Growing Food in Kitchens

Centuries ago, it would have been not easy to imagine that we could grow crops without soil. Rich soil has traditionally been an essential requirement for growing plants, but technological advancements in agriculture are changing. Hydroponic systems are challenging traditional soil gardening and may well be the plant-growing systems of the future. Prevailing traditional agricultural methods are not sustainable. Heavy consumption of pesticides, wastewater, emissions, deforestation, and ecosystem disruption are only some of the issues. Climate change, economic crises, and pressure on the environment put the food chain stability at risk. Today, however, commercial hydroponics growers adopted the laboratory practice of growing plants in water and fertilizer solutions for scientific studies. A wide variety of plants are suitable for hydroponics growing. We can grow vegetables, herbs, fruits, and flowers.

Availability of hydroponics is coupled with the need for urban agriculture. Such practices like hydroponics build up the agricultural potential of cities. At the same time, they are delivering positive environmental benefits. Since farmers can control the nutrient supply to the plants via hydroponics, they can grow crops in or out of season. They need to consider other factors like exposure to sunlight and temperature, yet they can manage those using farming methods that enable them to control their farm environment.

In many ways, hydroponics can help to reduce the agricultural sector’s contribution to global warming. It is not as carbon-intensive as traditional soil-based farming and encourages local food production and supply. Large-scale hydroponic systems operating in urban areas bring food supply closer to consumers. It cuts back on transport emissions generated along the supply chain. According to research on the environmental benefits of hydroponic growing in urban Europe, carbon-neutral hydroponic food production outperforms the two conventional types of agriculture. Moreover, in places where water scarcity is a problem, hydroponic systems can radically improve water consumption in farming. The hydroponic system uses ten times less water than traditional soil-based farming. This is because it is unlike field crop watering, where water has to be sprayed till the soil absorbs it. In hydroponics, the systems deliver nutrient solutions directly to plant roots. When they pump it through a medium, absorption is not necessary. The water which contains nutrients is recaptured and reused, unlike in traditional farming, where water is allowed to run off into the environment. This eliminates the need to source water resources often. 

Another advantage of hydroponics is the safety and neutrality of the crops. The intensive use of pesticides is one of the problems of traditional agriculture. Thanks to the controlled environment, pest attacks are not an issue in hydroponics. This means that there is minimal use of pesticides, if at all. Hydroponic systems eliminate the problem of weed growth which, in turn, means zero herbicides use. Using herbicides in traditional farming contributes to air pollution and soil contamination. Also, because the plants are not in the soil, there is no chance of chemical fertilizer contamination.

Lower consumption of water is another attraction of hydroponics. Farmers can reuse the nutrient solution in hydroponics indefinitely, although the nutrients themselves require replacing as depleted. They collect the solution as it drips from the channels into a nutrient reservoir. Also, farmers can get nutrients from various sources. One technique, aquaponics, uses fish excrement as a nutrient source.

Hydroponics is also more sustainable. Growing can occur all year long as seasonality does not limit it like traditional soil-based farming. This means that seasonal food scarcity due to snowfall or no rains can be reduced or eliminated. It presents an opportunity to improve the food supply. Moreover, hydroponic growing systems produce a greater yield of fruits and vegetables compared to traditional farming. This is because elements that determine plant health and yield are better monitored and controlled. These elements include light, water, nutrients, and pH. 

Also, because the plants are more densely packed, a hydroponic farm will yield much more than a field plantation of the same size. One other benefit of hydroponics is that it has a faster plant growth rate. Also, hydroponics is practicable almost anywhere in the world.

Hydroponics does not consume large expanses of land like traditional farming. With hydroponic growing, we can produce food locally without occupying agricultural land. This makes it an excellent option for land conservation without harming the food supply. We can do it indoors and outdoors, so it is possible to operate thriving hydroponics gardens in rural areas and built-up urban settlements. Hydroponics also helps conserve space as they usually arrange the tubes vertically, allowing farmers to use space above the ground. This is possible by anchoring the tubes to frames or suspenders.   

Hydroponic systems are not free of challenges. Farmers have to measure and control the electrical conductivity, pH, temperature, and dissolved oxygen. The margin for error in maintaining the right balance of all these elements is tiny. One slight mistake may affect the system severely. These challenges, however, do not reduce the environmental benefits of the hydroponic system in any way.

Diseases: The benefits of hydroponics do not include immunity to diseases. Pathogens can quickly spread because the water is recirculated. Therefore, the hydroponic system requires close monitoring. Not just to monitor the level of nutrients but also to ensure that the plants are protected from diseases.

Energy use: Depending on the environment, indoor hydroponic gardens may need an artificial light source. Also, most hydroponic techniques require an electric pump to keep the nutrients and water flowing. These consume energy. According to research, fossil fuel use decreases the benefits of hydroponic production. Therefore, it is essential to ensure that the energy source is clean and sustainable.

Food safety: Some rules may guide growing plants in hydroponic systems in your locality. These rules may dwell on safety practices for commercialized hydroponic gardens. It would help if you found out what regulations exist in your area and how they affect your hydroponic gardening endeavours.

Home scale hydroponic: You can apply hydroponics to home gardening successfully. It is an excellent option for people who do not have space for traditional gardening. You will need several things, including nutrient solutions, which can be bought at a store or made at home. If you are growing plants hydroponically indoors, it helps to have an artificial light source to stimulate healthy plant development. Also, ensure that the space has excellent air circulation. It is best to use vertical hydroponic systems to grow your vegetables and herbs.

Advantages and disadvantages of hydroponics

The hydroponic cultivation system is one of the hottest and most popular topics of the day in agricultural science, which has been able to attract the attention of many agricultural engineers and farmers around the world, as well as flower and flower plants growers. The advantages and disadvantages of hydroponics are wide and varied, and we intend to address them in this article, but a little explanation is needed beforehand. Some its advantages are as follows: 

No need for soil: Crops can be grown without the need for soil anywhere and with any climatic conditions and notable limitations of the traditional planting system. Nutrients are soluble in water, and you only need to prepare the ship environment such as perlite, coconut fibre, agricultural grade wool or clay gravel.

Less water is consumed: This system’s water consumption is up to 90% less than planting a plant in soil. This is especially important in hot, dry or desert areas such as Central Africa. Water contains circulating nutrients and is not wasted, and each time it enters the cycle, it goes back to the plant’s roots. Water evaporation also depends on the type of hydroponic culture system chosen, but it is generally very low, especially if you are indoors.

Control over nutrients: In a soil-based planting system, fertilizers lose their effectiveness after a while, and not all of them reach the plant. However, the solution used in the hydroponic system is in constant direct contact. As a result, only a few tablespoons of nutrients, even organic, per gallon of water, lower nutrient intake and supply costs. Nutrients are available in both powder and ready-to-buy forms. The powder type is cheaper, but it takes longer to dissolve. The ready mix is ​​more expensive and mixes quickly with water, and even has a pH buffer composition.

Better growth rate: A critical advantage of a hydroponic system is that each plant can grow as much as possible and get the most out of your crop because there are few limiting factors in the soil. Plant energy is spent on vegetative growth, not root development, to find nutrients in this system because it is always available. Plants are denser (4 to 16 times) and can grow in layers or vertically. Product production is between 2 to 8 times higher. The plant growth lamp provides the required light. By controlling water consumption, production increases up to 10 times.

Pests and insects are much less: Pests, weeds and insects are much less in this system, so you do not need to buy insecticides, pesticides or even fungicides, and these costs are greatly reduced, and you do not contaminate the soil. Pest control is more accessible due to their minimal number, and you have easier farming.

Less labour: Because you do not need soil, work such as plowing, planting, spraying and mulching will be eliminated, and you will need less labour. By removing these cases, planting and harvesting time will be much faster.

Much less space: One of the reasons plants are planted in the ground at intervals is that the roots grow to get nutrients and should not interfere with each other. In a hydroponic system, because nutrients are always available, there is no need for much root growth, much less space is required, and high densities are possible.

Healthy products and fewer diseases: Chemical fertilizers and pests are some of the factors that transmit the disease to plants and then to humans. By removing these items, the hydroponic system creates a healthy, very fresh and fresh product.

High compatibility: All types of plants can be used in hydroponic cultivation, but you may need to use some plants only for some types of hydroponic systems. Therefore, this case explains the advantages and disadvantages of hydroponics.

Disadvantages of hydroponic culture:

Despite an array of many advantages, hydroponics are yet without disadvantages. Some of which include what follows.

High start-up cost: This is one of the advantages and disadvantages of hydroponics that cannot be categorized as a disadvantage. The costs of setting up this system, especially when you want to grow plants indoors, are high. This is due to the purchase of plant growth lamps, ventilation systems to reduce ambient heat, air pumps, air stones, nutrients and reservoirs, as well as generators in the event of a power outage. However, the production of the product multiplies, and the said benefits offset these costs entirely.

The high importance of time: In the soil planting system, if you forget to irrigate the plant one day or do not do it for any reason, tomorrow is the time to compensate, but in the hydroponic system, if the water required by the plant is cut off, the plant will die. So although hydroponic cultivation is easy, it takes a long time because you have to be constantly vigilant. The more time you spend, the more profit you will make.

Aquatic diseases: Pests and diseases related to soil are eliminated, but they are related to water, so you need a filtration system, and on the other hand, the humidity and heat generated by the irrigation system should be reduced to prevent the growth of fungal agents, especially Take Pythium and phytophthora. Otherwise, it only takes 20 hours for these fungi to infect your entire sterile system because all plants use the same nutrient solution.

Technical knowledge: Planting a plant with a hydroponic system requires specialized knowledge and skills, and if you do not have it, you will need more time and capital to gain experience.

Better growth rate: A critical advantage of a hydroponic system is that each plant can grow as much as possible and get the most out of your crop because there are few limiting factors in the soil. Plant energy is spent on vegetative growth, not root development, to find nutrients in this system because it is always available. Plants are denser (4 to 16 times) and can grow in layers or vertically. Product production is between 2 to 8 times higher. The plant growth lamp provides the required light. By controlling water consumption, production increases up to 10 times.

Much less space: One of the reasons plants are planted in the ground at intervals is that the roots grow to get nutrients and should not interfere with each other. In a hydroponic system, because nutrients are always available, there is no need for much root growth, much less space is required, and high densities are possible.

Today, in big cities, living in backyards and villas has become a dream. In large cities, houses with flowers and plants planted in the small yard in front of them are not seen. In addition to depriving man of breathing in the fresh air, this also deprives the modern man of the opportunity to receive fresh vegetables and fruits.

In addition to beauty, natural flowers and plants in the house’s layout can clean the air of the house and give beauty to people. People who keep a lot of wildflowers in their homes feel better. If you wish to turn a corner of your kitchen into a hydroponic garden, you might face a challenge with choosing among many hydroponic systems. Hydroponics is a vast field, with many different scientific and technological solutions, each with its peculiarities, advantages and disadvantages.

Fruits and vegetables are significant sources of several nutrients that are strongly linked to good health, particularly the heart and blood vessels. Studies have shown that the most practical combination of fruits and vegetables are two servings of fruits plus three servings of vegetables per day, for five servings daily. The most significant health benefits came from eating leafy green vegetables (kale, spinach) and fruits and vegetables rich in vitamin C and beta carotene (citrus, berries, carrots). “These are primary sources of antioxidants that may play a role in preventing cancer.”. It’s typically preferable to cultivate salad greens like Lettuce, Parsley, Radish, Pakchoi, etc., in a Hydroponics greenhouse. 

What’s the nutritional difference between the carrot I ate in 1970 and the one I eat today? It would be overkill to say that the carrot you eat today has very little nutrition in it, especially compared to some of the other less healthy foods you likely also eat. At the same time, fruits and vegetables grown decades ago were indeed much richer in vitamins and minerals than the varieties most of us get today. The main culprit in this disturbing nutritional trend is soil depletion. Modern intensive agricultural methods have stripped increasing amounts of nutrients from the soil where we grow the food we eat. Studies have further demonstrated that one would have to eat eight oranges today to derive the same amount of vitamin A as our grandparents would have gotten from one. Sadly, each successive generation of fast-growing, pest-resistant carrot is truly less good for you than the one before.

Hydroponics is a technique for growing an intelligent farm within a greenhouse. Here, a ‘smart farm’ refers to a soilless, vertical setup that can house a thousand plants and more. A Hydroponics farm may be our best bet for churning out chemical-free produce in less than half the space of actual farmland. The number of vertical farms has grown to several hundred farms across Asia, Europe, and North America since the first appeared in 2010. Using different technologies, vertical farms are a new type of Controlled Environment Agriculture (CEA) that could be described as a stack of greenhouses on top of each other, multiplying the plant yield by the number of floors comprising the vertical farm. It has now become a solution to most of the issues deriving from traditional outdoor farming. By occupying less land, it can contribute to the restoration of forests, and by operating within a circular economy framework, it uses fewer resources and reuses organic waste. Impacts on health could also be significant as outdoor farming contributes to the spread of global infectious diseases. It is also interesting to compare the advantages of vertical farms with those of other types of urban agriculture. For instance, open lots are a common way of growing food in an urban environment. However, open lots are in close contact with car exhaustion, which penetrates the soil, is absorbed by plants, and is consumed by people. Another example is building gardens on rooftops, which can only be done in regions of the world where winter temperatures are mild. While greenhouses deal with this issue, they cannot yield sufficient food to feed the increasing number of urban dwellers. Vertical farms can be perceived as an ideal urban farming method, as it optimizes land use and increases food density per square foot of farming space. 

Vertical farming is a valuable solution to the issues involved with traditional outdoor farming. Its first and foremost contribution is to the environment. There is a broad consensus among academia, policymakers, international organization staff, and society in general that the current system of outdoor soil-based farming is unsustainable and primarily responsible for climate change. Half the world’s trees –the equivalent of the size of Brazil– have been deforested for the sake of agriculture. As it is well known, trees are a core element that sequesters carbon dioxide and produces oxygen. The destruction of forests for agricultural land use has a considerable role to play in climate change. Indoor farming, notably vertical farming, would allow us to reduce the amount of land necessary to feed the ever-increasing world population, which is particularly important considering that the latter is expected to grow up to 9.8 billion in 2050. Vertical farms could even contribute to the restoration of 60 to 70% of forests (two trillion trees), which would sequester enough carbon to reverse the rate of global warming.

Admittedly, indoor farming cannot be expected to fully replace all of the 1.87 billion hectares devoted to crop production. For instance, rice is highly costly to grow indoors, while beef is almost impossible to raise indoors. However, it can become a considerable source of food, decreasing the need for excessive farmland usage. Indeed, other animals such as crustaceans, fish, and poultry can be produced in vertical farms, and cattle food – growing soy indoors could significantly impact deforestation. Even if indoor farming does not fully replace outdoor farming, it may complement the food system facing the increasing pressures of demographic growth and land scarcity.

The human body needs 200 grams of vegetables daily, which is less for the elderly over seventy, adolescents and children. Such daily consumption of vegetables prevents chronic diseases such as heart disease, diabetes, cancer and obesity. According to new research, vegetable color plays a role in classifying their properties. Therefore, it is recommended to eat vegetables with various colors for health. 

Adopting hydroponics is one of the ways the world can move towards sustainable agriculture. It is also a valuable tool in combating food scarcity as it allows plants to be grown in and out of season. Vertical farms decentralize the food system and democratize the food supply since it increases supply, lowers prices, and contributes to food access to all sections of the population, including the poorest. More equitable and widespread access to food will further enhance urban systems’ sustainability.