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LAND RESOURCES: ON THE EDGE OF THE MALTHUSIAN PRECIPICE?

A briefing document prepared for the Royal Society and

Association of British Science Writers

by Mike Holderness

May 1997

There are two ways of looking at the Malthusian precipice: as an edge over which we can rush like the Gadarene Swine⁽¹⁾ into the abyss; or as the heights which we are climbing, rather successfully so far. From the introduction by the Chair^(2).

SUMMARY

How hungry will our children be?

How many people will there be in the world by, say, 2050?

How much food will they be able to grow, for how much longer after that and at what cost?

In 1798 the English clergyman Thomas Malthus published his Essay on the Principle of Population⁽²⁰⁾. He noted that population rises geometrically. That is, if 10 people occupy a tiny island and each generation has twice as many members as the last, succeeding generations will have 20, 40, 80, 160, 320 ... members. He suggested that food production can only rise arithmetically: each generation may have the capacity to feed 100, 120, 140, 160, 180, 200 ... people. The fifth generation of our islanders reach the "Malthusian Precipice".

"The power of population is so superior to the power in the earth to produce subsistence for man," Malthus concluded, "that premature death must in some shape or other visit the human race."

Almost all who study population growth are now convinced that Malthus was wrong. In 1998 the earth's population will pass six billion⁽¹⁸⁾. In 2030 there will be at least eight or nine billion.

But the world's population will stabilise - our maximum numbers are likely to be 10 billion, or 12 billion, or a few more.

The Big Question then is: can that many people feed themselves? More difficult: can they do it without degrading the soil for the generations to come, or destroying other species? Will there be any wild places left?

In order to answer the Big Question, we need to know:

• How many people there will be if food supply doesn’t restrict the number

• How much food they will be able to grow; this in turn depends on many things, including:

• How much land is available for food production

• How much water can be delivered to that land

• The type and condition of the soil on that land

• How much nutrient - "plant food" - is available

• How efficiently crops will be able to use those nutrients, and what possible future crop varieties are likely to be able to do

The answers to such questions depend on each other, and on yet other questions. "How much land is available" is a question of politics and economics as much as of geography. "How much nutrient is available" depends on the state of the soil and on the supply of water and on the capacity of possible future crop varieties to extract nourishment.

This briefing is divided into nine sections for easy reference. The real world clearly is not that neat: everything interacts. There is not space to list all the connections - please read the entire briefing!

Malthus' projections, as an example, were wrong because he reckoned without two things.

One is that over the last half century, through plant breeding, irrigation and use of fertilisers and pesticides - the so-called "green revolution" - humanity has managed a geometric increase in food production.

The second, which offers hope that our species may reduce its size of geometric increase, is the so-called "demographic transition". Crudely, when parents no longer need large numbers of children to work the land, they reduce the number of children they have. (There may be intense arguments about why demographic transitions happen; but there is no dispute that they do happen.)

It is not surprising, then, that forecasts can be spectacularly wrong.

We simply do not have the information to answer many of the questions accurately. Dr Webster⁽¹¹⁾ pointed out that it is not good enough to look at soil type and quality on a national level; we would need a field-by-field survey of the whole world to produce accurate answers.

What forecasts can do is set upper and lower limits, provided nothing unexpected happens. It is not possible (barring meteorite strikes and the like) that the world's population in 2050 will be less than six billion; neither is it possible (barring a bizarre fertility-enhancing epidemic) for it to be much over 12 billion.

1. POPULATION GROWTH

Any mention of population invokes a horde of political demons: some Westerners' fears of teeming Third World hordes versus burning resentment of people for whom eating too much is a problem; the need for women to have choices over having children versus allegations of coerced abortion and anathemas on contraception ... and so on.

Demographers - the people who predict future population sizes - now find themselves above these frays.

Dr Heilig⁽³⁾ reported that the lowest estimates for the world's population in 2050 are seven billion, the expected number is about nine billion, and the upper range 11 billion. The opinion that the lower range is likely is "not shared by many" - which is polite science-speak for "off the wall".

Discussion of population growth often - perhaps because of Malthus' continuing influence - focuses on rates of growth. Percentages do not eat. People do.

The number of additional people on the earth each year is already falling - Dr Heilig gives it as 85 million in the early 1990s, and 80 million a year now. The total population will probably level out at 12 billion or so.

This will happen regardless of anything that politicians or pundits do or say. Even wars and famines will have relatively little impact. The numbers are determined by the sheer number of children and teenagers alive now.

(In other words, the strongest constraint on the number of babies born is the number of mothers: and most of those who will be mothers in the next two decades have already been born. Medical advances which prolong the old age of the rich have a negligible impact. Advances which increase the numbers of children who survive to become parents have and have had a huge impact.)

A vital factor in achieving a transition in the 20th Century is educating girls beyond the 6th grade. South-East Asia, for example, seems to be in transition now - earlier than expected by some, and invalidating some of the more extreme population projections of the 1970s.

2. LAND

Dr G. Fischer⁽³⁾ added that most of the increase in world population will happen between now and 2030. We have extraordinarily little time to develop the land sustainably.

How much land is there? Taking a broad-brush approach, Dr Fischer concludes that there are 1.6 billion hectares (Gha⁽¹⁹⁾) of land which have some potential for cultivation and are not currently used. Two-thirds of that is forest and wetland, the Amazon Basin for example; 550 Mha have, "more or less", the ability to support cultivation.

But this potential new land is not in the same place as the people are: 45% of it is in Central and South America and only 8% in Asia. By 2050 the population of Asia will have passed the current population of the world.

The great bulk of the extra food required, therefore, will have to come from greater yields on already-farmed land. But in some areas - notably parts of Africa - productivity is declining as soil degrades or erodes.

3. WHO DECIDES? ECONOMICS FOR SMALL FARMERS

In the areas with the greatest population increases, how food is grown is decided almost entirely by small farmers. They rarely have access to capital; loans, if available, are at extortionate rates.

Schemes for sustainable farming which require any interruption of crop supply or income are therefore futile. Someone who owns only clothes, cooking pots and seed-corn is not going to plant nut trees and then starve for ten years waiting for a crop.

Professor Gregory⁽¹³⁾ says that farmers in Australia, too, forcefully point out that what they're most interested in is staying in business in the bad years; if they didn't do that, they wouldn't be able to take advantage of the good years.

The very poorest people usually farm the most marginal land - that which is most vulnerable to erosion and other forms of degradation. Dr Barbier⁽⁴⁾ points out that for them it is often rational, in economists' terms, to farm in ways which maximise short-term returns.

Similarly, in places such as the Amazon where unfarmed land exists, poverty is a major driver of deforestation. In some cases - Dr Barbier mentioned ranching in South America and palm oil plantations in South-East Asia - government policies on pricing or subsidised credit encourage deforestation, which encourages land erosion.

Where security of land-tenure is poor, whoever gets to unfarmed land first has effective control. People farming already-cultivated land have no incentive at all to do things like tree-planting (see 4.3) if they're likely to lose the use of the land at short notice. In some areas, almost all food production is by women - but any trees planted would belong to their men, or to their landlords.

Effective measures to conserve soil and forest must be aimed directly at small farmers on marginal land. Getting affordable credit to them would help a lot. Spreading information on sustainable farming methods which increase productivity - when many farmers are knowledgeable, but may also be "educated illiterates" - is vital. Time is short.

4. LAND AND CROP PRODUCTIVITY

How much food you can grow on a hectare of land depends fundamentally on (in no particular order):

• The amount of sunshine and length of the growing season - which we may be affecting on the longer timescale of global warming, but cannot alter at will;

• The amounts of nutrients available, from the soil and from fertilisers, and the absence of plant poisons like excess salt in the soil;

• The amount of water available to plants, from rain or from irrigation; and

• The performance characteristics of the crop varieties being grown.

A frequently cited principle is that the rate of plant growth is controlled by the resource that is most limiting. If there is plenty of water but the soil is poor, nutrients are said to be limiting. The same goes for individual nutrients: if there is plenty of water and nitrogen but little phosphorus, phosphorus is limiting. If there's plenty of everything else, elements which are required in tiny quantities, like zinc, may be limiting.

Water supply affects the availability and accessibility of nutrients. The condition of the soil affects both. Crudely, if the soil is baked to concrete, it may be chock-full of nutrients but they will be locked up, and water will run straight off.

Soil, water supply and yields have traditionally been studied by three very different scientific disciplines: soil scientists, hydrologists and plant physiologists who too rarely, some said, follow each others' work. But, as Dr Wallace⁽⁹⁾ said in discussion, "The plants are not aware that two [sic] disciplines are arguing about them".

4.1 CROP EFFICIENCY

From the CSIRO Division of Plant Industry in Canberra, Dr Evans⁽⁵⁾ described the enormous increases in crop yields achieved by plant breeding (alongside soil and plant management). Much of this is due to short-stemmed or "dwarf" rice and wheat varieties, which can utilise large quantities of nitrogen fertiliser. Traditional grains, presented with that much food, get top-heavy, fall over and die. They also use more of the nutrient for stems and leaves than do the dwarves.

From time to time someone will notice a falling-off in yield increases and conclude that the End is Nigh. Graphs of many processes of change start out with an upwards curve which could be the start of an "exponential" curve, representing a continuous percentage increase year on year, as below:

Few processes continue to follow this form of growth for ever, many following, instead, an S-shaped or "sigmoid" curve ("sigma" is Greek for "s").

Note that the early parts of the curves - the first 40 years in these arbitrary examples - are very similar. It is thus extremely difficult to tell when a process is making the transition. It is conversely very easy to "cry wolf" in either sense: "population is increasing exponentially!" or "food production is trailing off!". Dr Evans calls this latter "sigmoid fraud".

Further breeding can produce even more extreme dwarf varieties. A number of ways in which plants might use sunlight more efficiently are worth exploring, though the fact that we start from the results of more than 5 000 years of selective breeding makes further staggering increases unlikely. Possibly the biggest opportunity for increasing grain yields is in producing varieties which are more precisely adapted to local conditions.

Dr Sivakumar⁽⁶⁾ presented a broad-brush approach to defining such conditions - the Agro-Ecological Zonation of the United Nations Food and Agriculture Organisation (FAO).

4.2 WATER

It is, however, no good breeding efficient plants if they die of thirst. Dr Falkenmark⁽⁸⁾ presented what she called "back-of-an-envelope calculations" on the world's effective supply of fresh water.

Each person needs a minimum of 900 tons of fresh water a year, almost all of it for growing food. It is extremely expensive to capture and use more than 20% of the water which falls as rain.

On this basis, North Africa is running out of water about now. Northern Egypt already achieves more than 100% utilisation of water from the Nile, by re-cycling. And 26% of the water now used by Egypt is "virtual" - it is used in fields in other countries, from which Egypt imports food.

The uncertainties in Dr Falkenmark's projections of world water needs in 2025 are as large as the amount of water used today. But she concludes that very probably fresh-water supply will be a serious problem for more than half the world's people by 2050.

Dr Jim Wallace of the Centre for Ecology and Hydrology⁽⁹⁾, by contrast, points out that a million tons of fresh water exists on Earth for each person. (A lot of it, though, is in inconvenient places like Siberia.)

Many things can be done to increase how efficiently water is used in crop fields. Radical changes in crops are unlikely to arrive in time, even with genetic engineering. Almost all the other measures are very low-tech and concerned with keeping the water which falls as rain where the plants can reach it.

"Mulching" with dead plant matter decreases evaporation from the soil. Terracing reduces run-off. Growing plants like clover underneath grain crops - often called a "green mulch" - also reduces run-off. Green mulches of, for example, clover and bean-family plants, "fix" nitrogen from the air - convert it to a form which plants can use - and thus fertilise the soil at the same time.

4.3 SOIL CONSERVATION AND NUTRIENT RESTORATION

Experiments in Kenya show that planting rows of trees, with "alleys" of grain or beans between, prevents water run-off equivalent to 70 mm of rain a year.

The goal of this "agroforestry" was described by Dr Sanchez⁽¹⁰⁾ as "successfully manag[ing] competition for light, water and nutrients between trees and other crops". In some places farmers can grow trees which produce valuable crops. Everywhere, they will provide fuel.

Some such conservation measures are urgent. Dr Sanchez estimated that Sub-Saharan Africa is losing 9.3 million tons (Mt) of crop nutrients a year through soil erosion and degradation. The region imports 1.7 Mt a year of fertiliser, so at most one-fifth of the annual loss is made up.

Dr Sanchez also described other work on restoring soil fertility. Professor Syers⁽¹⁵⁾ predicts that investment in such restoration should have a rapid pay-back.

Where soil lacks nitrogen, both Dr Sanchez and Professor Syers propose mostly organic means to replenish it. (Nitrogen fertiliser is beyond the means of many African farmers.) Trees of the bean (legume) family can convert or "fix" nitrogen from the air into forms which plants can use - at a rate of 50 to 150 kg per ha per year. Recent work has also shown that their deep roots can get at nitrogen which cereal roots cannot reach. In some areas, however, this deep nitrogen may have been washed into the ground and wasted in the past; no-one knows whether it is a sustainable source.

Many farmers in Africa cannot afford manufactured fertiliser because of the effects of "structural readjustment" policies. Thousands are growing Tithonia shrubs, known as Mexican Sunflowers, in their hedges and using the foliage to mulch their fields. Apart from the other benefits of mulching, this allows the farmers to restore phosphorus-deficient soils using ground-up phosphate-bearing rock. This source of phosphate, Dr Sanchez says, is plentiful in Africa - enough for a century or more. Rock phosphate as it comes out of the ground is useful to crops only when it is applied with a mulch. In the industrialised countries it is chemically converted to super-phosphate from an energy-intensive and expensive process. Replenishing phosphorus can increase annual maize yields from 1 t/ha to 4 t/ha.

Professor Vlek⁽¹²⁾ and Dr Kuehne reinforced the idea that the key to soil fertility is a mixture of fertiliser and organic matter. Though mulches and agroforestry sound very "organic", not one speaker was opposed to inorganic fertilisers or to pesticides and several stated that without them we would starve.

Professor Vlek was sceptical, though, of the prospects. Producing enough food for projected populations of the developing world in 2020, for example, would mean supplying 185 Mt of added plant nutrients (nitrogen, phosphorous and potassium fertiliser) a year, compared with 62 Mt in 1990. To restore levels of plant nutrients in the soil, instead of maintaining it in its present developed state, would mean adding not 185 Mt but 251 Mt a year in 2020.

The explosive growth of cities has a major effect on plant nutrient budgets. A proportion of the nutrients absorbed by plants ends up in food, which is "exported" from the countryside to the city. It ends up in sewage, much of which finds its way to the sea. Recycling sewage as fertiliser is impossibly difficult to organise economically (it may happen in China, by decree). Worse, city sewage is very often contaminated with heavy metals from light industry. But recycling must in the long run be achieved.

Still more nutrients are exported to cities in firewood.

"Soil scientists tend to believe that soil is important," noted soil scientist Professor Gregory⁽¹³⁾. "Are all soils important," he asked, "and are they important all of the time?"

Soil scientists have been rather successful in wiping out the differences, at least for farmers who can afford fertiliser and irrigation. But the old notion of a sack of fertiliser printed with a recommended dose won't do any more.

All the measures proposed for increasing and sustaining food production depend on fine-tuning agriculture almost hectare by hectare. There will simply never be enough soil scientists or meteorologists to make detailed recommendations on that scale. Everything depends on the farmers, and on the information they have to base decisions on. Professor Gregory speculates about "a sort of Sub-Saharan Archers" as a way of getting useful information out. The BBC radio soap opera "The Archers", set in the farming community of Ambridge, was launched on 1 January 1951 at the behest of the Ministry of Agriculture, as a means of informing and educating farmers in Britain.

A lot of that information will be fairly familiar to farmers, or their parents. Traditional small fields in England reflected the scale of variation of soil and water supply. Agroforestry is very similar to the forest gardens of Amazonia and New Guinea.

5. WHAT SHALL WE EAT?

Whether our children can feed themselves depends partly on what they expect to feed themselves.

On the one hand, increased prosperity seems to be essential to the "demographic transition", and hence to achieving a stable population.

On the other, it massively increases demand for food production. Dr de Vries⁽⁷⁾ calculates that a purely vegetarian diet requires 490 kg of grain equivalent per person per year. A diet with a moderate amount of meat requires 860 kg/year; and an affluent, US-style diet 1500 kg/year. The reason is that it takes a lot of vegetable crops - primary food production - to feed animals for meat. Already, in South-East Asia increased affluence is leading to much higher demand for primary food production.

The growth of population alone means that primary food production must increase by a factor of about two. Changes in expectations - burgers for all! - could mean that there was demand for six times as much primary food in 2050 as is grown now.

The chances of such a sixfold increase in primary food production being achieved are, in scientists’ language, "vanishingly small". In lay terms "… and pigs might fly". Few of our children will have a high-meat diet.

6. NOT BY BREAD ALONE ...

Dr de Vries also pointed out that there will be massive competition for land. As the remaining oil becomes more and more expensive to extract, there will be pressure to grow crops for fuel and not for food. You can run a car from 2 ha of well managed land in many parts of the world - or you can feed a couple of families.

Fuel already competes with food. In parts of Ethiopia, Dr Sanchez⁽¹⁰⁾ said, almost every organic thing grown goes for fuel - not even for food and animal fodder. And Professor Vlek⁽¹²⁾ observed that it's not easy to convince farmers in the tropics to leave straw in the fields as mulch to conserve water, if they have to build their houses from it and use it as fuel.

Economic development also competes with food production. One participant noted that in her country almost all the fertile land is in flat valley-bottoms; and this is where US companies are building their sprawling, low-rise microelectronics factories. Another predicted that by 2050 the Philippines may have no Grade A land left.

7. LAND CONFLICT: HOW MUCH MAY WE USE?

Dr Tinker⁽¹⁶⁾ quoted US computer millionaire Ross Perot as saying "If our children are hungry we will cut every last tree. And we will not worry about the Spotted Owls, except maybe to eat them."

Expanding food production competes for land with other species and cultures.

He asked "Why are people so excited about the destruction of the tropical forest?" He gave four reasons:

• Destruction of tropical forests implies a massive release of carbon dioxide into the atmosphere, increasing the risk of global warming;

• Felling the forests would severely change their local climates over a much shorter time-scale;

• The forests contain a very significant portion of the world's biodiversity; and

• Aesthetic considerations cannot be ignored.

(To that list this author would add the importance of the people who live in the forests and of allowing their unique human cultures to enter the 21st Century on their own terms.)

If current trends continue, nearly the entire rainforest of Zaire could have been felled by 2050. The tropical forest of South-East Asia may be largely lost by 2030. The position of "montane" (upland) forests is, however, worse than that of the rainforest; these are disappearing at 1.1% per year, compared to 0.6% per year for tropical forest in 1981-1990.

Dr Tinker is optimistic about farmers dealing with erosion on their own land. But it is in no-one's direct interest to deal with off-site effects - and so he is pessimistic about that. If you can put a price on these effects, something will be done about them.

Reafforestation and agroforestry, for example, have their off-site costs. They are designed to reduce run-off of rain and so to maximise the amount of water which passes through plants and into the air. That means less water for everyone downstream.

8. THE SHRINKING WORLD: THE FRONTIER IS CLOSED

The liveliest session of an engrossing meeting was the half hour at the end devoted to general discussion. The major theme was one of increasing international interdependence.

It seems unlikely that China and the Punjab will in future achieve the same yield increases that they managed in the past 40 years. So will farmers in the Punjab get fed up with wheat and rice, because they're not making enough money? Will they diversify into high-value crops because the Indian middle class demands them - and is there then the possibility of Europe and the US becoming the grain-baskets of the world?

One participant predicted that "We in Africa will buy maize from Indiana, where they complain about 9 t/ha yields, and we'll sell you cures for prostate cancer and other high-value crops".

This notion depends, as Dr Bie⁽¹⁷⁾ pointed out, on transport infrastructure which does not exist - and which it is hard to see being built in the next 20-30 years.

9. WHAT, THEN, IS TO BE DONE?

More research is needed, to gain a better understanding of how food supply can be maximised with a minimum input of expensive resources and a minimum degradation of the soil and environment.

But the matter of anything being done about that research is intensely political. The issue is not so much food supply, as poverty. "As scientists," one concluded, "we have a political and moral responsibility to make politicians aware of the issue".

Dr Bie, leaving the Food and Agriculture Organisation that month, noted that: Governments sign many things. The Universal Declaration of Human Rights includes food as a human right and there are 840 million people who are food-insecure. So some governments have not been doing their job. The World Food Summit made a commitment to halving the number by 2015; Fidel Castro said this was in a way disgraceful and that they should aim to feed everyone.

Grand-scale projects alone will not fulfil that aim.

It seems over-optimistic, for example, to assume that the next 20-25 years will see enough economic development to provide farmers everywhere with fertilisers, credits to buy them and roads to deliver them. Such vast projects are simply not completed in that sort of time - unless, perhaps, they are awarded the overriding priority that the US and Soviet nuclear weapons projects had. To do so would mean confronting another concern which was fashionable in the 1960s, is urgent now and was outside the remit of the meeting: the finite nature of fossil fuel reserves. (A similar meeting on energy is indicated.)

Governments make less policy than they think they do, and the people who get soil on their hands make much more. Both scientific research and practical support for food production must be done in collaboration with these small farmers, and must help them make the best use of whatever resources they have - in many cases, little more than their own ingenuity.

Professor Gregory summed up: "By 2050 there will be eight billion people in the world. Those people will feed themselves - but only if we do the necessary research to increase crop production." Water is the worrying question mark over that prediction. "They will", he continued, "do so mostly using improved technology. The population will stabilise - one way or another, unless it declines because they fail to feed themselves. And what will be the cost to the global environment?"

"Then we're left," Professor Gregory concluded, "with a very considerable management problem, to maintain that level of food production. In a sense, what we're talking about now is the shape of agriculture in 2075."

1. Luke 8:26-33

 

2. Professor D.J. Greenland F.R.S.

Low Wood

The Street

South Stoke tel: 01491 873259

Reading RG8 0JS

 

3. Dr G.K. Heilig and Dr G. Fischer

International Institute of Applied Systems Analysis

Schlossplatz 1

A-2361 LAXENBURG tel: 00 43 2236 807

Austria fax: 00 43 2236 71313

 

4. Dr E.B. Barbier

Dept of Economics and Environmental Management

University of York

Heslington tel: 01904 434060

York YO1 5DD fax: 01904 432998

 

5. Dr L.T. Evans, A.O., F.R.S.

CSIRO Division of Plant Industry

GPO Box 1600

CANBERRA, ACT 2601 tel: 00 61 6 246 5460

Australia fax: 00 61 6 246 5000

 

6. Dr M.V.K. Sivakumar

Agricultural Meteorology Division

World Meteorological Organization

41, avenue Giuseppe-Motta

Case postale no. 2300

CH-1211, GENEVA 2 tel: 00 41 22 730 8380

Switzerland fax: 00 41 22 734 8031

 

7. Dr F.W.T. Penning de Vries

Research Institute for Agrobiology and Soil Fertility (AB-DLO)

AB-DLO Wageningen

Centre de Born, PO Box 14

NL-6700 AA WAGENINGEN tel: 00 31 317 475 960

The Netherlands fax: 00 31 317 423 110

 

8. Dr M. Falkenmark

Swedish Natural Science Research Council

Box 7142

S-10387 STOCKHOLM tel: 00 46 8 454 4200

Sweden fax 00 46 8 454 4250

 

9. Dr J.S. Wallace

Institute of Hydrology

Maclean Building

Crowmarsh Gifford

WALLINGFORD tel: 01491 838800

Oxon OX10 8BB fax: 01491 692430

 

10. Dr P.A. Sanchez

Director

ICRAF

PO Box 30677

NAIROBI tel: 00 254 252 1003

Kenya fax: 00 254 252 0023

 

11. Dr R. Webster

Rothamsted Experimental Station

HARPENDEN tel: 01582 763133

Herts AL5 2JQ fax: 01582 760981

 

12. Dr P.L.G. Vlek

Institute of Agronomy and Animal Health

Georg-August-Universitat

Grisebachstrasse 6

D-37077 GOTTINGEN tel: 00 49 551 393751

Germany fax: 00 49 551 393759

 

13. Professor P.J. Gregory

Dept of Soil Science

University of Reading

Whiteknights

PO Box 233 tel: 0118 931 8911

Reading RG6 6DW fax: 0118 931 6666

 

14. Professor R. Lal

School of Natural Resources

The Ohio State University

2021 Coffey Road

COLUMBUS, OH 43210-1085 tel: 00 1 614 292 6446

USA fax: 00 1 614 292 7432

 

15. Professor J.K. Syers

Dept of Agricultural and Environmental Science

The University tel: 0191 2225677

NEWCASTLE UPON TYNE NE1 7RU fax: 0191 2225677

 

16. Dr P.B.H. Tinker

Department of Plant Sciences

University of Oxford

South Parks Road tel: 01865 270000

OXFORD OX1 3RB fax: 01865 275074

 

17. Dr S. Bie

Formerly Director - Research, Training and Extension

Dept of Sustainable Development

c/o Food and Agriculture Organisation

Via Delle Terme di Caracalla

00100 ROME

Italy

 

18. Throughout, "billion" is used in the common sense of one thousand million.

 

19. One hectare (abbreviation: ha) is a square 100m on a side, one-hundredth of one square kilometre or, if you must, 2.47 acres. The prefix G stands for 1 billion; M stands for one million. T for tonnes.

 

 

20. Thomas Malthus, An Essay on the Principle of Population as it affects the future improvement of society with remarks on the speculations of Mr. Godwin, Mr. Condorcet and other writers: London, printed for J. Johnson, in St Paul's Church-Yard, 1798.

 

---

Enquiries to: Ref: PR 22 (97)

Miss Anna Link

Science Promotion Section

The Royal Society

6 Carlton House Terrace

London

SW1Y 5AG

Direct line: 0171 451 2581 13 May 1997

On 4 and 5 December 1996, the Royal Society held a scientific meeting entitled "Land Resources: on the edge of the Malthusian precipice?" This document was prepared afterwards to summarise key issues raised by the speakers and to provide a list of helpful contacts for future reference.

The document does not necessarily constitute the views of the Royal Society or of the Association of British Science Writers, and views expressed in it should not be attributed either to the Royal Society or to the Association. Copyright 1997 is held jointly by the Royal Society and the author. Moral rights are asserted. A license is hereby granted: (1) to all, to make copies for personal non-profit use only; and (2) to Fellows of the Royal Society, the Association of British Science Writers, the Medical Journalists' Association, and those receiving the document on paper through the Royal Society's press service, to make extensive quotations without payment and without reference to source. For other uses and to request further printed copies, please contact the Royal Society at the address above.

Copyright ABSW  © 2008  Last update 30 May 2008