The Trouble with Permaculture

4 10 2016

With the recent passing of Bill Mollison, much has been published on the interweb about Permaculture; While Glenda was here for nine days, I didn’t spend much time at this laptop, preferring to help her set her own stamp on the Fanny Farm and using her very able gardening skills to get stuck into some planting…. and fixing the goose tractor in readiness for the acquisition of more birds, but there will be time for that some place else on this site.

Having published Samuel Alexander’s epitaph for Bill Mollison by merely copying and pasting the Conversation article, I didn’t bother following the links therein; luckily, Greg Bell did, and posted a couple in a comment he left here, many thanks Greg…. as he says in his comment, “Those two “here” links to critiques of permaculture are the two most important things I’ve read all year (and they, in turn, link to even more)……

The first link is to Resilience.org and bears the same title as this entry. Fascinating reading indeed, as are the comments below it.





Fifty Million Farmers

14 03 2014

There was a time not so long ago when famine was an expected, if not accepted, part of life. Until the 19th century—whether in China, France, India or Britain—food came almost entirely from local sources and harvests were variable. In good years, there was plenty—enough for seasonal feasts and for storage in anticipation of winter and hard times to come; in bad years, starvation cut down the poorest and the weakest—the very young, the old, and the sickly. Sometimes bad years followed one upon another, reducing the size of the population by several percent. This was the normal condition of life in pre-industrial societies, and it persisted for thousands of years.

SainsburyInStoreToday, in America, such a state of affairs is hard to imagine. Food is so cheap and plentiful that obesity is a far more widespread concern than hunger. The average mega-supermarket stocks an impressive array of exotic foods from across the globe, and even staples are typically trucked from hundreds of miles away. Many people in America did go hungry during the Great Depression, but those were times that only the elderly can recall. In the current regime, the desperately poor may experience chronic malnutrition and may miss meals, but for most the dilemma is finding time in the day’s hectic schedule to go to the grocery store or to cook. As a result, fast-food restaurants proliferate: the fare may not be particularly nutritious, but even an hour’s earnings at minimum wage will buy a meal or two. The average American family spent 20 percent of its income on food in 1950; today the figure is 10 percent.

This is an extraordinary situation; but because it is the only one that most Americans alive today have ever experienced, we tend to assume that it will continue indefinitely. However there are reasons to think that our current anomalous abundance of inexpensive food may be only temporary; if so, present and future generations may become acquainted with that old, formerly familiar but unwelcome houseguest—famine.

The following are four principal bases (there are others) for this gloomy forecast.

The first has to with looming fuel shortages. This is a subject I have written about extensively elsewhere, so I shall not repeat myself in any detail. Suffice it to say that the era of cheap oil and natural gas is coming to a crashing end, with global oil production projected to peak in 2010 and North American natural gas extraction rates already in decline. These events will have enormous implications for America’s petroleum-dependent food system.

energyfarmingModern industrial agriculture has been described as a method of using soil to turn petroleum and gas into food. We use natural gas to make fertilizer, and oil to fuel farm machinery and power irrigation pumps, as a feedstock for pesticides and herbicides, in the maintenance of animal operations, in crop storage and drying, and for transportation of farm inputs and outputs. Agriculture accounts for about 17 percent of the U.S. annual energy budget; this makes it the single largest consumer of petroleum products as compared to other industries. By comparison, the U.S. military, in all of its operations, uses only about half that amount. About 350 gallons (1,500 litres) of oil equivalents are required to feed each American each year, and every calorie of food produced requires, on average, ten calories of fossil-fuel inputs. This is a food system profoundly vulnerable, at every level, to fuel shortages and skyrocketing prices. And both are inevitable.

An attempt to make up for fuel shortfalls by producing more biofuels—ethanol, butanol, and biodiesel—will put even more pressure on the food system, and will likely result in a competition between food and fuel uses of land and other resources needed for agricultural production. Already 14 percent of the U.S. corn crop is devoted to making ethanol, and that proportion is expected to rise to one quarter, based solely on existing projects-in-development and government mandates.

communityfarmingThe second factor potentially leading to famine is a shortage of farmers. Much of the success of industrial agriculture lies in its labour efficiency: far less human work is required to produce a given amount of food today than was the case decades ago (the actual fraction, comparing the year 2000 with 1900, is about one seventh). But that very success implies a growing vulnerability. We don’t need as many farmers, as a percentage of the population, as we used to; so, throughout the past century, most farming families—including hundreds of thousands and perhaps millions that would have preferred to maintain their rural, self-sufficient way of life—were economically forced to move to cities and find jobs. Today so few people farm that vital knowledge of how to farm is disappearing. The average age of American farmers is over 55 and approaching 60. The proportion of principal farm operators younger than 35 has dropped from 15.9 percent in 1982 to 5.8 percent in 2002. Of all the dismal statistics I know, these are surely among the most frightening. Who will be growing our food twenty years from now? With less oil and gas available, we will need far more knowledge and muscle power devoted to food production, and thus far more people on the farm, than we have currently.

The third worrisome trend is an increasing scarcity of fresh water. Sixty percent of water used nationally goes toward agriculture. California’s Central Valley, which produces the substantial bulk of the nation’s fruits, nuts, and vegetables, receives virtually no rainfall during summer months and relies overwhelmingly on irrigation. But the snowpack on the Sierras, which provides much of that irrigation water, is declining, and the aquifer that supplies much of the rest is being drawn down at many times its recharge rate. If these trends continue, the Central Valley may be incapable of producing food in any substantial quantities within two or three decades. Other parts of the country are similarly overspending their water budgets, and very little is being done to deal with this looming catastrophe. [editorial note:  this is happening right now!]

climateagricultureFourth and finally, there is the problem of global climate change. Often the phrase used for this is “global warming,” which implies only the fact that the world’s average temperature will be increasing by a couple of degrees or more over the next few decades. The much greater problem for farmers is destabilization of weather patterns. We face not just a warmer climate, but climate chaos: droughts, floods, and stronger storms in general (hurricanes, cyclones, tornadoes, hail storms)—in short, unpredictable weather of all kinds. Farmers depend on relatively consistent seasonal patterns of rain and sun, cold and heat; a climate shift can spell the end of farmers’ ability to grow a crop in a given region, and even a single freak storm can destroy an entire year’s production. Given the fact that modern American agriculture has become highly centralized due to cheap transport and economies of scale (almost the entire national spinach crop, for example, comes from a single valley in California), the damage from that freak storm is today potentially continental or even global in scale. We have embarked on a century in which, increasingly, freakish weather is normal.

I am not pointing out these problems, and their likely consequences, in order to cause panic. As I propose below, there is a solution to at least two of these dilemmas, one that may also help us address the remaining ones. It is not a simple or easy strategy and it will require a coordinated and sustained national effort. But in addition to averting famine, this strategy may permit us to solve a host of other, seemingly unrelated social and environmental problems.

Intensifying Food Production

In order to get a better grasp of the problems and the solution being proposed, it is essential that we understand how our present exceptional situation of cheap abundance came about. In order to do that, we must go back not just a few decades, but at least ten thousand years.

stone-age-farm-farmer-lgThe origins of agriculture are shrouded in mystery, though archaeologists have been whittling away at that mystery for decades. We know that horticulture (gardening) began at somewhat different periods, independently, in at least three regions—the Middle East, Southeast Asia, and Central America. Following the end of the last Ice Age, roughly 12,000 years ago, much of humanity was experiencing a centuries-long food crisis brought on by the over-hunting of the megafauna that had previously been at the center of the human diet. The subsequent domestication of plants and animals brought relative food security, as well as the ability to support larger and more sedentary populations.

As compared to hunting and gathering, horticulture intensified the process of obtaining food. Intensification (because it led to increased population density—i.e., more mouths to feed), then led to the need for even more intensification: thus horticulture (gardening) eventually led to agriculture (field cropping). The latter produced more food per unit of land, which enabled more population growth, which meant still more demand for food. We are describing a classic self-reinforcing feedback loop.

As a social regime, horticulture did not represent a decisive break with hunting and gathering. Just as women had previously participated in essential productive activities by foraging for plants and hunting small animals, they now played a prominent role in planting, tending, and harvesting the garden—activities that were all compatible with the care of infants and small children. Thus women’s status remained relatively high in most horticultural societies. Seasonal surpluses were relatively small and there was no full-time division of labor.

But as agriculture developed—with field crops, ploughs, and draft animals—societies inevitably mutated in response. Plowing fields was men’s work; women were forced to stay at home and lost social power. Larger seasonal surpluses required management as well as protection from raiders; full-time managers and specialists in violence proliferated as a result. Societies became multi-layered: wealthy ruling classes (which had never existed among hunter-gatherers, and were rare among gardeners) sat atop an economic pyramid that came to include scribes, soldiers, and religious functionaries, and that was supported at its base by the vastly more numerous peasants—who produced all the food for themselves and everyone else as well. Writing, mathematics, metallurgy, and, ultimately, the trappings of modern life as we know it thus followed not so much from planting in general, as from agriculture in particular.

As important an instance of intensification as agriculture was, in many respects it pales in comparison with what worldpopgrowth4has occurred within the past century or so, with the application of fossil fuels to farming. Petroleum-fed tractors replaced horses and oxen, freeing up more land to grow food for far more people. The Haber-Bosch process for synthesizing ammonia from fossil fuels, invented just prior to World War I, has doubled the amount of nitrogen available to green nature—with nearly all of that increase going directly to food crops. New hybrid plant varieties led to higher yields. Technologies for food storage improved radically. And fuel-fed transport systems enabled local surpluses to be sold not just regionally, but nationally and even globally. Through all of these strategies, we have developed the wherewithal to feed seven times the population that existed at the beginning of the Industrial Revolution. And, in the process, we have made farming uneconomical and unattractive to all but a few.

That’s the broad, global overview. In America, whose history as an independent nation begins at the dawn of the industrial era, the story of agriculture comprises three distinct periods:

The Expansion Period (1600 to 1920): Increases in food production during these three centuries came simply from putting more land into production; technological change played only a minor role.

The Mechanization Period (1920 to 1970): In this half-century, technological advances issuing from cheap, abundant fossil-fuel energy resulted in a dramatic increase in productivity (output per worker hour). Meanwhile, farm machinery, pesticides, herbicides, irrigation, new hybrid crops, and synthetic fertilizers allowed for the doubling and tripling of crop production. Also during this time, U.S. Department of Agriculture policy began favoring larger farms (the average U.S. farm size grew from 100 acres in 1930 to almost 500 acres by 1990), and production for export.

The Saturation Period (1970-present): In recent decades, the application of still greater amounts of energy have produced smaller relative increases in crop yields; meanwhile an ever-growing amount of energy is being expended to maintain the functioning of the overall system. For example, about ten percent of the energy in agriculture is used just to offset the negative effects of soil erosion, while increasing amounts of pesticides must be sprayed each year as pests develop resistances. In short, strategies that had recently produced dramatic increases in productivity became subject to the law of diminishing returns.

While we were achieving miracles of productivity, agriculture’s impact on the natural world was also growing; indeed it is now the single greatest source of human damage to the global environment. That damage takes a number of forms: erosion and salinisation of soils; deforestation (a strategy for bringing more land into cultivation); fertilizer runoff (which ultimately creates enormous “dead zones” around the mouths of many rivers); loss of biodiversity; fresh water scarcity; and agrochemical pollution of water and soil.

In short, we created unprecedented abundance while ignoring the long-term consequences of our actions. This is more than a little reminiscent of how some previous agricultural societies—the Greeks, Babylonians, and Romans—destroyed soil and habitat in their mania to feed growing urban populations, and collapsed as a result.

Fortunately, during the past century or two we have also developed the disciplines of archaeology and ecology, which teach us how and why those ancient societies failed, and how the diversity of the web of life sustains us. Thus, in principle, if we avail ourselves of this knowledge, we need not mindlessly repeat yet again the time-worn tale of catastrophic civilizational collapse.

The 21st Century: De-Industrialization

How might we avoid such a fate?

deindustrialisationSurely the dilemmas we have outlined above are understood by the managers of the current industrial food system. They must have some solutions in mind.

Indeed they do, and, predictably perhaps, those solutions involve a further intensification of the food production process. Since we cannot achieve much by applying more energy directly to that process, the most promising strategy on the horizon seems to be the genetic engineering of new crop varieties. If, for example, we could design crops to grow with less water, or in unfavourable climate and soil conditions, we could perhaps find our way out of the current mess.

Unfortunately, there are some flaws with this plan. Our collective experience with genetically modifying crops so far shows that glowing promises of higher yields, or of the reduced need for herbicides, have seldom been fulfilled. At the same time, new genetic technologies carry with them the potential for horrific unintended consequences in the forms of negative impacts on human health and the integrity of ecosystems. We have been gradually modifying plants and animals through selective breeding for millennia, but new gene-splicing techniques enable the re-mixing of genomes in ways and to degrees impossible heretofore. One serious error could result in biological tragedy on an unprecedented scale.

Yet even if future genetically modified commercial crops prove to be much more successful than past ones, and even if we manage to avert a genetic apocalypse, the means of producing and distributing genetically engineered seeds is itself reliant on the very fuel-fed industrial system that is in question.

Is it possible, then, that a solution lies in another direction altogether—perhaps in deliberately de-industrializingdetroitfarm production, but doing so intelligently, using information we have gained from the science of ecology, as well as from traditional and indigenous farming methods, in order to reduce environmental impacts while maintaining total yields at a level high enough to avert widespread famine?

This is not an entirely new idea (as you all well know, the organic and ecological farming movements have been around for decades), but up to this point the managers of the current system have resisted it. This is no doubt largely because those managers are heavily influenced by giant corporations that profit from centralized industrial production for distant markets. Nevertheless, the fact that we have reached the end of the era of cheap oil and gas demands that we re-examine the potential costs and benefits of our current trajectory and its alternatives.

I believe we must and can de-industrialize agriculture. The general outline of what I mean by de-industrialization is simple enough: this would imply a radical reduction of fossil fuel inputs to agriculture, accompanied by an increase in labour inputs and a reduction of transport, with production being devoted primarily to local consumption.

Once again, fossil fuel depletion almost ensures that this will happen. But at the same time, it is fairly obvious that if we don’t plan for de-industrialization, the result could be catastrophic. It’s worth taking a moment to think about how events might unfold if the process occurs without intelligent management, driven simply by oil and gas depletion.

Facing high fuel prices, family farms would declare bankruptcy in record numbers. Older farmers (the majority, in other words) would probably choose simply to retire, whether they could afford to or not. However, giant corporate farms would also confront rising costs—which they would pass along to consumers by way of dramatically higher food prices.

Yields would begin to decline—in fits and starts—as weather anomalies and water shortages affected one crop after another.

Meanwhile, people in the cities would also feel the effects of skyrocketing energy prices. Entire industries would falter, precipitating a general economic collapse. Massive unemployment would lead to unprecedented levels of homelessness and hunger.

Many people would leave cities looking for places to live where they could grow some food. Yet they might find all of the available land already owned by banks or the government. Without experience of farming, even those who succeeded in gaining access to acreage would fail to produce much food and would ruin large tracts of land in the process.

Eventually these problems would sort themselves out; people and social systems would adapt—but probably not before an immense human and environmental tragedy had ensued.

I wish I could say that this forecast is exaggerated for effect. Yet the actual events could be far more violent and disruptive than it is possible to suggest in so short a summary.

Examples and Strategies

cityfarmThings don’t have to turn out that way. As I have already said, I believe that the de-industrialization of agriculture could be carried out in a way that is not catastrophic and that in fact substantially benefits society and the environment in the long run. But to be convinced of the thesis we need more than promises—we need historic examples and proven strategies. Fortunately, we have two of each.

In some respects the most relevant example is that of Cuba’s Special Period. In the early 1990s, with the collapse of the Soviet Union, Cuba lost its source of cheap oil. Its industrialized agricultural system, which was heavily fuel-dependent, immediately faltered. Very quickly, Cuban leaders abandoned the Soviet industrial model of production, changing from a fuel- and petrochemical-intensive farming method to a more localized, labor-intensive, organic mode of production.

How they did this is itself an interesting story. Eco-agronomists at Cuban universities had already been advocating a transition somewhat along these lines. However, they were making little or no headway. When the crisis hit, they were given free rein to, in effect, redesign the entire Cuban food system. Had these academics not had a plan waiting in the wings, the nation’s fate might have been sealed.

cubaHeeding their advice, the Cuban government broke up large, state-owned farms and introduced private farms, farmer co-ops, and farmer markets. Cuban farmers began breeding oxen for animal traction. The Cuban people adopted a mainly vegetarian diet, mostly involuntarily (Meat eating went from twice a day to twice a week). They increased their intake of vegetable sources of protein and farmers decreased the growing of wheat and rice (Green Revolution crops that required too many inputs). Urban gardens (including rooftop gardens) were encouraged, and today they produce 50 to 80 percent of vegetables consumed in cities.

Early on, it was realized that more farmers were needed, and that this would require education. All of the nation’s colleges and universities quickly added courses on agronomy. At the same time, wages for farmers were raised to be at parity with those for engineers and doctors. Many people moved from the cities to the country; in some cases there were incentives, in others the move was forced.

The result was survival. The average Cuban lost 20 pounds of body weight, but in the long run the overall health of the nation’s people actually improved as a consequence. Today, Cuba has a stable, slowly growing economy. There are few if any luxuries, but everyone has enough to eat. Having seen the benefit of smaller-scale organic production, Cuba’s leaders have decided that even if they find another source of cheap oil, they will maintain a commitment to their new, decentralized, low-energy methods.

I don’t want to give the impression that Cubans sailed through the Special Period unscathed. Cuba was a grim place during these years, and to this day food is far from plentiful there by American standards. My point is not that Cuba is some sort of paradise, but simply that matters could have been far worse.

It could be objected that Cuba’s experience holds few lessons for our own nation. Since Cuba has a very different government and climate, we might question whether its experience can be extrapolated to the U.S.

uncle-sam-victory-gardenLet us, then, consider an indigenous historical example. During both World Wars, Americans planted Victory Gardens. During both periods, gardening became a sort of spontaneous popular movement, which (at least during World War II) the USDA initially tried to suppress, believing that it would compromise the industrialization of agriculture. It wasn’t until Eleanor Roosevelt planted a Victory Garden in the White House lawn that agriculture secretary Claude Wickard relented; his agency then began to promote Victory Gardens and to take credit for them. At the height of the movement, Victory Gardens were producing roughly 40 percent of America’s vegetables, an extraordinary achievement in so short a time.

In addition to these historical precedents, we have new techniques developed with the coming agricultural crisis in mind; two of the most significant are Permaculture and Biointensive farming (there are others—such as efforts by Wes Jackson of The Land Institute to breed perennial grain crops—but limitations of time and space require me to pick and choose).

permapicPermaculture was developed in the late 1970s by Australian ecologists Bill Mollison and David Holmgren in anticipation of exactly the problem we see unfolding before us. Holmgren defines Permaculture as “consciously designed landscapes that mimic the patterns and relationships found in nature, while yielding an abundance of food, fiber, and energy for provision of local needs.” Common Permaculture strategies include mulching, rainwater capture using earthworks such as swales, composting, and the harmonious integration of aquaculture, horticulture, and small-scale animal operations. A typical Permaculture farm may produce a small cash crop but concentrates largely on self-sufficiency and soil building. Significantly, Permaculture has played an important role in Cuba’s adaptation to a low-energy food regime.

Biointensive farming has been developed primarily by Californian John Jeavons, author of How to Grow More Vegetables. Like Permaculture, Biointensive is a product of research begun in the 1970s. Jeavons defines Biointensive (now trademarked as “Grow Biointensive”) farming as

. . . an organic agricultural system that focuses on maximum yields from the minimum area of land, while simultaneously improving the soil. The goal of the method is long-term sustainability on a closed-system basis. Because biointensive is practiced on a relatively small scale, it is well suited to anything from personal or family to community gardens, market gardens, or minifarms. It has also been used successfully on small-scale commercial farms.

???????????????????????????????Like Homgren and Mollison, Jeavons has worked for the past three decades in anticipation of the need for the de-industrialization of food production due to accumulating environmental damage and fossil fuel depletion. Currently Biointensive farming is being taught extensively in Africa and South America as a sustainable alternative to the globalized monocropping. The term “biointensive” suggests that what we are discussing here is not a de-intensification of food production, but rather the development of production along entirely different lines. While both Permaculture and Biointensive have been shown to be capable of dramatically improving yields-per-acre, their developers clearly understand that even these methods will eventually fail us unless we also limit demand for food by gradually and humanely limiting the size of the human population.

In short, it is possible in principle for industrial nations like the U.S. to make the transition to smaller-scale, non-petroleum food production, given certain conditions. There are both precedents and models.

However, all of them imply more farmers. Here’s the catch—and here’s where the ancillary benefits kick in.

The Key: More Farmers!

comfarmOne way or another, re-ruralization will be the dominant social trend of the 21st century. Thirty or forty years from now—again, one way or another—we will see a more historically normal ratio of rural to urban population, with the majority once again living in small, farming communities. More food will be produced in cities than is the case today, but cities will be smaller. Millions more people than today will be in the countryside growing food.

They won’t be doing so the way farmers do it today, and perhaps not the way farmers did it in 1900.

Indeed, we need perhaps to redefine the term farmer. We have come to think of a farmer as someone with 500 acres and a big tractor and other expensive machinery. But this is not what farmers looked like a hundred years ago, and it’s not an accurate picture of most current farmers in less-industrialized countries. Nor does it coincide with what will be needed in the coming decades. We should perhaps start thinking of a farmer as someone with 3 to 50 acres, who uses mostly hand labour and twice a year borrows a small tractor that she or he fuels with ethanol or biodiesel produced on-site.

How many more farmers are we talking about? Currently the U.S. has three or four million of them, depending on how we define the term.

Let’s again consider Cuba’s experience: in its transition away from fossil-fueled agriculture, that nation found that it required 15 to 25 percent of its population to become involved in food production. In America in 1900, nearly 40 percent of the population farmed; the current proportion is close to one percent.

Do the math for yourself. Extrapolated to this country’s future requirements, this implies the need for a minimum of 40 to 50 million additional farmers as oil and gas availability declines. How soon will the need arise? Assuming that the peak of global oil production occurs within the next five years, and that North American natural gas is already in decline, we are looking at a transition that must occur over the next 20 to 30 years, and that must begin approximately now.

Fortunately there are some hopeful existing trends to point to. The stereotypical American farmer is a middle-aged, Euro-American male, but the millions of new farmers in our future will have to include a broad mix of people, reflecting America’s increasing diversity. Already the fastest growth in farm operators in America is among female full-time farmers, as well as Hispanic, Asian, and Native American farm operators.

young-farmer-female

Another positive trend worth noting: Here in the Northeast, where the soil is acidic and giant agribusiness has not established as much of a foothold as elsewhere, the number of small farms is increasing. Young adults—not in the millions, but at least in the hundreds—are aspiring to become Permaculture or organic or Biointensive farmers. Farmers markets and CSAs are established or springing up throughout the region. This is somewhat the case also on the Pacific coast, much less so in the Midwest and South.

What will it take to make these tentative trends the predominant ones? Among other things we will need good and helpful policies. The USDA will need to cease supporting and encouraging industrial monocropping for export, and begin supporting smaller farms, rewarding those that make the effort to reduce inputs and to grow for local consumption. In the absence of USDA policy along these lines, we need to pursue state, county, and municipal efforts to support small farms in various ways, through favourable zoning, by purchasing local food for school lunches, and so on.

We will also require land reform. Those millions of new farmers will need access to the soil, and there must be some means for assisting in making land available for this purpose. Conservation land trusts may be useful in this regard, and we might take inspiration from Indian Line Farm, here in the northeast.

Since so few people currently know much about farming, education will be essential. Universities and community colleges have both the opportunity and responsibility to quickly develop programs in small-scale ecological farming methods—programs that also include training in other skills that farmers will need, such as in marketing and formulating business plans.

Since few if any farms are financially successful the first year or even the second or third, loans and grants will also be necessary to help farmers get started.

These new farmers will need higher and stabilized food prices. As difficult as it may be even to imagine this situation now, food rationing may be required at some point in the next two or three decades. That quota system needs to be organized in such a way as to make sure everyone has the bare essentials, and to support the people at the base of the food system—the farmers.

Finally, we need a revitalization of farming communities and farming culture. A century ago, even in the absence of the air and auto transport systems we now take for granted, small towns across this land strove to provide their citizens with lectures, concerts, libraries, and yearly chautauquas. Over the past decades these same towns have seen their best and brightest young people flee first to distant colleges and then to the cities. The folks left behind have done their best to maintain a cultural environment, but in all too many cases that now consists merely of a movie theater and a couple of video rental stores. Farming communities must be interesting, attractive places if we expect people to inhabit them and for children to want to stay there.

If We Do This Well

We have been trained to admire the benefits of intensification and industrialization. But, as I’ve already indicated, we have paid an enormous price for these benefits—a price that includes alienation from nature, loss of community and tradition, and the acceptance of the anonymity and loss of autonomy implied by mass society. In essence, this tradeoff has its origins in the beginnings of urbanization and agriculture.

Could we actually regain much of what we have lost? Yes, perhaps by going back, at least in large part, to horticulture. Recall that the shift from horticulture to agriculture was, as best we can tell, a fateful turning point in cultural history. It represented the beginning of full-time division of labour, hierarchy, and patriarchy.

permaculture_farmBiointensive farming and Permaculture are primarily horticultural rather than agricultural systems. These new, intelligent forms of horticulture could, then, offer an alternative to a new feudalism with a new peasantry. In addition, they emphasize biodiversity, averting many of the environmental impacts of field cropping. They use various strategies to make hand labor as efficient as possible, minimizing toil and drudgery. And they typically slash water requirements for crops grown in arid regions.

We have gotten used to a situation where most farmers rely on non-farm income. As of 2002 only a bit less than 60 percent of farm operators reported that their primary work is on the farm. Only 9 percent of primary operators on farms with one operator, and 10 percent on farms with multiple operators, report all of their income as coming from the farm.

The bad side of this is that it means it’s hard to make a living farming these days. The good side is that we don’t have to think of farming as an exclusive occupation. As people return to small communities and to farming, they could bring with them other interests. Rather than a new peasantry that spends all of its time in drudgery, we could look forward to a new population of producers who maintain interests in the arts and sciences, in history, philosophy, spirituality, and psychology—in short, the whole range of pursuits that make modern urban life interesting and worthwhile.

Moreover, the re-ruralization program I am describing could be a springboard for the rebirth of democracy in this nation. I do not have to tell this audience how, over the past few years, democracy in America has become little more than a slogan. In fact this erosion of our democratic traditions has been going on for some time. As Kirkpatrick Sale showed in his wonderful book Human Scale, as communities grow in size, individuals’ ability to influence public affairs tends to shrink. Sociological research now shows that people who have the ability to influence policy in their communities show a much higher sense of satisfaction with life in general. In short, the re-ruralization of America could represent the fulfilment of Thomas Jefferson’s vision of an agrarian democracy—but without the slaves.

If we do this well, it could mean the revitalization not only of democracy, but of the family and of authentic, place-based culture. It could also serve as the basis for a new, genuine conservatism to replace the ersatz conservatism of the current ruling political elites.

What I am proposing is nothing less than a new alliance among environmental organizations, farmers, gardeners, organizations promoting economic justice, the anti-globalization movement, universities and colleges, local businesses, churches, and other social organizations. Moreover, the efforts of this alliance would have to be coordinated at the national, state, and local level. This is clearly a tall order. However, we are not talking about merely a good idea. This is a survival strategy.

It may seem that I am describing and advocating a reversion to the world of 1800, or even that of 8,000 BC. This is not really the case. We will of course need to relearn much of what our ancestors knew. But we have discovered a great deal about biology, geology, hydrology, and other relevant subjects in recent decades, and we should be applying that knowledge—as Holmgren, Mollison, Jeavons, and others have done—to the project of producing food for ourselves.

whats-wrong-with-our-food-system

Cultural anthropology teaches us that the way people get their food is the most reliable determinant of virtually all other social characteristics. Thus, as we build a different food system we will inevitably be building a new kind of culture, certainly very different from industrial urbanism but probably also from what preceded it. As always before in human history, we will make it up as we go along, in response to necessity and opportunity.

Perhaps these great changes won’t take place until the need is obvious and irresistibly pressing. Maybe gasoline needs to get to $10 a gallon. Perhaps unemployment will have to rise to ten or twenty or forty percent, with families begging for food in the streets, before embattled policy makers begin to reconsider their commitment to industrial agriculture.

But even in that case, as in Cuba, all may depend upon having another option already articulated. Without that, we will be left to the worst possible outcome.

Rather than consigning ourselves to that fate, let us accept the current challenge—the next great energy transition—as an opportunity not to vainly try to preserve business as usual, the American Way of Life that, we are told, is not up for negotiation, but rather to re-imagine human culture from the ground up.

(This lecture drew on certain ideas earlier put forward by Knox, New York farmer Sharon Astyk in her remarks at the 2006 Peak Oil and Community Solutions conference in Yellow Springs, Ohio, and on others that emerged in conversation with Pat Murphy of Community Service and Julian Darley of the Post Carbon Institute.)





A Letter from the garden.

19 02 2014

Another inspirational guest post from my friend the potter, Steve Harrison……  Self sufficiency at its best.
Steve Harrison

Steve Harrison

The heat wave continues. It continues not to rain. The tomatoes continue to ripen and get sunburnt. The cucumbers continue to die off in the heat and the dry.  The corn continues to shrivel and desiccate. Some plants handle the dry and the heat better than others. Clearly cucumbers have a strict upper limit past which they just die! No room to negotiate. They curl-up, shrivel and turn to dried paper over night. Watering twice a day didn’t help. Perhaps we might have to use shade cloth during the summer months over these sensitive plants in the future if our local climate continues to heat up and dry out like this. Global warming – what global warming? We have tried to prepare ourselves as well as we can. We have dug 4 dams over the years to collect all the ground water that passes our boundaries, some more effective than others. We usually have enough water in the dams to provide us with irrigation water for the gardens and orchards to get us through the summer heat.

There have been years when I had to pump all the remaining water in the lowest dams up to the higher ones to reduce the water surface area and reduce evaporation.
I disconnected the petrol powered fire-fighting pump from the pottery system and carried it into the dried out dam floor, then ran a temporary poly-pipe line up the dam wall and over to the next dam, concentrating all the water up there. I repeated this 3 times until all the water was concentrated from the other three dams into the smallest dam. This provided us with enough water to keep plants alive for another 2 to 3 weeks longer in the summer. On two occasions we have run out of water in the dams altogether, having pumped them all down to mud. We said good bye to all our fruit trees and let them wither. Fortunately for us it was only another few weeks before it rained again and nearly all the trees survived. Only the oldest and weakest died. As in life.
We collect all our own drinking water in water tanks, from the rain that falls on our roofs. There have been times when we got so low in reserves that we only had a few weeks of drinking water left, and as it was from the bottom of the last tank, it was getting a bit murky with sediment. We had to ask a group of potters that planned to visit, if they wouldn’t mind bringing their own drinking water with them. It is possible to buy drinking water and get it delivered in a tanker truck. We have never got that low that we have been forced to buy drinking water. We’ve always managed on our own. When we came here, with virtually no money, we bought some second hand water tanks that were very cheap because they were old, and old water tanks don’t like to be moved. These old rusty tin tanks slowly corroded away with age, however, as we settled in over the years and started to be able to save some money, we were able to replace these old water tanks with new ones, one at a time as they slowly turned to rust. I became quite a dab hand at getting inside the old tanks and either cementing them up to extend their life span, or later, using silicon rubber to fill small holes. Of course patching-up old water tanks rarely works, it just gives you a few more leaky years. Because as we all know, rust never sleeps.
Eventually, after 20 years we saved up enough to get a ‘cast-on-site’ concrete tank built by an itinerant tank maker who was passing through the area, several of us in the village put our names down. We all lived to regret it. He dudded all of us in different ways. He acquired the nick-name of ‘Tank-Boy’ from one of the locals. Tank-boy never worked when you were watching, he’d turn up, always late, and if I was home working in the kiln factory where I could see him, he’d make some excuse to leave again. I don’t know where he went, perhaps to other jobs, where there was no-one at home. He was completely shonkey. He worked in chaos with rubbish all around him. He had to borrow my spanners to tighten up the bolts on his metal form-work. On the day of the big concrete casting, there still wasn’t any steel reo mesh in the bottom of the tank. When I came home from working at the Art School all day, the tank was cast. I suspect that my tank has no reinforcing mesh in it’s base. When it was all finished and he’d gone with his cheque. I finally got to look inside to find that the concrete was so badly cast, that there was steel mesh showing on the inside surface. It would soon rust out and crack the tank apart if left, so I had to climb inside and re-render the holes and patches with a special concrete primer and then render the surface with cement. 2 days of work. The final insult came when I found that he hadn’t fitted the tap into the tank properly, just cemented it onto the outside. As soon as the tank started to fill up with rain water, the tap just “popped” off. I had to get inside again and chisel out a proper hole through the wall of the tank and then fit a 2″ threaded brass pipe through the wall with flanges and sealant on both ends and screw it up tight. Then I fitted my own 2″ tap to the outlet. This part is the only part of the tank that is well done and is still working well 20 years later. The concrete on the other hand is full of cracks and ‘weep’ lines. The concrete roof in particular is in shocking state of cracks.
My friend Dave who runs a truck with a ‘Palfinger’ hydraulic crane and moves all my kilns for me, plus other jobs like stretching orchard netting over garden frames, had a tank built by the same guy, a year or so later, west of Mittagong. Dave came home to find the plastic down pipes missing from the guttering on his shed. Tank boy had sawn them off to make support pillars inside the tank that he was casting for Dave. We compared notes and it turned out to be the very same guy. Quite a strange man.
The time for having fun and making pots is over for a while now. I have to find some paying work, so it’s back into the factory/toy-shop to make some kilns to earn some money.

One kiln finished and ready to deliver with another being welded prior to galvanising.




As it’s February now we are approaching the end of Summer. Everything is ripening and we are very busy in the kitchen in the evenings. The kitchen echoes to the sound of the fermenter ‘blurping’ away as it converts our grapes into wine. I took the afternoon off from kiln building and stainless steel sheet-metal work to harvest half of our shiraz crop. This year the vintage is quite early. In past years the shiraz was vintaged in March, but with global warming, everything has moved forward a month, more or less in line with all our other fruit crops. Since the early seventies when we first moved here ripening has occurred earlier and earlier, and it snows less and less. It hasn’t snowed here in Balmoral for years now and it must be at least 5 years since the Hume Highway was blocked by a sudden snow fall. The shiraz aren’t fully ripe yet, not as ripe as I’d like them to be, but the black birds, wattle birds and the friar birds have found them and more importantly, have found that they can just squeeze through the 65mm hex mesh ‘chook’ wire that encloses the garden. We will need to re-wire the garden completely with smaller mesh, if we are to keep them out in the future. I only want the little insect eating birds in the garden, not the larger fruit eaters. I suppose that we are lucky that it has taken the birds 15 years to work out that they can get into the garden and help themselves. I plan to re-clad the garden walls with 30 mm hex mesh in the future, if fact, as soon as I have the time and money. I already have a 50 metre roll of white plastic orchard netting left over in the shed from when we netted the vineyard 20 years ago. This is enough to cover the top. I have kept it wrapped up in black plastic up in the barn loft, so that it wouldn’t deteriorate from ultraviolet exposure.






If only I’d known all this when I started!  I could have saved myself a lot of time, effort, loss, angst and money. In my experience of life. I start out knowing nothing and learn as I go, usually by observation and then by asking questions. Most people respond well to genuine enquiries, but there are a few stupid people who think that everyone should know what they already know and respond in a Neanderthal sort of way. I can do without them. I don’t think that they know as much as they think. They say that they don’t suffer fools gladly, but all of us are fools until we get ourselves educated and as there is always something to learn, I’m a perpetual fool. Even experts are fools in another field. There was one particular shop keeper in Bowral that I’m thinking of! The Neanderthals prove themselves redundant in the long run. Mademoiselle Fifi and I have learnt to live our lives, by living it, on the job as it were, from trial and error –  A lot of error actually, but we persist, and good-will always shines through and it’s been mostly fun. A complex mixture of hard work, fun and the emotional rewards and comforts of that hard work!

IMG_0150 IMG_0149(1)

This year we are experimenting with whole bunch maceration for the shiraz vintage. I have picked the grapes a little early, before the birds eat them all. They could be sweeter, but never mind. In a perfect world I’d wait another week or possibly two, but the wildlife won’t allow that. I have two fermenters working. One with and one with-out French and American, lightly toasted oak shavings in the must. I’m trying whole bunch maceration again this year, I have enjoyed a few very nice wines made by this method, that some of my friends and associates have either made themselves or given to me as presents. The product can be quite tannic from the extended close infusion of the tannins from the skins, pips and stalks in the vat. This is not a bad thing. But takes time to soften out. Just about all red wines. Well, actually, all quality red wines, are made by extended contact with the grape skins. The better wine makers who want the best results for their wines also perform a ritual, called ‘plunging the cap’. No, it’s not a ritual humiliation performed on youngsters in british private schools. It’s a way of getting the maximum contact with the grape skins with the fermenting juice. All the colour in red grapes is in the skins. The juice is clear, hence champagne, a white wine, being made from red Pinot noir grapes as well as chardonnay grapes.
With prolonged contact of the skins and sugars, the yeast slowly converts the sugars in the juice to alcohol. The alcohol is the active ingredient that dissolves the anthocyanins that produce the red colour. I’ve read that the red is good for me. I certainly hope so. I like to think so, just as I like to drink it. I won’t know for another year or so whether this experiment has worked well enough or not. It has become quite trendy recently to ferment wines on wild yeasts. I have decided that there is enough at risk in making our years harvest of shiraz grapes into wine without adding the uncertainty of possibly loosing it all to a rogue wild yeast. So I have taken the precaution of using a known, reliable, cultivated red wine, shiraz, yeast.


After all these last few weeks of dry heat, it has finally rained. We have 32 mm. of slow soaking rain and it is really nice. All the plants are responding well and shooting out new growth.
Mmselle Fifi is out and about in the garden with her baskets harvesting whatever is ready to be eaten on the day, any excess is cooked, concentrated and otherwise preserved in some way for later use.


Yesterday, she was out harvesting some of the red ‘isabella’ grapes. Perfect for making dark grape juice. So far she has pasteurised and preserved 14 litres of the delicious stuff, so fruity, fragrant and sweet. A perfect drink for a hot summers day or any time really. So far she is about half way through the crop. A crop that we otherwise wouldn’t have got if we hadn’t put it entirely under netting a month or two ago.

with love from Syrah and Isabella