State of the Planet

News from the Columbia Climate School

Vertical Farms: From Vision to Reality

Vertical farm designs by Chris Jacobs, Gordon Graff, SOA Architectes

(Updated October 17, 2011)

Dr. Dickson Despommier laughs when  he recalls how crazy people thought he was just a few years ago.  But Despommier, the most passionate proponent of vertical farming—the growing of crops indoors in multi-story urban buildings—is now seeing his vision being realized. He believes vertical farming can help feed the growing global population and undo the environmental damage caused by conventional agriculture.

“Farming has upset more ecological processes than anything else—it’s the most destructive process on earth,” Despommier told me. As of 2008, 37.7 percent of global land and 45 percent of U.S. land was used for agriculture. The encroachment of humans into wild land has resulted in the spread of infectious disease, the loss of biodiversity and the disruption of ecosystems. Over-cultivation and poor soil management has led to the degradation of global agricultural lands. The millions of tons of toxic pesticides used each year contaminate surface waters and groundwater, and endanger wildlife.

Agriculture is responsible for 15 percent of global greenhouse gas emissions, and accounts for one-fifth of U.S. fossil fuel use, mainly to run farm equipment, transport food and produce fertilizer. As excess fertilizer washes into rivers, streams and oceans, it can cause eutrophication: Algae blooms proliferate; when they die, they are consumed by microbes, which use up all the oxygen in the water; the result is a dead zone that kills all aquatic life. As of 2008, there were 405 dead zones around the world.

More than two-thirds of the world’s fresh water is used for agriculture. And around the world, farmers are losing the battle for water for their crops as scarce water resources are increasingly being diverted to expanding cities. As climate change brings warmer temperatures and more droughts, the water crisis will worsen.

To feed the growing and increasingly urban global population of 9 billion expected by 2050, we need to boost food production by 70 percent through higher crop yields and expanded cultivation. The FAO estimates that we will need nearly 300 million more acres of arable land to do this, but most of the remaining arable land lies in developing countries, and many of the available land and water resources are currently providing other important ecosystem functions. Pressing them into service to produce food will upset many more of the planet’s ecosystems.

Dickson Despommier.

In 1999, while exploring the negative impacts of agriculture, Despommier, a professor of environmental health sciences at Columbia University’s Mailman School of Public Health, and 105 graduate students came up with the concept of the vertical farm—a multi-story building growing layers of crops on each floor. Vertical farm crops can be grown using hydroponics, where plants grow in water or a growing medium with nutrients delivered directly to their roots; aeroponics, which uses a mist to deliver nutrients to plant roots; aquaponics, when fish are raised concurrently and their waste is used as nutrients for crops; or even in soil if the building is designed accordingly.

At present, lettuce, leafy greens, herbs, strawberries and cucumbers are the most commonly grown crops in vertical farms, but in theory, corn and wheat could be grown, as well as biofuel crops and plants used to make drugs. Hydroponics use 70 percent less water than conventional agriculture; aeroponics use even less; and all water and nutrients not taken up by the plants are recycled.

LED lights. Photo credit: John Abela

Climate controls and LED lights programmed to deliver the wavelengths of light that plants prefer create optimum growing conditions. Methane generated from restaurant or crop waste can supply energy and heat for vertical farms.

As a balanced mini-ecosystem, the vertical farm has many advantages. A vertically farmed acre can produce the equivalent of 4 to 6 soil-based acres, depending on the crop (for strawberries, 1 vertical farm acre produces the same amount as 30 outdoor acres). Plants can be grown year-round, unaffected by weather conditions such as droughts, floods or pests. Vertically farmed food is safe from contamination  (for example, from e-coli or radiation), and is grown sustainably and organically without the use of fertilizer, pesticides or herbicides.

Fossil fuel use is minimal because there’s no need for farm equipment, transportation of produce into cities, storage or distribution. Unused urban buildings can be revamped as sustainable centers providing healthy food in neighborhoods where fresh produce is scarce, and also creating new job opportunities. In war or disaster zones or refugee camps, modular vertical farms could provide much needed fresh produce. And if vertical farms were implemented on a large scale, we might one day be able to reclaim farmland and restore our soil, forests and ecosystems. Without fertilizer runoff, coastal waters could be revitalized and our fisheries might once again flourish.

Some skeptics have said that the amount of electricity that would be needed to replace sunlight in vertical farms would be prohibitively expensive and unachievable. But Despommier counters that the cost of LED lighting is offset by savings from the elimination of fossil fuel use in fertilizer, transport, storage and distribution, as well as from less spoilage and waste. This, however, remains to be proven, since no one has yet done a life cycle cost comparison between vertical farm-grown crops and those produced conventionally.

Another criticism, no doubt in response to early designs of futuristic vertical farms towering over a city, is that the steep capital investment needed is prohibitive and doesn’t make economic sense. Despommier himself acknowledges that integrating multiple stories of crop growing presents engineering issues that need to be solved. But why do vertical farms have to be in skycrapers?

One year ago, no vertical farms existed. Today the modestly sized vertical farms springing up around the world are proving the skeptics wrong.

Kyoto, Japan’s Nuvege is growing a variety of lettuces in a 30,000-square-foot hydroponic facility with 57,000 square feet of vertical growing space. Amidst fears of radiation contamination from the Fukushima nuclear plant, Nuvege can tout the safety and cleanliness of its crop. Over 70 percent of its produce is already being sold to supermarkets, with 30 percent going to food service clients such as Subway and Disney.

PlantLab in Den Bosch, Holland, is constructing a three-story underground vertical farm that completely eliminates the wave lengths of sunlight that inhibit plant growth. With the latest LED technology, PlantLab can adjust the light composition and intensity to the exact needs of the specific crop. The room temperature, root temperature, humidity, CO2, light intensity, light color, air velocity, irrigation and nutritional value all can be regulated. PlantLab claims it can achieve a yield three times the amount of an average greenhouse’s while using almost 90 percent less water than traditional agriculture.

Growbeds and fish tanks in The Plant. Photo credit: Plant Chicago

In the U.S., a dilapidated 93,500-square-foot former meatpacking facility in Chicago is being transformed into a net-zero aquaponic and hydroponic vertical farm. The Plant will also include an artisanal brewery, kombucha brewery, mushroom farm and bakery. Waste from the food businesses will be used to generate methane in an anaerobic digester, which will produce enough steam and electricity to meet the full energy needs of the facility.

In Seattle, ecological designer Dan Albert and his wife run a 100-square-foot, two-level vertical farm called Civesca (the name is due to change) in a simple warehouse. They will begin selling their aeroponically grown salad greens, mustard greens, and kale to a few local restaurants on Nov. 1.

Purple basil and mizuna growing in Civesca.

Albert gives high praise to his aeroponics technology, created by Ithaca, NY-based AeroFarms. The modular system incorporates aeroponics, programmable LED lights, climate controls, and a proprietary horizontal cloth conveyor that takes the plants from seed to harvest. AeroFarms says its customizable system increases yield up to 60 times that of conventional agriculture, uses 80 percent less water than hydroponic systems and only 3 percent of the land required by conventional agriculture.

In New York City, Big Box Farms is a hybrid vertical farm, growing salad greens inside a one-story industrial warehouse. It stacks plants between 10 and 20 layers high, up to 20 feet high, and uses a proprietary controlled and automated environment and harvesting system that employs LED lights, hydroponics, and 5 percent of the water used by conventional agriculture. The farms will be built right next to food suppliers and distributors to provide them with “private label,” just-harvested products.

About 3 million New Yorkers have no access to supermarkets or fresh produce in their neighborhoods. Vertical farms and other types of urban farming could help low-income residents shop and eat more healthfully. Despommier was a core member of the Earth’s Institute’s Urban Design Lab, whose fall 2003 Urban Ecology Studio project on remediating the Gowanus Canal in Brooklyn produced the first concrete vertical farm design (called Agro-wanus by Andrew Kranis) based on his ideas. The Urban Design Lab recently published a report examining New York City’s capacity for urban agriculture, ranging from community gardens to rooftop greenhouses.

Kubi Ackerman, project manager at the lab, told me that the report focuses on “existing” and “shorter-term” solutions, only mentioning vertical farms in passing, “But I’m a fan of Dickson Despommier’s. His work is interesting and there’s real value in having that vision out there to grow the discussion.”

And the discussion is indeed growing. Vertical farms are also being constructed in Manchester, England and Milwaukee, WI. And there is interest around the world—from Newark, NJ to Beijing, China, and in Singapore, Doha, Vancouver, Milan, Amman, Riyadh and Las Vegas. As more vertical farms are created, the engineering and technology will continue to evolve. And one day, NYC may well have vertical farms of all sizes in every borough, providing fresh produce to retailers, restaurants, and community residents. I think it’s only a matter of time…

Science for the Planet: In these short video explainers, discover how scientists and scholars across the Columbia Climate School are working to understand the effects of climate change and help solve the crisis.
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phan chanh tin
12 years ago

that a good idea…but it is very difficul to do.

ampoule led
12 years ago

A great idea! It seems to be working pretty well in the locations where these vertical farms have been built. I wish there were more of them around! A big initial investment but very interesting on a long term analysis I guess…Recreating natural light with LED lights is a great idea and it saves a lot of electricity.

trackback
11 years ago

[…] watts for each 9 square feet of plant area. Indoor CO2 levels can be controlled by sensors using various automated systems. A recent vertical farm in Singapore produces 1000 lbs of vegetables a day, with […]

indra
indra
7 years ago

i am interested in this project.
could you send me the paper research?

our family work in this field for over 4 decades, so we have established our network.