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Linking research to knowledge transfer

lights inside a greenhouse

With over 20 years of research and extension services dedicated to helping both floriculture greenhouse growers and nursery producers to address their many production issues, the University of Guelph’s Dr. Youbin Zheng is well-known to growers in the ornamental horticulture sector. With a focus on plant production in controlled environments, over the years, Dr. Zheng’s research has addressed a broad and diverse range of production issues on behalf of growers across Canada.

If there can be a single common theme to describe Dr. Zheng’s many varied research initiatives, it would be best described as a quest to find sustainable, environmentally acceptable solutions to tackle present-day production issues. On behalf of the outdoor nursery plant sector, Dr. Zheng’s work has dealt with a diversity of issues, ranging from best fertilization practices to water quality improvement and irrigation practices. On behalf of the floriculture greenhouse sector, past projects have focused on growing media, fertilization, and irrigation technologies, with his current attention turning to the challenges associated with the recent trend to LED lighting, in addition to rootzone management strategies.

According to Dr. Zheng, just as important as the need for ongoing research to meet current production challenges is the ability to successfully transfer research knowledge to individual growers within a time frame that is appropriate for them. It is a task, he says, that begins with awareness, and he sees it as a responsibility of himself and the University of Guelph research team to use a broad range of measures to create that awareness.

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Dr. Youbin Zheng
University of Guelph

two plants in pots

Campanula stock plants grown under static LED vs dynamic LEDs (Right).

“There are many variables that will determine a grower’s need or decision to implement new production practices based on research results. Sometimes, research will result in recommendations such as modifications to fertilization practices, that are easy to adopt immediately. But often, our research results may necessitate complex or expensive upgrades which a grower is not able to implement immediately.”

It is Dr. Zheng’s quest to make growers aware that their first step to adopting new or improved techniques to their growing operations can be as simple as a call to himself. He is quick to point out that he is only a part of a larger knowledge base, and it is his role to coordinate that knowledge base for the purpose of effective knowledge transfer.

“Researchers don’t just conduct research projects, they are part of a complex information network,” says Dr. Zheng. “Besides our own research projects, we have the opportunity to attend international science conferences, providing us with access to the latest in scientific theories and research findings which all become part of our knowledge base.

“Also, an equally important component of most research projects is the opportunity to train what is known in the trade as HQPs, or highly qualified personnel. After graduation, many of these people are employed by the industry or perhaps other research institutions, but they almost always tend to stay in touch with the University. They too become important contributors to our knowledge base.”

Although a variety of venues are available to researchers to disseminate research results, Dr. Zheng notes that face-to-face opportunities are generally the most effective. He is almost always on the agenda of the Canadian Greenhouse Conference, and over the years has addressed the nursery grower sector at provincial association conferences across the country. He does not find it unusual to receive phone calls up to five years later, with conversations starting with a query such as “Remember that talk about water quality you gave at the BC CanWest conference a few years ago?” “That’s usually all it takes for me to be able to forward to them the research information they’re looking for,” says Dr. Zheng. “Conducting research is a relatively straightforward process that ideally results in a new set of data within a predetermined time frame. It is not nearly as easy to define or predict how and when there will be uptake of those results by growers.”

Dr. Zheng’s current research project “Use of LEDs to improve ornamental crop production” which is specifically designed to work in close consultation with the floriculture sector typifies his research philosophy.

For more than 10 years, greenhouse growers have been transitioning away from High Pressure Sodium (HPS) lighting in favour of LED lighting. While this new technology has proven to be both economical and environmentally friendly, the real motivation for this transition, according to Dr. Zheng, has been the substantial crop production benefits of LED lighting. The transition to LED lighting has been well-supported by the international research community, but there continue to be many knowledge gaps which have limited the widespread uptake of this technology by greenhouse growers.

Once gaps are identified, research typically starts at the University’s facilities where basic parameters can be established. They are then tested at the commercial greenhouse level, first on a trial basis and eventually expanded throughout the entire production facility.

According to Dr. Zheng, the real benefit of LED lighting is the ability to control the available colour spectrum. Simply stated, different plant species respond differently to various light regimens at certain stages of their growing cycle, so the question becomes, how do you use the light spectrum most effectively to meet their specific needs and growing requirements. As an example, different combinations of blue and red light will have an impact of photosynthesis and overall plant height. This variability is why we see such an abundance of LED lighting research around the world. It is also why final results and implementation will vary from grower to grower.

grow lights

Growth chamber used to test plants response to different LED light spectra.

“The objectives of our lighting project are clearly stated and straightforward. They include the impact of light quality on seed germination and performance and understanding how light quality can be manipulated to optimize cutting uniformity of stock plants. But there is a great deal of variability from grower to grower. Our real measure of success as a research team is having available reliable data which we can then help growers to adapt to their own specific growing operation.”

At the conclusion of his current research project, Dr. Zheng will add the following outcomes to his already extensive knowledge base on behalf of ornamental greenhouse growers:

  • Knowledge on whether we can, and how to use light to improve seed germination and seedling propagation for various ornamental crops in controlled environments.
  • Recommendations on lighting recipes for growing stock plants for the purposes of improving quality of cuttings and ease of harvesting.
  • Provide guidance on under what circumstances current commonly used HPS lamps can be replaced by LEDs to save energy and improve plant performance in greenhouse ornamental production.
  • Recommendations on how to use lower intensity, end of day light quality treatments to control morphology and flowering in ornamentals.
  • Knowledge on whether we can, and how to use pre-finishing light treatments for improving plant robustness during shipping and at retail environments.

The project Use of LEDs to improve ornamental crop production is part of the “Accelerating Green Plant Innovation for Environmental and Economic Benefit” Cluster and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO), private sector companies, and the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program, a federal, provincial, territorial initiative.

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Understanding how temperatures within plants affect their growth

plants inside a greenhouse

A Canadian research project the first of its kind in the world

In much the same way as a greenhouse can trap the sun’s energy, many plant shapes and structures are also able to capture solar energy. Air temperatures inside open bowl or parabolic-shaped flowers, for instance, such as poppy, buttercup or anemone can be several degrees higher than the ambient air temperature. The pubescence of willow catkins and similar plants can trap heat. And air temperatures inside enclosed flowers such as snap dragons can be as much as seven degrees Celsius warmer than the surrounding air temperature.

There is documentation to support the fact that these phenomena as related to floral structures have been observed as early as the 18th century. More recently, advances in technology have also shown that hollow plant stems also create a greenhouse effect, resulting in increased temperatures inside these stems. While there has been significant research on how ambient temperatures impact plant growth, there is little known about temperature variations caused by plant shape, and especially within hollow stems and other structures can impact plant development.

The research project “Temperatures within horticultural plants: Stems and flowers, explaining rapid growth,” by Dr. Peter Kevan (University of Guelph) and Masters’ graduate student Charlotte Coates, is studying how the micro-thermic regimes in floral stems and flowers may lead to practical applications in culture, aesthetics, and possibly even disease and pest control.

According to Dr. Kevan this is a very specialized area of research and the first of its kind in the world. “We understand the greenhouse effect in broad terms, but there is not a lot of information on micro impacts. The greenhouse is a large model, but even in such protected environments there is an incomplete ability to control many aspects of the environment.” It is suggested by Dr. Kevan and his team that the inter-relationships between the many factors at the macro-level (greenhouse) can be refined to apply at the within-plant micro level as they actually impact plant, growth maturation, reproduction and health.

Simply stated, says Dr. Kevan, a micro thermic regime is what is available in a very small space (micro = small, thermic = warmth or temperature and regime = environment). Focusing on the greenhouse floriculture sector, this research project is studying the impact of temperature variations caused by the micro-greenhouse effect inside hollow stems and other plant parts of both indoor and outdoor plants.

“We were fortunate that the original design of this project included both greenhouse and outdoor production,” noted Charlotte, explaining that the research team were able to continue their work in 2020 and into 2021 in the outdoor environment with some extra COVID protections in place.

peter kevan

Dr. Peter Kevan

University of Guelph

Charoltte Coates

Masters’ graduate student

Figure 1. Pumpkin (Cucurbita pepo L.) flower, top image taken using Forward Looking Infrared Camera that shows a thermal image of the surface temperature of the flower. The scale bar indicates what temperature (°C) each colour in the image matches to.

In the outdoor environment, various squash plant varieties as well as some native plants such as milkweed are good candidates to produce extensive data which can be further analyzed to determine the impact of both temperature and light on plant stem growth and seed development, with results to be translated to indoor production.  This outdoor research work is mostly conducted on private lands with the support and interest of co-operator growers in the areas of Guelph, Cambridge, KW, Peterborough and as distant as the Laurentians in Quebec.

Regrettably, some of the preliminary work which was conducted at the UofG greenhouses was lost as COVID access restrictions prevented the team from being able to monitor or maintain their initial research trials. Regardless, Dr. Kevan is confident that the remaining two years of the research project will nonetheless produce some interesting and ultimately useful results.

Although perhaps not overly sophisticated by today’s standards, it is largely due to the specialized high-tech equipment available to the research team that makes it possible to consider this project’s objectives and design.

Figure 2A. Gerbera daisies (Gerbera jamesonii) grown at Van Geest Brothers Greenhouse in Grimsby, ON, with dataloggers recording the ambient air temperature and stem temperature. The study plot contained Gerbera plants with varying degrees of hollowness, and the results showed that hollow Gerbera stems reached more extreme temperatures, both hotter and colder, than the solid stemmed Gerbera.

Figure 2B. Gerbera –  Prestige variety with fine wire thermocouple inserted into the stem recording the internal stem temperature, and one secured to the outside of the stem to record air temperature.

Thermocouples — temperature probes made from a pair of very fine wires, are used to measure the internal temperature of plant stems, in flowers and fruits. Battery powered datalogging hand-held units are able to monitor up to eight plants per unit for up to a week at a time. In the outdoor environment, radiation shields eliminate the impact of radiant heat from the sun, so that internal temperatures can be accurately compared to ambient temperatures.

Solar radiation meters are used to collect data on the incident amount of radiation. Spectrometers characterize the type of light that is present. Connected to a computer, they can produce a graph of the visible light spectrum and how much of each wavelength of light is present both outside and inside the plants’ hollow structures.

Thermal cameras are used to accurately measure plant surface temperature. “Thermal cameras have become an important tool for many greenhouse growers,” notes Charlotte, “but the less expensive models used by growers do not always provide completely accurate data.  One of the objectives of this project has been to provide growers with data they can use to better interpret their own thermal camera readings.”

Designed to be of benefit to commercial floriculture greenhouse growers, with an initial focus on high value gerbera production, research trials are currently underway thanks to the generous cooperation of a Grimsby, Ont.-based greenhouse grower. Additionally, there is an expectation that the research results will also be of considerable interest to the edible horticulture sector. Some preliminary but not yet documented observations on the impact of temperature variations inside hollow plant parts have been noted in greenhouse grown bell peppers in a cooperator operated greenhouse in Kingsville, Ont.

Figure 3A & 3B. Various colours of snapdragons (Antirrhinum majus) growing in the experimental greenhouse at the University of Guelph. Temperatures within the enclosed petals of the flowers are up to 4.5 ˚C warmer than ambient air.

The team’s work in the outdoor environment has also pointed to a tie-in to research work underway to preserve the pollinator populations, noted Charlotte. Floral temperatures influence pollinator behaviour, as well as floral humidity, presentation, fertilization and seed production. Using micrometeorological techniques in various part of plants allows for deeper insight into how temperature affects pollinator and plant relationships. This is especially important to consider for phenology, as plants and pollinators are dependent on each other to be there simultaneously. Thus, it is understandable that temperature regimes affect pollinating systems in concert with one another rather than on plants and pollinators separately.

Kevan writes: “I am grateful to COHA for their support of a project that I know many people may consider to be a little outside the norm, but I believe the findings of this and follow-up research work will put Canada on the map. Already we have garnered interest from the science community around the world, including U.S., Russia, Australia, Europe and India.”

Figure 4 (top or left): Infrared image of Gerbera flowers from Van Geest Brothers Greenhouse. Average surface temperature of flowers: 22.5 C, the average surface temperature of stems: 20.7 C, and average surface temperature of leaves: 20.1 C. (Right or bottom): Colour image of the study flowers.

This project is part of the “Accelerating Green Plant Innovation for Environmental and Economic Benefit” Cluster and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO), private sector companies, and the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program, a federal, provincial, territorial initiative.

Related LInks

International Journal of Biometeorology
(2018)
Short communication: thermal regimes in hollow stems of herbaceous plants—concepts and models
Peter G. Kevan1 & Patrícia Nunes-Silva1 & Rangarajan Sudarsan2

Bulletin of the North-Eastern Scientific Center, Russia
(2019)
Temperatures within flowers & stems: Possible roles in plant reproduction in the north
Peter G. Kevan1, Evgeniy A. Tikhmenev2, Patricia Nunes-Silva1

OPEN ACCESS GOVERNMENT, University of Guelph
(2019)
How plants regulate their body temperatures: Implications for climate change science & policy
Peter G. Kevan, University Professor Emeritus at the School of Environmental Sciences, University of Guelph

www.researchoutreach.org
(2019)
Secrets of the Stalk: Regulating plant temperature from the inside out
Dr. Peter Kevan

Annals of Botany
(2019)
The thermal ecology of flowers
Casper J. van der Kooi1,*, , Peter G. Kevan2 and Matthew H. Koski3,
1Groningen Institute for Evolutionary Life Sciences, University of Groningen, Groningen, the Netherlands, 2School of Environmental Sciences, University of Guelph, Guelph, Canada and 3Department of Biology, University of Virginia, Charlottesville, VA, USA

Thermochimica Acta
(2020)
In situ calibration of an uncooled thermal camera for the accurate quantification of flower and stem surface temperatures
Ryan A.E. Byerlay a,*, Charlotte Coates a, Amir A. Aliabadi b, Peter G. Kevan a
a School of Environmental Sciences, University of Guelph, Guelph, Ontario, Canada b School of Engineering, University of Guelph, Guelph, Ontario, Canada

Polar Biology
(2020)
Heat accumulation in hollow Arctic flowers: possible microgreenhouse effects in syncalyces of campions (Silene spp. (Caryophyllaceae)) and zygomorphic sympetalous corollas of louseworts (Pedicularis spp. (Orobanchaceae))
Peter G. Kevan1

Newsletter of the Biological Survey of Canada
(December 2020)
Warm & Comfortable within Hollow Stems, Leaf-mines and Galls: Little known habitats for Entomologists & Botanists to explore
Peter G. Kevan1, Charlotte Coates1, Patricia Nunes Silva2, & Marla Larson1
1School of Environmental Sciences, University of Guelph, Guelph, ON N1G 2W1, 2 Programa de Pós Graduação em Biologia, Escola Politécnica, Universidade do Vale do Rio dos Sinos (UNISINOS), São Leopoldo, Brazil, 93022-750.

YouTube video by Scientia Global
Exploring Micrometeorology in Plants

Irrigation efficiency in nurseries: towards a more sustainable approach

irrigated plants inside a hoophouse
Optimal irrigation for model species. Laval University Nursery.
pic of a man
Dr. Charles Goulet

Aided by an abundance of research, nursery container production has matured significantly over the years, resulting in ever-increasing categories and size ranges of plants grown in containers.  While we have also seen corresponding improvements in irrigation technologies in that same timeframe however, the complexity of containerized nursery production means that nursery growers in Canada continue to rely on inefficient overhead irrigation practices.

The constant movement of pots, necessitated by a multitude of factors ranging from decreased inventory during the sales season to winter storage requirements, adds to the already higher costs associated with more efficient drip irrigation technologies. Additionally, the lack of automation typically available for overhead systems means that watering decisions are based primarily on timed irrigation intervals and visual clues to plan irrigation scheduling. The result can be either under or over watering, both of which can have detrimental impacts on plant growth and quality. More recently, reliable access to water has also become problematic for many growers, making water conservation an increasingly important priority.

A research project currently underway by Laval University’s Dr. Charles Goulet entitled Irrigation efficiency in nurseries: towards a more sustainable approach, will offer nursery growers the ability to optimize their irrigation practices by delivering the right amount of water at the right time and to the right plant. This project is part of the “Accelerating Green Plant Innovation for Environmental and Economic Benefit” Cluster and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO), private sector companies, and the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program, a federal, provincial, territorial initiative.

This current project continues work started by Dr. Goulet under the Growing Forward 2 (2013 – 2018) Cluster program which focused on the use of wireless tensiometers to measure the water available to the plant, thereby allowing for precise irrigation scheduling based on plant needs. This high-tech wireless web-based technology was paired with drip irrigation systems, with or without capillary mats. Both water use and plant growth were measured to determine the impact of each strategy. The researchers were able to conclude that precision irrigation has the potential to significantly reduce water use in nursery plant production as wireless tensiometers provide reliable data to guide irrigation scheduling decisions. Additionally, wireless technology provides considerable operational flexibility by providing the grower with easy access to data.

irrigation at a nursery
Optimal irrigation with automation at the commercial nursery site.

A plant’s water needs can vary widely from species to species, however monitoring the individual needs of each species with tensiometers would be both complicated and expensive. As a result, finding plants with similar watering requirements which can be grouped or clustered in the nursery environment became an important component of this phase one research project. To facilitate the decision-making process on watering practices, such as frequency and volume of water, a series of reference plants representing a good diversity of watering requirements, was determined. As well as being an essential part of the research process, reference plants facilitate the ability for clustering plants according to their very specific cultural requirements.

Initial research was conducted at the University’s production facilities, which incorporates the use of wind tunnels to mitigate as much as possible the impacts of weather events such as rain, temperature and wind, to the research data.  However, as the project was eventually moved to a commercial nursery setting, it became necessary to make several modifications to the project’s overall design. The use of wireless tensiometers provided reliable data to the nursery and the research teams, but the challenges associated with weather factors, especially wind or the knowledge of a pending rain event, ultimately pointed to the option of adopting a hybrid approach to irrigation scheduling.  Ultimately, the final decision to irrigate was made by the nursery’s production team, guided by data provided by the tensiometers.

plants in post with tubes in them
Clustering experiment at Laval University Nursery.

The data collected and lessons learned from the first phase of this research project have largely dictated the design and objectives of the current phase. According to Dr. Goulet, “Due to cost factors, nursery growers will find it necessary to use overhead irrigation systems, but there is a need for precision irrigation management that will allow growers to make the most of their existing systems. To be truly efficient in terms of water use, the different irrigation strategies need to be expanded to meet the requirements of the species and the climate.”

The first objective of the current project is to improve irrigation management in the nursery setting through the use of wireless tensiometers. Specifically, the research will seek to optimize the use of tensiometers to support the practice of clustering. The research will also evaluate how the amount and frequency of watering can influence plant growth. Using several species with very diverse watering requirements, in combination with different irrigation management strategies, (eg: comparing different volumes of water and different irrigation intervals) will help researchers to determine water use and the impact on plant growth. More precise data will be obtained in the first two years by conducting the experiment at the Laval University research facilities and the data obtained will be used to determine irrigation strategies when the research is transferred to a commercial nursery setting.

field grown plants in pots
Soil tension measurement at the commercial nursery site.

Research will also continue into expanding the use of clustering practices. In order to best meet the very diverse watering needs of the very wide range of species that make up the inventory of most growers, the number of reference species will be increased. According to Dr. Goulet, “The clustering process is not as simple as it seems, as the factors that impact overall plant growth include factors such as frequency of watering as well as amount of water applied with each irrigation event. Clustering is not as straightforward as determining plant species with high, medium and low water requirements.”

It will be the objective of the project to increase the list of reference species from the current 10 to a total of 15 species, and the corresponding clustering recommendations will be increased from 50 to 100 species. To ensure accurate data, this component of the research project will use the wind tunnel facilities at Laval University to mitigate the impacts of natural weather events.

shrubs growing in pots in an nursery
Optimal irrigation for clustering species. This photo shows the irrigation mats which were used in the Cluster 2 project; they are not a part of the current project.

To truly live up to its potential, precision irrigation must be supported by a solid automation process. Over the past few years, many models have been developed that integrate various technologies to optimize the irrigation process and the third objective of this project will determine the most useful parameters to automate irrigation in the commercial nursery setting. The research team will evaluate if irrigation controlled by evapotranspiration measurements will provide similar results to irrigation controlled by the new generation of wireless tensiometers, as well as the potential to integrate these technologies.

Again looking at the need to provide practical recommendations for use in the commercial nursery setting, the research will evaluate the various parameters which could be added to the automation process with data obtained from external weather sites, including daily rain forecast, wind speed (to delay a planned irrigation event if the wind is too strong) and evapotranspiration predictions. The ultimate goal is to provide growers with various options depending on their existing systems and their resources to acquire new irrigation technologies.

Weather station
Weather station for irrigation automation.

New research project focuses on improving standards for effective pond management

two people on a dock on the water
One of five mesocosms or in-pond cells, is installed at a nursery location in the summer of 2019.

Nursery growers have implemented a variety of solutions, with varying degrees of success, to reduce the excessive biological growth usually found in recycled water irrigation ponds. This growth is responsible for the clogging of intake filters and subsequently, expensive maintenance costs. With little in the way of research or scientific data to support alternative methodologies and no clear standards of practice for effective pond management, there is a critical need in the sector for reliable information on affordable and sustainable solutions to improve water quality.

Several projects focusing on water quality are currently being funded through the COHA research cluster. Minimizing horticultural impacts on surface water quality to encourage re-use through enhanced pond management is one of these projects being led by Dr. Jeanine West of PhytoServ. With an end goal of helping growers to manage their irrigation costs through environmentally appropriate and sustainable improved pond management strategies, this project is part of the Cluster Project and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO) and by the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program

According to Dr. West, “Almost all nursery growers use recycled water and it is inevitable that they experience issues related to excessive growth of aquatic weeds, algae and cyanobacteria, also known as blue green algae, especially in the warmer summer months. This research project will focus on investigating new methods of controlling the flow of nutrients and especially phosphorous into ponds, and to study various in-pond treatments to improve overall water quality.”

The research project has been designed to take into consideration the requirements of three very diverse audiences. The general public’s increasing concern for the environment is further reinforced by the aesthetics and risks of algae and cyanobacteria in our ponds and lakes. Various ministries across Canada, at both the provincial and federal levels now have in place application and discharge regulations to control the excessive use of nutrients, especially phosphorous and nitrates. And farmers have a need for effective and sustainable pond management strategies that will help them to meet environmental regulations while at the same time mitigating the costly impacts from clogged irrigation systems.

The first phase of the project, completed in 2019 with considerable input from a Technical Advisory Committee, was to design, construct and test a reliable experimental design which would allow for effective comparisons of various water quality treatments. “Arriving at a suitable project design was no easy task,” explains Dr. West, “as it needed to be bigger than a bench scale design, but we had physical and budgetary constraints to consider as well.”

A total of five nursery locations across Ontario were selected as research sites and each one brings unique site challenges and therefore opportunities to the project. “As we’ve come to expect, each of the participating nurseries have been very cooperative in helping us to install the various on-land or in-pond structures necessary for this project,” notes Dr. West adding that several nursery sites have assisted in the installation of media beds to study the impacts of pre-pond treatments.

With a stated objective of employing a systematic evaluation and comparison of various pond management tools, the project devised by Dr. West and her research team consists of up to five mesocosms (in-pond enclosures, or test cells) at each test location. Each mesocosm has a volume of 1-2 m3 (depending on the pond depth), is framed with PVC tubing to allow for flotation, as it was important that water be able to flow around the sides and bottom of each cell. The wall material eventually chosen by the advisory team is a plastic material commonly used as a wind barrier. “Our technical advisory team struggled with the concept of permeability and its ultimate impact on project results. We ultimately determined that the most accurate data would be realized by a limited exchange of water between the mesocosm and the pond water.”

At each site, the project is designed to test up to five mesocosms including a control, and up to four of the following treatments: submerged aquatic macrophytes, aeration through mechanical bubblers, a phosphorus-binding media, vegetative shade through the use of duckweed, and mechanical shading through the use of shade cloth.

At one farm, the research team has also installed a series of PhytoLinks, or floating planted islands which, similar to constructed wetlands, are specifically engineered to improve water quality. The PhytoLinks™ were installed in channels within a narrow pond, with one channel empty (control), one with two PhytoLinks™, and one with two PhytoLinks™ and a suspended material that serves as a surface for growth of periphyton, a complex microorganism population known to assist in nutrient uptake.

Any research project conducted in outdoor environments is subject to many unpredictable variables and Dr. West and her team have encountered the usual challenges.  With several of the research sites being located far from reliable electrical sources, Dr. West found herself becoming an expert in the design and installation of small solar systems to power an aerator.

An exceptionally hot summer in 2020 resulted in excessive water use, impacting the water depth in some ponds. And of course, this year the team found themselves dealing with the ultimate disruptor – the unforeseen impacts of a global pandemic.

As most of the work planned for 2020 has been outdoors and in low-contact environments, Dr. West and her team have been able to successfully mitigate potential impacts of the impacts of Covid19. Working with collaborator Dr. Ann Huber, the team was fortunate to be able employ qualified family members as technicians, making it possible to comply with Covid19 workplace guidelines.

The limited water testing conducted in 2019 was mostly to validate the research design and system installations. Actual water sampling to record and analyze the effectiveness of each treatment, is being conducted throughout 2020 and 2021. A YSI meter or sonde-type multi probe is used to test and record various parameters such as temperature, pH levels, dissolved oxygen levels, chlorophyll a and phycocyanin levels, turbidity and conductivity. Further water and sediment samples are sent to A&L Canada Laboratories to test for nutrient and chemical levels. Grab samples of algae, aquatic plants, and cyanobacteria are collected regularly and diagnosed by Dr. Ann Huber of the Soil Resource Group to look for other trends and indicators of pond health. Some of the most revealing results to date are the inadequacy of water quality indicators in some of the traditional measurements, and the need to explore a range of parameters and testing approaches to truly get a picture of overall pond health.

Confirms Dr. West, “We will share our results with the industry at the end of the season, but with the caveat that there are too many variables at play in any single year, in particular seasonal weather conditions and changes in production practices, to make those results conclusive. Even the two full years of testing we will be able to conduct as part of this project will not be sufficient to provide definitive results but will hopefully point us in the right direction. Ideally, we should be looking at an analysis after five years of testing; hopefully we will be able to extend our experiment past the time restrictions of this research project.”

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Hybrid Treatment Systems show promise as an effective water filtration method for greenhouse and nursery growers

nursery field
An in-ground installation of a permanent hybrid treatment system. Advance use of the portable HTS makes it possible to optimize the media sequence specific to each grower’s needs, for the removal of relevant PGRs and pesticides as well as nutrients and fungal populations.

Water recycling is increasingly recognized as necessary to deal with the dual issues of water availability and the ever-evolving environmental restrictions faced by greenhouse and nursery producers related to water run-off. Although conservation has become an essential objective, the practice of using recycled water poses many risks and challenges. Recirculated water often contains nutrient, pesticide and plant growth regulator (PGRs) residues which could negatively affect crop production. Research is being conducted around the world to improve recycled water quality, and several projects currently being funded through the COHA research cluster are especially focused on sustainable and affordable solutions.

Enabling re-circulation with hybrid treatment systems is the next phase of longer-term water research being led by environmental microbiologist Dr. Ann Huber of the Soil Resource Group. This project is part of the Cluster Project and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO) and by the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program.

Simply stated, a hybrid treatment system (HTS) is a non-vegetated, constructed approach to the filtration and cleansing of water through a series of organic and inorganic media filters. Explains Dr. Huber, “An HTS is the next step in water cleaning technologies as a successor to previous research into constructed wetlands and woodchip bioreactors. While those individual approaches have been found to be useful for some pathogen and nutrient removal, there are many external factors that can impact their usefulness.”

Earlier projects by Dr. Huber have already proven the effectiveness of hybrid treatment systems in the removal of certain nutrients, including nitrogen and phosphorus, and fungal pathogens. The objective of the current project is to expand those research findings to include other greenhouse production chemicals and especially plant growth regulator (PGR) residues, which have been shown to impact plant growth even when found in very low levels of recirculated water.

Due to their typical four- to five-year funding cycle, research projects are generally defined by very specific start and end dates. However, as water issues within the horticulture sector have long been a top priority for both governments and industry, Dr. Huber has succeeded in making her research into effective water re-circulation technologies a mostly continuous long-term field of study, beginning in 2007.

Besides the very obvious benefits of providing the industry with continually updated research results, the continuity of Dr. Huber’s research projects also provides significant economic efficiencies. Two portable pilot units constructed as part of a previous research project funded with support from Flowers Canada Ontario (FCO) at a cost of $50,000 each are now an integral component of this next-phase study.

According to Dr. Huber, “As far as I’m aware, there are no other pilot-scale systems such as these being used for water re-circulation research.  The system is designed to have the capacity to test up to eight mineral or organic media in any combination or alternatively, test the same media at different flow rates and retention times. These pilot systems provide us the opportunity to test commercial greenhouse water on-farm without risking the health of the crop.”

The original focus of Dr. Huber’s work was to study the effectiveness of woodchip denitrification bioreactors on the removal of various water pollutants. Although she continues to be optimistic about the use of woodchip as an effective and economical treatment for some contaminants, the current research project also incorporates a number of mineral media, including pea gravel, wollastonite, filter sand and a slag/gravel mix to expand the range of undesirable components that can be removed within a single ‘hybrid’ treatment system.

And, although other researchers are studying organic systems (e.g. woodchips) which employ an aerobic process to remove pesticide and PGR residues, the research work being conducted by Dr. Huber and her research team is an ongoing study of an anoxic approach in order to retain the current treatment system’s capacity to remove nitrogen and fungal pathogens.

With the current research project reaching the half-way mark during the fall of 2020, Dr. Huber and her team have been able to successfully mitigate the impacts of Covid19 that might have otherwise negatively impacted their progress.  Most of the work has been outdoors and in low-contact environments, and both Dr. Huber and collaborator Dr. Jeanine West were also extremely fortunate to have access to qualified family technicians.

Although the preliminary research results are not conclusive, to date the data collected by the research team, based on water quality analysis and results of bioassay testing indicate very promising results. The team has been able to demonstrate the removal of a range of PGRs and pesticides by several of the individual media in batch studies, and the bioassay results demonstrate a positive growth response to PGR removal. Interestingly, the bioassay tests are capable of detecting the presence of some PGRs at concentrations lower than the sensitivity of laboratory testing.

Because this is a very new technology, only three growers — two floriculture greenhouses and one nursery grower — are currently using hybrid treatment systems to treat recycled irrigation water. The research team is confident that these early results will meet their original objective, to provide growers with a valuable and affordable approach to realize clean recycled water for their production needs.

READ MORE.

Research team:

Dr. Ann Huber, Soil Resource Group

jeanine westDr. Jeanine West, Phytoserv

Technician Elizabeth Huber-Kidby prepares to take water samples from each of the eight cells, each one containing a different filter media. All water samples are sent to the University of Guelph laboratories for PGR and pesticide testing, and to SGS Agri-Food Laboratories (Guelph) for nutrient analyses.
The two portable HTS trailers, currently installed at Walden Greenhouses in Wainfleet, ON were previously designed and constructed for a previous phase 1 pilot project.
A bioassay for paclobutrazol (Bonzi™): Broccoli seeds are planted into vermiculite soaked in the test solutions, ranging in concentrations from 6 to 400 micrograms per litre (parts per billion). Fourteen days after planting, the hypocotyl length of each plant is measured and compared to the control plants (no PGR).
two women inside a work shed
pipe inside a cistern in the ground
rolls of pipes and buckets in a work shed

Utilizing high tech to bring native perennials to the marketplace

Within the ornamental sector, an ever-evolving environmental movement has resulted in the demand for more ecologically responsible plants and plant production techniques. The demand for low-maintenance, drought resistant, low-input plants has converged with the trend to the use of more natives and pollinator plants in our gardens and landscapes.  However, as any garden centre owner or landscape designer knows all too well, aesthetic attributes on the sale’s bench or in the landscape plan are all-important.  And, from the perspective of greenhouse growers, cost-effective propagation and production technologies are an absolute must if these otherwise desirable plants are to find a way to the consumer’s garden.

Exploring a variety of integrated systems designed to overcome the obstacles that are generally associated with the efficient production of native species, “Integrated techniques for efficient breeding, production and transplant survival of unique ornamental species” is an ambitious research project currently underway at the University of Guelph.  This project is part of the Cluster Project and is funded by the Canadian Ornamental Horticulture Alliance (COHA-ACHO) and by the Government of Canada under the Canadian Agricultural Partnership’s AgriScience Program.

Bringing these diverse and lofty goals to this project is achievable largely through a unique collaboration of expertise and facilities.  Leading the project, Dr. Alan Sullivan has over 25 years of experience in horticultural breeding with the past 10 years focused on breeding and physiology of native ornamental species that are tolerant to low water and low nutrient conditions.

The project’s co-lead, Dr. Praveen Saxena, has spent 25 years working with stakeholders of the floriculture and horticulture sectors to develop efficient protocols for rapid in vitro multiplication of a diverse range of ornamental and medicinal plants.  Dr. Saxena is also the director of the GRIPP Institute, a University of Guelph based organization led by himself and Dr. Sullivan dedicated to the preservation of endangered plant species. GRIPP makes some sophisticated facilities available to this project, including cryopreservation technologies.

With a goal of developing improved varieties and germplasm of existing plant species that already exhibit the required environmental and aesthetic attributes, the project relies on the expertise of Rodger Tschanz, manager of the University’s ornamental trial garden program.  Rodger’s many years of on-the-ground supervision of various trial garden programs and other related horticultural projects makes him uniquely qualified to help identify native plants with superior ornamental qualities that are adapted to environmentally challenging conditions.

Focused on two impressive goals – the accelerated breeding and introduction of exiting new perennial plants to the marketplace, together with the development of efficient propagation and production technologies – both Dr. Sullivan and Dr. Saxena are equally excited about the potential economic impact to all sectors of the ornamental industry.  “It is our goal to make available to the Canadian ornamental industry a whole new selection of commercially available native plants that support a strong marketplace trend,” said Dr. Sullivan.

Although off to a promising start, keeping the project on track during the COVID-19 shutdown has proven to be a challenge for Dr. Sullivan and Dr. Saxena.  “The COVID impacts were severe,” noted Dr. Sullivan.  “We are grateful to the University for their positive response to our various applications to continue our research, even on a limited basis, as we had plants that had come out of cold storage and were coming into flower for crossing if we were to keep the project alive and somewhat on track.”

The project team is now coping with a number of unforeseen expenses.   Additional greenhouse space is required to accommodate social distancing requirements, and extra costs incurred for more vehicles and trips due to COVID restrictions continue to mount.  These unanticipated costs are nonetheless a far better scenario than the alternative of having to start over again.

With some ingenuity and creative solutions, the first objective of the project remains on track.   Employing both traditional and advanced breeding methods, new and improved varieties of pre-selected species will be developed and further trialled in the UofG trial garden network.   The 10 species selected for this program, include Lobelia, Helinium, Physotegia, Allium, Penstemon, Monarda and Aquilegia.  Not included on the original plant list, Dr. Saxena is excited that he has since secured several native and exotic orchid species to add to the collection.

Dendrobium spp. in culture currently being used to develop orchid propagation technology.

Efficient production will be key to ensuring commercial success of these new varieties.  Drawing on research results and resources made available through GRIPP, a variety of approaches will be utilized, including an expansion of research already underway to study the ability of indolamines compounds to enhance plant growth and survival.  Optimized tissue culture propagation systems will improve mass production efficiency and cryopreservation techniques will help in biobanking of important genotypes of endangered and horticulturally important species.

As Dr. Saxena pointed out, despite its devasting impacts, the pandemic has brought a whole new focus to the importance of our homes and our gardens.  “A look at the impact of COVID on home gardening shows the importance of ornamental horticulture.  New varieties and especially those that meet our demand for ecologically sound plants will be important to drive the sector into the future.”

Organization: University of Guelph

Research team:

Dr. Alan Sullivan, Professor, Plant Agriculture

Dr. Praveen Saxena, Professor, Plant Agriculture, and Director of GRIPP

Rodger Tschanz, Technician, Manager UofG Trial Garden

Penstemon hirsutus
Aquilegia canadensis
Lobelia siphilitica
Allium cernuum
Lobelia cardinalis