1. Introduction
Vertical farming is one of the crop production strategies that falls under the term controlled environment agriculture. Plants are grown indoors in purpose-designed structures where they are mostly or completely protected from the vagaries of the weather. Worldwide interest in vertical farming has increased substantially over the last decade due to concerns about the continued growth of the world population, the impacts of climate change, and the availability of nutritious food and resources (land, water, energy). Technological advances in sensing and control systems, plant breeding, automation and robotics, and energy-efficient equipment have supported the rise in vertical farming, as have disruptions in food supply systems due to man-made or weather-related climate-change events. Large population centers have started to pay more attention to resiliency, as well as the distance food travels, and vertical farming seems to be a logical fit in terms of a more reliable food supply.
Vertical farming is practiced using a variety of different growing systems. These systems include growing on multiple levels on a single floor (using shelving systems) or growing on multiple floors in a single building (using a single growing layer per floor or a shelving system on each floor). Other systems that are often considered vertical farming include vertically mounted growing systems (e.g., growing troughs suspended from the ceiling), A-frames, and (largely) vertical conveyor systems. While vertical farming can include the production of fish, animals and crops, this paper focuses primarily on crop production.
During the last decade, substantial investments have been made in vertical farming operations, giving the impression that vertical farming will become a major player in our food supply system. However, vertical farming typically increases production costs due to higher capital investments and higher energy requirements. These higher costs are acceptable to consumers only when the product has higher quality attributes, is fresher, or is not otherwise available. However, the higher production costs of vertical farming make it unlikely that staple crops (corn, soybean, wheat, rice, potato, etc.) can be grown economically in vertical farms. Therefore, vertical farming is likely to remain focused on the production of leafy greens, herbs, and some fruiting crops (e.g., strawberries, tomatoes, peppers), i.e., produce that does not ship or store well. Therefore, we believe that vertical farming will contribute to our food supply system, but only with respect to a limited number of crops. On the other hand, vertical farming does provide innovative and financially attractive opportunities to grow medicinal crops, especially cannabis, and we see opportunities for increased production capacity where security and/or environmental isolation may be necessary. While accurate numbers are difficult to ascertain, we estimate that worldwide investments over the last decade in the VF industry exceed well over USD 1 billion.
Most crop agriculture uses sunlight as the sole energy source for photosynthesis. As we move crop production indoors, the available sunlight is not always sufficient for vigorous year-round crop production. Therefore, indoor crop production often requires the use of supplemental lighting. When we move crop production into fully enclosed structures (as is often the case for vertical farming operations), all the energy required for photosynthesis needs to be provided by a so-called sole-source lighting system. Since relatively high light intensities are needed for vigorous plant growth, the electricity consumption associated with plant lighting systems is typically high and will have a major impact on the production costs. [
1] reported on the key performance characteristics of the various lamp types used for horticultural applications, including their power consumption and efficacy. In addition to labor costs, the other major expense for vertical farming operations involves temperature and humidity control (often accomplished with air-conditioning systems). Additionally, when crops are grown on multiple floors, the cost of continually pumping water can be quite substantial.
As with other forms of agriculture, vertical farming systems are often perfected by trial and error. This process takes time and money and results in systems that are often site-specific based on local conditions and restrictions. It also makes the developers protective of their approaches and solutions. While understandable, this attitude has resulted in start-up companies often having to ‘reinvent the wheel’, and has prevented extensive collaborations with researchers at academic institutions. We believe that this situation has hindered progress and we encourage the vertical farming industry to find arrangements that allow for the protection of key production elements, while also allowing for more collaboration and information exchange.
The objective of this paper is to provide considerations for those planning or operating a vertical farm. We recognize the potential vertical farming has to make portions of our food supply system more efficient and resilient, and to increase the availability of nutritious food, especially in high-density population centers. On the other hand, we want to point out several challenges that we believe require more discussion and research.
2. Planning a Vertical Farm
Vertical farming operations can be expensive in terms of capital and operating expenses [
2]. The larger vertical farms often require investments from venture capital or investment firms. Finding a suitable location can be challenging, particularly in urban areas where land and building prices are high. Operating expenses include labor, energy, and supplies needed to grow, harvest, and possibly store the crop [
3]. After labor, energy is typically the second-largest operational expense, but other inputs (e.g., water, nutrients, carbon dioxide, shipping supplies, product labels) are also needed. As the vertical farming industry expands, and production systems and practices become more mainstream, it is expected that production costs will come down [
4].
According to [
5], most cities have a variety of sites suitable for vertical farming, and appropriate planning can ensure operations can turn a profit while providing important services to nearby communities. However, in many locations there is still a lack of institutional, financial, and technological support [
6]. In addition, planners and decision makers sometimes have insufficient knowledge about commercial indoor crop-production practices, making it less likely they will make supportive decisions. Therefore, it may take a lot of effort to explain the proposed plans and convince decision makers that vertical farming can have measurable benefits for local communities.
Vertical farming can make efficient use of urban spaces, including previously vacant warehouses, rooftops, and other abandoned or vacant areas. Such under-utilized buildings/areas are readily available throughout the U.S. Some companies are planning to build their facilities just outside urban centers in order to reduce cost and still require limited transportation times. The suitability of sites and buildings that can be converted into vertical farming operations depends on how long a property is available, how much space is available, and how the site is zoned. While some municipalities, districts, counties, or states will have regulations, codes, or guidelines in place that support agriculture and the associated construction of facilities (e.g., [
7]), such rules typically do not address the unique issues associated with vertical farming. Additionally, since vertical farms are not very common, zoning variance may have to be secured and zoning officials may have to be educated about the proposed usage and any potential impacts. Therefore, additional time may be needed to secure all the permits required to operate a vertical farm. A comprehensive feasibility study can help address all concerns that may arise when developers propose new vertical farming operations [
8].
When choosing a crop to grow in a vertical farm, two broad categories need to be considered: grow-technical challenges and marketability. Grow-technical challenges involve the ability to design and operate a vertical farming system that cultivates the selected crop. Marketability refers to the competitiveness of the products grown in such a system. Theoretically, any crop can be grown in a vertical farm, but most will create major technical and growing challenges. For example, many vertical farming systems produce leafy greens (e.g., head lettuce, leaf lettuce, leafy herbs) because of their small size, fast growing cycles, and relatively low energy requirements [
9]. On the other hand, large, energy-intensive crops, such as heavy vining crops (e.g., melon) or tree fruit, may require a special design that is different from that of a typical vertical farming system. Therefore, such crops are seldom grown in a vertical farm. Developing special designs for vertical farming systems is the domain of companies focused on designing vertical farming technology.
In addition to looking at what is grow-technically feasible, operators must also consider several questions related to how marketable their product is. How will the product be distributed? What is a fair price? Is there seasonal demand? Crops from vertical farms usually cannot compete on price compared to conventionally grown crops because of the higher labor and energy inputs [
10]. Consequently, their products need to have some additional value compared to conventionally grown crops. Examples of added value are: 1. Distribution channels can be less complicated because the location of the farm is very close to its final destination; 2. crops—for example, ornamentals and cannabis—can have a higher quality from being grown in a controlled environment; 3. crops can be marketed as being more resource efficient, and hence environmentally friendly, adding to their value [
11]; and 4. certain crops with high demand during their conventional off-season might be able to command a premium price. Essentially, vertical farm operators must have some sort of marketing advantage to counteract the higher operational costs of running a vertical farm.
The primary goal of most businesses is to maximize profits for the owners or a group of stakeholders. After that, most businesses will focus on their customers, the local environment, and society at large. Vertical farming operations that promote transparency and are willing to engage with their customers and local communities are well positioned to provide needed solutions to the existential challenges that our communities face today [
6]. The high degree of control over crop-production practices that is possible with vertical farming operations ensures that growers can maximize resource-use efficiency while minimizing negative environmental and societal impacts [
4].
On the other hand, commercial businesses need to be competitive and strategic. Growing high-yielding, fast-growing plants that have low production costs in areas with adequate marketing potential will be crucial for the success for vertical farming operations. Branding and consumer education are important business tools that can help develop a loyal customer base [
12]. Today’s consumers are more and more focused on local production that helps create jobs and adheres to environmentally friendly production practices.
3. Operating a Vertical Farm
A variety of challenges must be understood in order to successfully run a vertical farm. Picking a crop that can be grown profitably and safely is paramount to a vertical farm’s success. The inherent complexity of the system requires a cohesive team and delegation of tasks. Similar to a traditional farm during its growing season, vertical farms need constant upkeep, with the main difference being that a vertical farm’s growing season continues year-round. Upkeep includes managing the growing system, crop growth, and pests. A systematic approach to data collection, processing, and analysis is necessary to continuously track production and evaluate further optimization strategies for the farm.
As discussed above, vertical farm operators should generally focus on a cultivation system that has been used in other similar settings and leave development of new systems to specialized companies. Depending on the crop(s) cultivated, there are a variety of systems to choose from. The most popular systems use some form of hydroponics to minimize weight and maximize water and nutrient use efficiency. These systems break down into two broad categories: stacked horizontal layers and vertical columns. Stacked horizontal layer systems create multiple layers of typical hydroponic systems (e.g., nutrient film technique and flood tables) and stack them vertically. On the other hand, vertical columns use tall columns that either drip or spray nutrient solution onto the suspended roots of plants. Stacked horizontal layer systems are significantly more complex and costly to implement than vertical columns. Operators must deliver fresh, climate-controlled air, nutrient solution, and lighting to each layer of their system, which is typically facilitated by a complex network of electrics, plumbing, and heating, ventilation, and air conditioning (HVAC). The main disadvantage of vertical column systems is the necessity of inter-canopy lighting. With current lighting technology, top lighting for vertical columns cannot achieve homogenous light distribution for the entire column. Inter-canopy lighting adds complexity and cost to the system. Ultimately, each cultivation system has its own unique advantages and disadvantages that an operator must consider before implementation in their vertical farm.
Once a crop and cultivation system has been selected, close attention must be paid to pest management. Without an integrated pest management (IPM) program, a vertical farm will almost certainly succumb to pest-related crop failure. The main pests encountered in controlled settings are fungal or arthropods (e.g., mites and gnats). Since vertical farms operate in a contained space, pests are almost always coming in from the outside, either on personnel, seeds, in the air, or in the water. Exclusion of these pests through air showers, coveralls, seed sterilization, air filtration, and water treatment can prevent pests from entering the facility. Exclusion of pests through various decontamination protocols should be the first line of defense, but it cannot be the only one [
13]. Eventually, pests will enter the facility and proper management is necessary to avoid crop loss. Proper environmental control is essential to avoid humidity buildup and condensation, which can favor fungal growth. Biocontrol agents can help control outbreaks of arthropod pests. However, they must be used as a proactive strategy, because introduction in reaction to an outbreak will typically not be fast enough to stop crop damage. Beneficial insects must be introduced prior to outbreaks and their populations must be maintained in the facility for maximum effectiveness [
13].
Safely growing crops in a vertical farm requires a separate set of standards compared to crops grown using conventional agricultural practices. Organizations such as the CEA Food Safety Coalition and the Global Food Safety Initiative have developed food-safety guidelines for vertical farming operations. In order to meet these guidelines, operators need to consider all factors that could potentially contaminate food. These can include water, other inputs, seeds, product handling, storage, and shipping. A major area of concern is water quality. Recirculating water systems can easily spread pathogens when the nutrient solution is not treated properly. Potential food-safety concerns can be monitored through data collection and traceability, allowing for quick action in case of a pathogen outbreak.
Labor is by far the highest cost for VF operations [
10]. Compared to conventional field agriculture, vertical farming is significantly more labor intensive and lacks widespread automation. Without significant advances in automation, operators will need to rely on a human workforce for the time being. Given that vertical farms operate year-round, a local labor force is preferred, compared to conventional farms that hire seasonal labor. Considering that most vertical farms are located in urban areas, they typically have access to a large local labor force. However, laborers sourced from urban areas typically have little to no experience or training for the labor required on a vertical farm [
14]. Thus, operators will need to invest significant resources to train their workforce. Proper training is needed for cultivation techniques, integrated pest management, food safety and handling, and data collection. As discussed earlier, failure in any of these areas can have severe consequences for the profitability of a vertical farm. Relying on undertrained and unexperienced employees might be necessary without a developed workforce, which is a major risk to a new vertical farm. Beyond training employees, operators must create a workplace culture with open communication. This allows employees to quickly relay information related to issues on the farm, potential inefficiencies, and areas that need a more experienced point of view. Additionally, operators need to manage their workplace culture to minimize turnover. A high turnover rate interrupts the optimization process and wastes training resources and time. A significant source of institutional knowledge on the farm is the collective experience of the workforce. Their input is crucial for exposing inefficiencies in operations. However, this can only take place if the employees are well trained and accustomed to the operations. Ultimately, a well-trained, cohesive local labor force is necessary to run a vertical farm.
Labor automation, as mentioned above, can alleviate some of the labor costs associated with VF operations. Automated systems can control seeding, planting, moving plants, irrigation, harvesting, and post-harvest processing. These systems do not eschew the need for any labor. Quality control (of the production system and finished products) and maintenance of these systems is difficult to automate and requires highly skilled workers. On top of this, automated systems are capital intensive and out of reach for most small operations. A cost-effective approach to reducing labor in VF operations is a combination of automation and efficient systems. Efficiency can also be gained by reducing movement of laborers during routine maintenance of the crop, harvesting, and post-harvest processing.
Data collection and environmental monitoring enables optimization of a vertical farming system. Optimization of yields and energy efficiency is needed to increase the economic viability of VF. A main advantage of VF systems is their high degree of controllability, which can be enhanced by data-driven decisions. Operators can collect large amounts of data related to environmental parameters and plant growth. Environmental parameters include air temperature, root-zone temperature, humidity/vapor pressure deficit, CO
2 concentration, dissolved O
2 in the nutrient solution, nutrient concentrations, water flow rate, and light intensity. Plant growth data include observations from quantitative measurements such as plant fresh weight or shoot length, and qualitative measurements such as physiological disorders (e.g., tip burn) and leaf color. Monitoring of these parameters needs to take place throughout the vertical farm to uncover any heterogeneous conditions [
15]. A data-management system is needed to aggregate and analyze the large amounts of data gathered from a vertical farm. An Internet of Things (IoT) system, such as the one proposed by [
15], can allow for remote and distributed access to the data generated by the farm. Advances in artificial intelligence (AI) can accelerate data-driven decision making. For example, data can be used to alter inputs and environmental set points to increase yields or can be used to predict harvest timing. Typically, AI algorithms are proprietary, precluding the sharing of information and data-processing techniques. Without such sharing, critical advancements in decision-making capabilities across the entire industry are slowed. AI can also assist expert growers with decision making and adjusting environmental control set points, which can reduce the labor costs and resource consumption in the long run [
16].