Could Vertical Farming Be The Future?

Farm capable of feeding 50,000 people could fit 'within a city block'

Rice on the seventh floor. Wheat on the twelfth. And enough food within an 18-story tower to feed a small city of 50,000.

Vertical farms, where staple crops could be grown in environmentally friendly skyscrapers, exist today only in futuristic designs and on optimistic Web sites. Despite concerns over sky-high costs, however, an environmental health expert in New York is convinced the world has the know-how to make the concept a reality — and the imperative to do so quickly.

With a raft of studies suggesting farmers will be hard-pressed to feed the extra 3 billion people swelling the world’s ranks by the year 2050, Columbia University professor Dickson Despommier believes a new model of agriculture is vital to avoid an impending catastrophe.

“The reason why we need vertical farming is that horizontal farming is failing,” he said. If current practices don’t change by mid-century, he points outs, an area bigger than Brazil would need to become farmland just to keep pace with the demand.

Working the soil has always been an uncertain venture, and Despommier argues that the price of crop failure is growing ever steeper as the global population mushrooms. “The world,” he said, “is running out of resources faster than what it can replace.”

Critics like Bruce Bugbee, a professor of crop physiology at Utah State University in Logan, see improvements in how future farmlands are managed as more practical and cost-effective. To Despommier, though, the world already has the need and the technology to dramatically improve yields and reliability by adjusting its point of view: from out to up.

The Columbia researcher said his interest in vertical farming is an extension of his long-standing work on disease transmission among humans. Among the laundry list of benefits he cites, Despommier believes vertical farming could help break the transmission cycle of diseases in traditional agricultural settings. But it’s the potential to help solve impending food shortages that really excites him.

A recent exercise conducted by students in his medical ecology class found that a self-sustaining vertical farm able to feed 50,000 people could “fit comfortably within a city block,” rising perhaps 18 stories. With adequate funding, a smaller prototype could be up and running in seven to 10 years, he predicts. Eventually, full-scale versions could be a new feature of city skylines, climbing as high as 30 stories and filled with automated feeders, monitoring devices and harvesting equipment. And, of course, they would feature crops such as wheat, rice, sugar beets and leafy greens grown in mineral nutrient solutions or without any solid substrates at all.

These hydroponic and aeroponic growing techniques, respectively, have benefited from NASA’s strong interest because any long-term venture to the moon or beyond would require the use of self-contained and resource-limited growth chambers. Despommier concedes that current practices must be improved and systems put in place to quickly identify and quarantine plants stricken with pests or disease. “No pun intended, but the bugs need to be worked out of this thing,” he said.

He insists, though, that money is the last major obstacle. To his critics, that hurdle has tripped up past entrepreneurs and may yet be insurmountable. “I can’t be very optimistic about this study,” said Utah State’s Bugbee. “None of this is very new. But it doesn’t mean the whole concept is without merit. It just means the claims are greatly exaggerated.”

Bugbee’s chief objection is the exorbitant power requirement for such a vertical structure.  Plants on the lower floors would require artificial light year-round or expensive mechanical systems to get more light to them. And during a typical winter in northern U.S. cities, he said, average sunlight is only 5 percent to 10 percent of peak summer levels due to sapped intensity and shorter days.

“November, December, January and February are really dark,” Bugbee said. “Plants aren’t limited by the temperature, they’re limited by the light.” High-pressure sodium lights may be a reasonable stand-in for sunlight to maintain plant growth,  he said, but the electric bill is enormous. “Boy have a lot of people gone bankrupt trying hydroponic greenhouses for that reason.”

Nevertheless,  greenhouses such as Arizona’s 265-acre Eurofresh Farms are thriving with their hydroponic tomatoes and seedless cucumbers. Gene Giacomelli, Director of the Controlled Environment Agriculture Program at the University of Arizona in Tucson, said questions of safety, quality and sustainability are pushing agriculture in a host of other directions, including Despommier’s vertical farming idea. “He’s one extreme – a very good one,” Giacomelli said.

Several years ago, Giacomelli and collaborators in Arizona explored another extreme when they won a contract to design and build a growth chamber within a new building at Antarctica’s Amundsen-Scott Research Station. The chamber can be tweaked remotely by scientists back in Arizona but is now largely managed by volunteers at the station.

Besides supplying some much-needed color and light for the research station’s residents during Antarctica’s bleak and bitterly cold winter months, the indoor chamber has yielded a range of crunchy greens, tomatoes, cucumbers, hot and sweet peppers and even cantaloupe. Next year, a student will try to grow watermelon in what is arguably the worlds’ most inhospitable place for a garden. Remarkably, the plot has produced about two-thirds of what top greenhouses in North America can deliver.

“I like to say that we can grow any plant anywhere and any time, but for a price,” Giacomelli said. The catch in Antarctica is that electricity  for the lights and pumps has inflated the cost to about $50 per pound of fresh vegetables . “Now, the local person at the supermarket would say you’re crazy for spending that much money on vegetables,” he said. “But you give that number to NASA and they’d say, ‘Wow, that’s a good number.’”

Transportation costs

Back on Earth, Despommier said urban farms could defray some of their own expense by significantly cutting transportation costs. And as the local food movement gains in popularity with environmentally conscious consumers, he said, what could be more local than vertical farming? Despite a lack of major technological advances, the effort also stands to benefit from small but steady improvements in hydroponics and automated systems to control temperature, humidity and nutrient delivery, according to Giacomelli.

To curb the excessive reliance on electricity, Giacomelli’s own group is planning to experiment with fiber-optic tubes called solar pipes that can capture sunlight from the Antarctic growth chamber’s roof. Meanwhile, Utah State University researchers have developed a clear piece of curved polyethylene that can retain heat in the ground and extend the growing season by up to four months for summer squash and tomatoes.

As for keeping up with global food demand by growing crops such as rice and wheat,  “we’re going to have to get better at farming marginal lands,” Bugbee said, “but it’s still going to be done outside because the sunlight is so cheap — well, free — and the sunlight levels are so high in the summer.”

He agrees that some farming will move toward more controlled environments, especially for high-value crops like fresh herbs that otherwise would be difficult to supply year-round. “Chefs will pay a lot for fresh basil,” Bugbee said, “but we’re not going to feed the world with that.”

Various Types Of Biogas Plants

Classification of biogas plants depends upon the plants design and mode of working.

 Classification of biogas plants depends upon the plants design and mode of working. One common way to classify them is

1. Movable type drum plant
2. Continuous type plant
3. Batch type plant

BATCH TYPE BIOGAS PLANT

Batch type biogas plants are appropriate where daily supplies of raw waste materials are difficult to be obtained. A batch loaded digester is filled to capacity sealed and given sufficient retention time in the digester. After completion of the digestion, the residue is emptied and filled again. Gas production is uneven because bacterial digestion starts slowly, peaks and then tapers off with growing consumption of volatile solids. This difficulty can overcome by having minimum to digester so that at least one is always in operation. This problem can also minimize by connecting batch loaded digester in series and fed at different times so that adequate biogas is available for daily use. The salient features of batch-fed type biogas plants are:

• Gas production in batch type is uneven.
• Batch type plants may have several digesters for continuous supply of gas.
• Several digesters occupy more space.
• This type of plants require large volume of digester, therefore, initial cost becomes high.
• This plant needs addition of fermented slurry to start the digestion process.

CONTINUOUS TYPE BIOGASS PLANT

In continuous type biogas plant, the supply of the gas is continuous and the digester is fed with biomass regularly. Continuous biogas plants may be single stage, double stage or multiple stages. Digestion of waste materials in a single chamber or digester is called single stage process, in two chambers or digester is called multi stage process. In double stage process, acidogenic and methanogenic stage are physically separated into two chambers. Thus, the first stage of acid production is carried out in a separate chamber and only diluted acids are fed into the second chamber where biomethanation takes place. In single stage, acidogenic and methanogenic stage are carried out in the same chamber without barrier. These plants are economic, simple and easy to operate. These plants are generally for small and medium size biogas plants. However, the two stage biogas plants are costlier, difficult in operation and maintenance but they produce more gas. 

These plants are preferred for larger biogas plant system. The important features of continuous type biogas plants are:

• Gas production is continuous.
• Retention period is less
• Fewer problems as compared to batch type
• Small digestion chambers are required

MOVABLE DRUM TYPE PLANTS

This also known as floating dome type biogas plant. The conventional movable drum type comprises a masonry digester with an inlet on one side for feeding slurry and an outlet on the other side for removing digested slurry. The gas collects in a steel gasholder which is inverted over the slurry and moves up and down depending upon accumulation and discharge of gas guided by a central guide pipe. This movable gas holder is made of steel. The gas holder is painted by anticorrosive painting at least once in year. This plant helps in consistent pressure which can be adjusted by regulating weight. The main drawback of this is that metal cost is large and maintenance cost is also high. To tackle this problem the scientists have created high density polyethylene.

Advantages:

• Constant gas pressure
• No problem of gas leakage
• Higher gas production
• Scum problem is less

Water - Every Drop Counts

After air, the next most vital thing for our survival is water. While at the moment we have enough water for our needs, a time is likely to come when our water supply runs out and we have to buy water at a price similar to fuel. The solution, which some people have implemented, is to save and store rainwater

More Efficient Renewable Resource.

New biofuel process generates energy 20 times higher than existing methods, and uses agricultural waste:

A new biofuel production process created by Michigan State University researchers produces energy more than 20 times higher than existing methods. The results, published in the current issue of Environmental Science and Technology, showcase a novel way to use microbes to produce bio fuel and hydrogen, all while consuming agricultural wastes.

Gemma Reguera, MSU microbiologist, has developed bioelectrochemical systems known as microbial electrolysis cells, or MECs, using bacteria to breakdown and ferment agricultural waste into ethanol. Reguera's platform is unique because it employs a second bacterium, which, when added to the mix, removes all the waste fermentation byproducts or non-ethanol materials while generating electricity.

Similar microbial fuel cells have been investigated before. However, maximum energy recoveries from corn stover, a common feedstock for biofuels, hover around 3.5 percent. Reguera's platform, despite the energy invested in chemical pretreatment of the corn stover, averaged 35 to 40 percent energy recovery just from the fermentation process, said Reguera, who co-authored the paper with Allison Spears.

"This is because the fermentative bacterium was carefully selected to degrade and ferment agricultural wastes into ethanol efficiently and to produce byproducts that could be metabolized by the electricity-producing bacterium," Reguera said. "By removing the waste products of fermentation, the growth and metabolism of the fermentative bacterium also was stimulated. Basically, each step we take is custom-designed to be optimal."

The second bacterium, Geobacter sulfurreducens, generates electricity. The electricity, however, isn't harvested as an output. It is used to generate hydrogen in the MEC to increase the energy recovery process even more, Reguera said.

"When the MEC generates hydrogen, it actually doubles the energy recoveries," she said. "We increased energy recovery to 73 percent. So the potential is definitely there to make this platform attractive for processing agricultural wastes."

Reguera's fuel cells use corn stover treated by the ammonia fiber expansion process, an advanced pretreatment technology pioneered at MSU. AFEX is an already proven method that was developed by Bruce Dale, MSU professor of chemical engineering and materials science. Dale is currently working to make AFEX viable on a commercial scale.

In a similar vein, Reguera is continuing to optimise her MECs so they, too, can be scaled up on a commercial basis. Her goal is to develop decentralised systems that can help process agricultural wastes. Decentralised systems could be customised at small to medium scales (such as compost bins and small silages, for example) to provide an attractive method to recycle the wastes while generating fuel for farms.

Worldwide, the market for biofuel production is expected to reach $100 billion by 2018, compared to $35 billion just a decade earlier.

The Story Of Water In India

India is a blessed country with 

The Future Of Renewable Energy

The Global State of Agriculture

The U.S. humanitarian assistance organization provides this infographic to illustrate the need for increased food production by emphasizing the boom in the global population. The planet now supports 7 billion people, and USAID estimates food production must increase 70% by 2050 to meet the growing need.

The Story Of Agriculture And The Green Economy

The future of our world depends on addressing global challenges now. We need to create sustainable livelihoods, feed a growing population and safeguard the environment. We need to make the global economy green.

Can Organic Agriculture Feed A World Of Nine Billion People?

A new meta-analysis suggests farmers should take a hybrid approach to producing enough food for humans while preserving the environment.

Agriculture has supplanted 70 percent of grasslands, 50 percent of savannas and 45 percent of temperate forests as a result of global climate changes. Modern commercial farming is also the leading cause of deforestation in the tropics and one of the largest sources of greenhouse gas emissions, a major contributor to the ongoing maul of species known as the “sixth extinction,” and a perennial source of nonrenewable groundwater mining and water pollution.

To restrain the environmental impact of agriculture as well as produce more wholesome foods, some farmers have turned to so-called organic techniques. This type of farming is meant to minimize environmental and human health impacts by avoiding the use of synthetic fertilizers, chemical pesticides and hormones or antibiotic treatments for livestock, among other tactics. But the use of industrial technologies, particularly synthetic nitrogen fertilizer, has fed the swelling human population during the last century. Can organic agriculture feed a world of nine billion people?

Environmental scientists at McGill University in Montreal and the University of Minnesota performed an analysis of 66 studies comparing conventional and organic methods across 34 different crop species. They found that, overall, organic yields are considerably lower than conventional yields but, this yield difference varies across different conditions. When farmers apply best management practices, organic systems, for example, perform relatively better.

In particular, organic agriculture delivers just 5 percent less yield in rain-watered legume crops, such as alfalfa or beans, and in perennial crops, such as fruit trees. But when it comes to major cereal crops, such as corn or wheat, and vegetables, such as broccoli, conventional methods delivered more than 25 percent more yield. But that is quantity, not quality.

The key limit to further yield increases via organic methods appears to be nitrogen – large doses of synthetic fertilizer can keep up with high demand from crops during the growing season better than the slow release from compost, manure or nitrogen-fixing cover crops. Of course, the cost of using 171 million metric tons of synthetic nitrogen fertilizer is paid in dead zones at the mouths of many of the world’s rivers. These anoxic zones result from nitrogen-rich runoff promoting algal blooms that then die and, in decomposing, suck all the oxygen out of surrounding waters.

To address the problem of nitrogen limitation and to produce high yields, organic farmers should use best management practices, supply more organic fertilizers or grow legumes or perennial crops.

In fact, more knowledge would be key to any effort to boost organic farming or its yields. Conventional farming requires knowledge of how to manage what farmers know as inputs – synthetic fertilizer, chemical pesticides and the like – as well as fields laid out precisely via global-positioning systems. Organic farmers, on the other hand, must learn to manage an entire ecosystem geared to producing food – controlling pests through biological means, using the waste from animals to fertilize fields and even growing one crop amidst another.

Organic farming is a very knowledge-intensive farming system. An organic farmer “needs to create a fertile soil that provides sufficient nutrients at the right time when the crops need them. 

 Source: Scientific American

Featured image credit: Chillymanjaro

Will The World Go Hungry?

In the first half of this century, as the world’s population grows to around 9 billion, global demand for food, feed and fiber will nearly double while, increasingly, crops may also be used for bio-energy and other industrial purposes. New and traditional demand for agricultural produce will thus put growing pressure on already scarce agricultural resources. And while agriculture will be forced to compete for land and water with sprawling urban settlements, it will also be required to serve on other major fronts: adapting to and contributing to the mitigation of climate change, helping preserve natural habitats, protecting endangered species and maintaining a high level of biodiversity. As though this were not challenging enough, in most regions fewer people will be living in rural areas and even fewer will be farmers. They will need new technologies to grow more from less land, with fewer hands.

How To Feed The World In 2050: Actions In A Changing Climate