Feeding a growing world population has been a serious concern for decades, but today there are new causes for alarm. Floods, heat waves and other weather extremes are making agriculture increasingly precarious, especially in the Global South.
Amid these challenges, some organizations are renewing calls for a second Green Revolution, echoing the introduction in the 1960s and 1970s of supposedly high-yielding varieties of wheat and rice into developing countries, along with synthetic fertilizers and pesticides. Those efforts centered on India and other Asian countries; today, advocates focus on sub-Saharan Africa, where the original Green Revolution regime never took hold.
But anyone concerned with food production should be careful what they wish for. In recent years, a wave of new analysis has spurred a critical rethinking of what Green Revolution-style farming really means for food supplies and self-sufficiency.
There was a consensus in the 1960s among development officials and the public that an overpopulated Earth was heading toward catastrophe. Paul Ehrlich’s 1968 bestseller, “The Population Bomb,” famously predicted that nothing could stop “hundreds of millions” from starving in the 1970s.
India was the global poster child for this looming Malthusian disaster: Its population was booming, drought was ravaging its countryside and its imports of American wheat were climbing to levels that alarmed government officials in India and the U.S.
Then, in 1967, India began distributing new wheat varieties bred by Rockefeller Foundation plant biologist Norman Borlaug, along with high doses of chemical fertilizer. After famine failed to materialize, observers credited the new farming strategy with enabling India to feed itself.
The standard legend of India’s Green Revolution centers on two propositions. First, India faced a food crisis, with farms mired in tradition and unable to feed an exploding population; and second, Borlaug’s wheat seeds led to record harvests from 1968 on, replacing import dependence with food self-sufficiency.
Meanwhile, the government urged Indian farmers to grow nonfood export crops to earn foreign currency. They switched millions of acres from rice to jute production, and by the mid-1960s India was exporting agricultural products.
Borlaug’s miracle seeds were not inherently more productive than many Indian wheat varieties. Rather, they just responded more effectively to high doses of chemical fertilizer. But while India had abundant manure from its cows, it produced almost no chemical fertilizer. It had to start spending heavily to import and subsidize fertilizer.
India did see a wheat boom after 1967, but there is evidence that this expensive new input-intensive approach was not the main cause. Rather, the Indian government established a new policy of paying higher prices for wheat. Unsurprisingly, Indian farmers planted more wheat and less of other crops.
Once India’s 1965-67 drought ended and the Green Revolution began, wheat production sped up, while production trends in other crops like rice, maize and pulses slowed down. Net food grain production, which was much more crucial than wheat production alone, actually resumed at the same growth rate as before.
According to data from Indian economic and agricultural organizations, on the eve of the Green Revolution in 1965, Indian farmers needed 17 pounds (8 kilograms) of fertilizer to grow an average ton of food. By 1980, it took 96 pounds (44 kilograms). So, India replaced imports of wheat, which were virtually free food aid, with imports of fossil fuel-based fertilizer, paid for with precious international currency.
Today, India remains the world’s second-highest fertilizer importer, spending US$17.3 billion in 2022. Perversely, Green Revolution boosters call this extreme and expensive dependence “self-sufficiency.”
The toll of ‘green’ pollution
Recent research shows that the environmental costs of the Green Revolution are as severe as its economic impacts. One reason is that fertilizer use is astonishingly wasteful. Globally, only 17% of what is applied is taken up by plants and ultimately consumed as food. Most of the rest washes into waterways, where it creates algae blooms and dead zones that smother aquatic life. Producing and using fertilizer also generates copious greenhouse gases that contribute to climate change.
The Green Revolution still has many boosters today, especially among biotech companies that are eager to draw parallels between genetically engineered crops and Borlaug’s seeds. I agree that it offers important lessons about how to move forward with food production, but actual data tells a distinctly different story from the standard narrative. In my view, there are many ways to pursue less input-intensive agriculture that will be more sustainable in a world with an increasingly erratic climate.
Glenn Davis Stone receives funding from the National Science Foundation and the John Simon Guggenheim Memorial Foundation.