I’ve been hearing a lot about spray drones; can I spray pesticides by drone on my farm now?

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By Ashley Ammeter, Whole Farm Specialist, Manitoba Crop Alliance

This topic has definitely been getting a lot of attention lately!

The short answer is yes, in some cases, agricultural pesticides can now be applied by drone in Canada. However, there are important rules and regulations to follow, drone spraying is not without risk and there are some unique considerations that are important to understand.

What changed?

On June 10, 2026, the Pesticides Regulatory Directorate (PRD) of Health Canada (formerly the Pesticide Management Regulatory Agency or PMRA) issued a Letter of No Objection, an interim measure which allowed the application of pesticides by drone in some circumstances, and was intended to apply until a final policy decision could be released.

On June 30, 2026, the PRD of Health Canada finalized their policy, allowing application of pesticides by drone for any product already registered for conventional aerial application. The full details of the new policy are available here.

Licenses and certification

If you’re considering drone spraying, there are several licenses and certifications you need to be aware of.

In Canada, drones weighing more than 250 g (including spray drones) must be registered, and the operator must have a drone pilot certificate from Transport Canada.

In Manitoba, commercial pesticide applicators must have a pesticide applicator license, but farmers applying pesticides on their own farms are exempt from licensing.

Always read and follow the product label

It is important to remember that pesticide labels are legal documents. Regardless of how you’re applying the pesticide, always read the label carefully.

If the product label allows aerial application to the crop you wish to spray, you may be eligible to spray by drone. You must follow all label directions for aerial application, including spray volume, application rate, droplet size, spray buffer zones or any other instructions. The only exception is that statements on nozzle distribution (ex. “Nozzle distribution along the spray boom length MUST NOT exceed 65% of the wing- or rotor-span”) are not applicable to drones.

If the label states “DO NOT apply by air” or “DO NOT apply by Remotely Piloted Aircraft Systems (RPAS)”, you may not use a drone to apply that pesticide. If the label requires a closed cab for ground application, you cannot apply that product by drone unless a similar “closed cab” system is used for the pilot.

In addition, the person who mixes and loads the pesticide must be different from the drone pilot. Mixers and loaders must wear the personal protective equipment (PPE) required for mixer/loaders by the pesticide label, and the drone pilot, visual observers, or anyone handling the drone must wear the PPE required for ground application. 

How well does drone spraying work?

This is where things get complicated. Drone spraying can be a useful and effective application method, but achieving consistent efficacy requires an understanding of some of the factors that make drone applications unique.

Sprayers 101, a non-profit website providing information on agricultural spraying, has several excellent articles focused on pesticide application using drones. I highly recommend their resources! Their article Safe and Effective Pesticide Application using Drones provides an excellent overview of factors to consider before jumping into drone spraying.  

One of the biggest challenges is determining a drone’s effective swath width. A drone’s swath width can vary significantly depending on the drone design, the height and speed of travel, spray droplet size, and weather conditions. The result is that the swath width that gives you adequate pesticide coverage and efficacy may differ from the values reported by manufacturers or determined by spray droplet deposition testing. Calibrating your equipment and measuring swath width under your conditions and spray settings is critical to preventing uneven pesticide coverage.  

Drift is another important consideration. Like with other aerial application methods, drone sprayers can be particularly susceptible to drift if conditions are not suitable. In addition, most spray drones use rotary atomizers, which differ from conventional nozzles. Most conventional nozzles follow an international standard, producing known droplet sizes at given flow rates and pressures. Rotary atomizers, however, are not standardized and may produce larger or smaller droplets than an operator expects. Understanding your equipment and application settings is critical to minimizing the risk of drift.

The bottom line

If you’re thinking of using a spray drone, whether you plan to operate it yourself or hire a custom applicator, make sure you understand the regulatory requirements and application best management practices. Like any spray operation, success with drone spraying depends on taking the time to do it right.  

For anyone interested in learning more, Sprayers 101 has many excellent resources. The articles linked below are a great starting point to learn about pesticide application with drones:

I think I have hard water, should I be adding AMS to my herbicide spray mix?

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By Ashley Ammeter, Whole Farm Specialist, Manitoba Crop Alliance

Water quality can play a significant role in pesticide performance, but it’s a consideration that often flies under our radar until a herbicide application doesn’t work as well as we hoped. If you suspect hard water, adding ammonium sulphate (AMS) could the right call, but first it’s important to know what’s actually in your water. 

Start by testing your water

The first step in managing potential spray water issues is to test your water. While it’s generally good practice to test your water quality, it’s even more important if you suspect that poor water quality is affecting the performance of your herbicides. Agricultural spray water analyses are offered by many accredited agricultural laboratories, such as AGVISE Laboratories, A&L Canada Laboratories, Central Testing Laboratory and Horizon Lab.

Once you have a water quality test, Sprayers 101 has a helpful article on how to make sense of your water quality test results.

Why is hard water a problem?

Hard water contains high levels of positively charged minerals such as calcium (Ca2+), magnesium (Mg2+) and others. These minerals bind to herbicide molecules, preventing them from being absorbed by the plant and reducing efficacy.

Glyphosate (e.g., Roundup) is commonly associated with hard water antagonism, but hard water can reduce the efficacy of all weak acid herbicides (found in Groups 1, 2, 4, 6, 9, 10, 14, 19 and 27).

How much hardness is too much depends on the herbicide, rate and water volume you’re using. For glyphosate, Bayer suggests a hardness limit of up to 700 ppm, when using higher rates or lower water volumes.

Should you add AMS?

If you have hard water but don’t have access to an alternate water source, adding AMS is an effective strategy.

When added to spray water before your herbicide, the negatively charged sulphate ions in AMS tie up the hard water cations before they can antagonize the herbicide. To calculate how much AMS to use, Sprayers 101 has a helpful calculator, but many agriculture labs that offer spray water tests will include AMS recommendations in your test results, and herbicide labels or the Manitoba Agriculture Guide to Field Crop Protection often include water quality recommendations.

In some cases, reducing water volumes and/or increasing your herbicide rate can help counteract the effects of hard water, but always make sure to stay within label guidelines. 

Other water quality issues to be aware of

Along with hardness, there are a few other water quality factors to keep on your radar:

  • Dirty water (turbidity): Particles of soil and organic matter can bind herbicides and reduce performance. Clean water is particularly important for herbicides that are known to strongly bind to soil, such as glyphosate and diquat (e.g., Reglone).
  • Bicarbonates: Bicarbonate ions can inhibit herbicides, particularly the Group 1 “dims,” including clethodim (e.g., Select, Centurion) and tralkoxydim (e.g., Achieve) and the Group 4 herbicides MCPA amine and 2,4-D amine.
  • pH (acidity or alkalinity): The pH of your spray water can impact pesticide solubility and breakdown. Unless recommended on the product label, it is generally not advised to adjust the pH of your spray solution. For those interested in learning more, Sprayers 101 has a helpful article.

My last piece of advice: always read and follow the directions on your pesticide label. While they can be long and unwieldy, the pesticide label includes key details on how to use your herbicide safely and effectively.

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