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A Conversation with Dr. Steve Shirtliffe

University of Saskatchewan

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Activity C.32: Integrating weed control for organic pea and lentil production

Activity C.33: Novel cultural and mechanical weed control for flax

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Can you tell us a bit about yourself?

I鈥檓 a professor here at the University of Saskatchewan, and have been here since 1998. I grew up on a grain and oilseed farm in Manitoba. I鈥檝e been doing organic research here since 2000-2001, and I refer to myself as a weedy agronomist. My specialty is looking at ways of controlling weeds using agronomic, as opposed to pesticide, methods. Part of my program is organic, while the other part of my program is essentially, in many cases, using tools, techniques or methods that many people would consider organic in nature to control weeds in other systems, such as controlling herbicide resistant weeds or weeds where there are no pesticides available.

Can you briefly explain your Research Activities in Organic Science Cluster II (OSCII)?

Let鈥檚 start with Activity C.33, the flax intercrop project. This activity is looking at novel ways of growing flax, which is a real challenge as an organic crop because it is not very competitive at all. It鈥檚 a short crop, and it produces these tiny little leaves that don鈥檛 shade out much light, so it has a real problem with weeds. In this research we鈥檙e actually evaluating a method that a grower suggested to us that they use for organic flax production, which is using a fall rye cover crop that is seeded in the spring between the rows of flax. The idea is that the fall rye cover crop needs to have a cold period for it to vernalize (switch from vegetative to reproductive), so if we seed it later in the spring, the fall rye won鈥檛 get cold, so it won鈥檛 vernalize and will stay low to the ground and shade out the weeds, and the flax can grow up in between it. We鈥檙e comparing fall rye with some other winter cereals, we鈥檙e also looking at winter oats and winter wheat, to see if fall rye is the best. And, we鈥檙e also comparing the intercrop to mechanical weed control, which we鈥檙e doing a lot of work with as well, looking at inter-row cultivation and rotary hoeing as methods of weed control.

In Activity C.32, we鈥檙e trying to optimize mechanical weed control for organic pulse production. Pulses are food legumes, and we鈥檙e looking at lentil and pea. We鈥檝e looked at quite a few tools for in-crop weed management in pulse crops: I鈥檝e looked at in-crop harrowing with Eric Johnson, we鈥檙e also looking at rotary hoeing, and now we鈥檝e started to look at inter-row cultivation, which is the focus of a graduate student, Katherine Stanley, as part of this OSCII project. So, the first part of the project is looking at inter-row cultivation and essentially figuring out what鈥檚 the optimum timing in terms of crop tolerance and weed control. The second part of the project will actually start to compare the different types of mechanical weed control. This really stems from a question that I always get from farmers who say 鈥淵ou know, you鈥檝e talked about a rotary hoe, you鈥檝e talked about a weeding harrow, you鈥檝e talked about inter-row cultivation. If you had to pick one machine, which one would you pick?鈥� And I鈥檓 always humming and hawing and I don鈥檛 really know what to say, because we鈥檝e never really compared them to each other. So, that鈥檚 what we鈥檙e going to be doing, we鈥檙e going to compare them to each other and in combination. We may end up saying that if you have a rotary hoe, you also need an inter-row cultivator to make it really work well. Or maybe something else, we don鈥檛 know the results yet! It鈥檚 all very practical, kind of seat of the pants agronomy stuff, which we tend to get really good feedback about when we go to producer meetings - there鈥檚 a strong demand for this information out there.

What brought you to this research, and what excites you the most about these projects?

The farmers really brought me to this. And, my interest in non-herbicidal weed control - people always doubt its efficacy. A lot of people call it integrated weed management, but I don鈥檛 call it that anymore, because I think that tends to put most farmers off of it. I call it using our agronomy to control weeds, because every farmer changes their agronomy.

So what brought me to it? It鈥檚 an interest of mine. I guess I like weeds to a certain extent. I don鈥檛 like working with herbicides, maybe somewhat philosophically, and somewhat because it鈥檚 really boring research since usually they work really well, it鈥檚 too easy. I always refer to organic weed control as the double black diamond slope of weed control. Sometimes there鈥檚 big wrecks, but it can be very satisfying when you get it right. In previous research we did with Dilshan Benaragama in the first Organic Science Cluster, we were able to demonstrate that just by doing three things in oats 鈥� by increasing seeding rate, by harrowing, and by using a more competitive cultivar, we were able to reduce weed biomass by 70% averaged over four years. The cool thing about that was that our check treatment wasn鈥檛 a dog treatment, it was already good, standard agronomy. To register an herbicide for control, you need 80% control, and we were looking at 70% control without using an herbicide, which got us really excited that this can really work. Going out to producer meetings, it鈥檚 just phenomenal the response that鈥檚 out there, I find it overwhelming almost, farmers are so curious for this kind of information.

You were also involved in the first Organic Science Cluster. Can you briefly explain your project and its outcomes? Have your current Research Activities developed as a result of the first Organic Science Cluster?

The main project, we鈥檙e still working on to be perfectly honest. Dilshan Benaragama, as part of his PhD, is looking at the Scott long term rotation, the Alternative Crop Production System Trial, which has an organic component where we鈥檙e looking at the dynamics of weed populations over time. When the trial was started (it鈥檚 actually over now, but it went through three cycles of six years each and ran for 18 years as a result), everyone was predicting that the organic rotation would fail because of weeds. But, that wasn鈥檛 true.

So, what we鈥檙e trying to figure out is how the dynamics in the organic system change over time. And we鈥檝e figured out that moisture is a large driver. We鈥檝e also looked at one aspect in depth, which is how much do weeds really affect the yield of organic crop production. It seems, in that rotation at least, that weeds aren鈥檛 the main limitation in terms of productivity. Instead, it appears that longer term soil fertility issues are what鈥檚 hurting the yield production in the organic system. We went in and hand weeded small plots and then hand weeded and added uniform weed densities in others. Even when we removed all of the weeds, the yields still were not up as high as we were hoping. We have a growth chamber experiment that we鈥檙e going be publishing that addresses that as well.

There鈥檚 a lesson in there, especially for western organic growers, that in the long term, export-based organic systems are going to suffer large reductions in productivity unless issues, especially with phosphorus, are dealt with. You can鈥檛 just keep exporting phosphorus off of the soil. There鈥檚 so little integration of livestock production and manure application, and our soils are calcareous, so rock phosphate doesn鈥檛 really work. There鈥檚 nothing magic about organic, you鈥檙e eventually going to run your soluble phosphate levels down to a very low level that will really limit productivity of that land.

Where are your projects taking place?

They are on organic farms. We run two locations with all of our trials, because we鈥檝e found that, with agronomy, more site-years is better. If we can run two sites a year, then we have twice as much data every year, and I鈥檓 much more confident with our data. So, we run one trial on research farm land here. We鈥檙e not certified organic - because of the parcels of land it would be hard to maintain the buffer zones necessary 鈥� but, the land has been organically managed for 10 years plus. We also rent land from an organic farmer to use another location.

How do you envision that your research will help organic producers in Canada?

Well, you know, weeds are a big issue! Weeds and phosphorus are the two big production issues.

How have the organic community and your industry partners helped to shape your research?

Well, I stole the ideas from farmers! [Chuckles] I kind of rely on that iterative process of developing research from farmers鈥� ideas. We鈥檙e starting a new relationship with a farmer this year, where he鈥檚 going to be essentially doing some of what we do, but on a larger basis, so we鈥檙e hoping to field test with him. I try to keep the organic part of my research program very producer focused.

Are there graduate students, undergraduate students, or postdoctoral fellows involved in this research?

Right now, there鈥檚 Dilshan Benaragama who鈥檚 working on his Ph.D. and Katherine Stanley working on her Masters, and I鈥檓 hoping to find a couple more students that will be involved. I also have a former student who is now a research associate. We hire about three or four undergraduate summer students every year. I might be having a Masters student from France coming over and working on part of the Cluster this year. So, there are lots of young minds involved!

For more information on Steve Shirtliffe鈥檚 work in OSCII, please visit the Activity C.32 and Activity C.33 pages at http://www.dal.ca/oacc. A print-friendly version of this article is available [PDF - 394 kB].

The Organic Science Cluster II (OSCII) project described in this article is supported by the of 's and industry partners. OSCII and this article are collaborative initiatives of the Organic Agriculture Centre of Canada at and the .