same principles, especially its foundational ethics, can also be applied to mariculture, particularly seaweed farming. An example is marine permaculture wherein artificial upwelling of cold, deep ocean water is induced. When attachment substrate is provided in association with such an upwelling, and kelp sporophytes are present, a kelp forest ecosystem can be established (kelp needs the cool temperatures and abundant dissolved macronutrients present in such an environment). Microalgae proliferate as well. Marine forest habitat is beneficial for many fish species, and the kelp is a renewable resource for food, animal feed, medicines and various other commercial products. It is also a powerful tool for carbon fixation.

The upwelling can be powered by renewable energy on location. Vertical mixing has been reduced due to ocean stratification effects associated with climate change. The Permian Mass Extinction was thought to have been brought on by such ocean warming, stratification, deoxygenation, wikt:anoxia, and subsequent extinction of 96% of all marine species. Reduced vertical mixing and marine heatwaves have decimated seaweed ecosystems in many areas. Marine permaculture mitigates this by restoring some vertical mixing and preserves these important ecosystems. By preserving and regenerating habitat offshore on a platform, marine permaculture employs natural processes to regenerate marine life.

Intellectual property

Trademark and copyright disputes surround the word permaculture. Mollison's books claimed on the copyright page, "The contents of this book and the word PERMACULTURE are copyright." Eventually Mollison acknowledged that he was mistaken and that no copyright protection existed.

In 2000, Mollison's U.S.-based Permaculture Institute sought a service mark (a form of trademark) for the word permaculture when used in educational services such as conducting classes, seminars, or workshops. The service mark would have allowed Mollison and his two institutes to set enforceable guidelines regarding how permaculture could be taught and who could teach it, particularly with relation to the PDC, despite the fact that he had been certifying teachers since 1993. This attempt failed and was abandoned in 2001. Mollison's application for trademarks in Australia for the terms "Permaculture Design Course" and "Permaculture Design" were withdrawn in 2003. In 2009 he sought a trademark for "Permaculture: A Designers' Manual" and "Introduction to Permaculture", the names of two of his books. These applications were withdrawn in 2011. Australia has never authorized a trademark for the word permaculture.

Criticism

Critics Peter Harper and Rob Scott pushed for less reliance on anecdote and extrapolation from ecological first principles, in favor of peer-reviewed research to substantiate productivity claims and to clarify methodology.

Defenders respond out that permaculture is not yet a mainstream scientific tradition and lacks the resources of traditional agriculture. Ferguson and Lovell point out that permaculturalists rarely engage with mainstream research in agroecology, agroforestry, or ecological engineering, and claim that mainstream science has an elitist or pro-corporate bias.

While there are long-term benefits from permaculture, the short-term decline in agricultural output compared to conventional farming may need to be combined with family planning or a two-child policy in most countries, so that no new farmland is needed for any given population.

Aquaculture

In his books Sustainable Freshwater Aquaculture and Farming in Ponds and Dams, Nick Romanowski expresses the view that the presentation of aquaculture in Bill Mollison's books is unrealistic and misleading.

Agroforestry

Greg Williams argues that forests cannot be more productive than farmland because the net productivity of forests declines as they mature due to ecological succession. Permaculture proponents respond that this is true only when comparing data between woodland forest and climax vegetation, but not when comparing farmland vegetation against woodland forest. For example, ecological succession generally results in rising productivity until it reaches the woodland state (67% tree cover), before declining until full maturity.