It seems so simple to plant a tree. But to grow a tree is more difficult! In many parts of the United States there is enough water for trees and turfgrass, but it is often a bad idea to mix the two. You may have observed that sometimes young trees do not grow as well when planted in turfgrass. Certainly this is a generalized view and tree/turfgrass genetics are very different between their respective species. So it is natural to expect different outcomes when planting different species of trees in any landscape setting, turfgrass notwithstanding. Another factor to consider is time. The day we plant a tree is not the same time reference as ten years later. In ten years, the tree if it is successful, may have modified
its environment significantly, making turfgrass cultivation more difficult. Most tree/turfgrass difficulties begin when the tree is young–as a newly planted tree. If it succeeds in growing a large canopy, difficulties will ensue for the turfgrass. Sometimes turfgrass cultural requirements (frequent irrigation) can predispose trees to root or root-collar diseases such as Phytophthora.
Trees and turfgrass have some similar and very different requirements from their respective landscape settings. Both trees and turfgrass require sunlight to photosynthesize and grow. Both would usually prefer full sunlight without shade. As trees grow they shade the turfgrass sward beneath their canopies. Turfgrass can lose density, and become a thinner sward that is more susceptible to diseases such as powdery mildew. Trees grow roots near the soil surface and as they become larger, some trees may even proliferate roots near the mowing height of turgrass and suffer repeated injury from mowers, also increasing the risk of pest invasion into the tree. Both trees and turfgrass need water and soil minerals to grow. While soil minerals are usually abundant enough for both, water is often limiting for one or the other in this landscape combination.
The maintenance practices required for turfgrass often injure trees, especially young trees. Mowing near trees can injure the bark on the lower stem especially if the mower comes to close and actually scrapes the young stem. Since grass will grow longer where the mower can’t reach right near a tree stem there is a temptation to use a string line trimmer or weed whip to maintain the grass that has shot up around the tree stem. The repeated use of string line trimmers around trees removed young bark and can “girdle” the tree stem. While trees can survive these practices their growth rates are slowed considerably.
One approach to having trees growing with turfgrass is to remove a ring of turf away from the tree and replace it with mulch. This eliminates the need to maintain the turfgrass near the trees stem and root flare. Richard Harris and others (1977) found many years ago that a one foot circle removed around the stem of newly planted trees would increase their establishment rates compared to trees with turfgrass growing right near the stem. Whitcomb (1979) also recognized that turgrasses are competitors with newly planted shade trees. Whitcomb’s earlier research (1973) showed reduction in root density when trees were planted in a sward of Kentucky bluegrass.
As trees grow it is important to widen the ring around them giving more room for mulch and reducing the competing turfgrass underneath their expanding canopies. This is a general concept; some trees can live in turfgrass without problems as long as resources are not limiting. Riparian trees such as sycamore can grow well in swards of turfgrass, but other species such as Peruvian pepper (Schinus mole) tend to languish.
Trees are adapted to drop leaves, this is termed litterfall and it becomes part of their natural mulch. Litterfall tends to prevent annual plants such as grasses from developing. Fallen leaves, fruit and twigs are recycled by fungi providing nutrients back to the tree. Turfgrass cultivation interrupts this process and while trees obtain some of the nutrients supplied to turfgrass, as Whitcomb observed, turfgrasses are fierce competitors for nutrients so young trees are especially susceptible to nutrient deprivation in turfgrass swards. For the best results in your
garden, it is best to maintain some distance between young trees and turfgrass. It is optimal if the mulched (no turf) area under a tree can expand to its dripline as it grows.
It seems that as interest in gardening grows, especially among younger generations, interest in different techniques that home gardeners use and different plants they grow are also on the increase. You see the old standbys like straw bales and containers emerge. Terraria, succulents, and air plants are having their moment. And all kinds of technology driven indoor growing systems are all over the web, mostly hydroponic, but some aeroponic and aquaponic as well (we’ll talk about the difference in a bit – if you’re just here for that, skip the first 2/3 of the article).
I had been thinking about getting one of those new techno aeroponic growing systems as a demo for my office as a discussion starter for those interested in controlled environment growing whether on the homework commercial scale. There is a general interest and need for basic education for hydroponics and aquaponics in the area that I hope to build extension programming around, so having something at the office could provide some interest from walk-in and social media clients. I had dusted off a first generation AeroGarden that I found in the storage shelves in the office storage catacombs and set it up in my office. It is a far cry from the new models I saw in those online ads that are outside of my budget for “toys to show off at the office.” It doesn’t have nice LED lights or connect to my phone via Bluetooth like the fancy new models. Given its age, it produces more noise and heat than the lettuce and herbs I’ve tried to grow in it. Maybe I’ll be able to get one of the fancy models one day.
Then I remembered a book that an urban ag friend of mine had written on building DIY hydroponic systems from common building materials and resolved to not only build a system, but incorporate it into my programming somehow. The book, appropriately titled “DIY Hydroponic Gardens: How to Design and Build an Inexpensive System for Growing Plants in Water” by Tyler Baras shares plans for building a variety of types of hydroponic systems using basic building materials like gutters and lumber, drip irrigation tubing and fittings, and various other bits and bobs. Tyler had been a featured speaker for the West Virginia Urban Agriculture Conference that I started and hosted when I worked for WVU Extension, so the book was on my radar – I placed an order. (Note: I don’t get a kickback for sharing the book – just sharing a good resource that happens to be from a friend.)
Teaching Hydroponics to an Unlikely Audience
As luck would have it, I had an opportunity to put the book, and my DIY hydroponic skills, to the test. Our university does quite a bit of work with and in Rwanda and in May I had the opportunity to travel to Rwanda as part of a study abroad program with my Ph.D. advisor. Rwanda is a very small country, just under the size of Massachussets, with a very big population by comparison – 12 million vs 7 million! Feeding that many people is a struggle, and even though Rwanda produces a lot of produce (and more lucrative export crops like coffee and tea), it still imports a lot of its fruits and vegetables. We were studying how innovation spreads in rural areas, and just before our trip I found a news article sharing that there would be an upcoming $8M USD ($8B RWF) investment in hydroponics in the country in order to increase production on the limited amount of land available.
In June I was scheduled to teach a group of Rwandan exchange students that are part of a sponsored program at the university, and remembering the planned investment in hydroponics I planned to add DIY hydroponics to the curriculum. This is fitting, since most small-scale operations would rely on finding what materials would be locally available. While the operations started by the investment would likely bring in “real” hydroponic systems, if small scale producers want to use the technology or if individuals want to build skills, they’re going to have to use what is at hand.
It was interesting teaching an audience who were interested in learning about the new technology, but have little experience or general knowledge on the subject. Even more interesting was the fact that many of the students had not used or even seen some of the basic power tools we used in building the system. I’m no shop teacher, but in the end the students not only learned a little bit about hydroponics and hydroponic systems, but also some skills using tools that they can apply in other applications.
Hydroponics, Aeroponics, & Aquaponics – Oh My!
Earlier I mentioned that there are differences between hydroponics, aeroponics, and aquaponics. In some ways, they use similar basic setups. All are based on soil-less growing using an inert media to support plants, supplying nutrients and water directly to the plant roots, and providing light to the plants using either natural sunlight or supplemental lighting. Differences come from the source of plant nutrients and from how they are delivered to the plant. I thought I’d take a few minutes to talk about the basics of each of the techniques so you can understand the differences just in case you want to buy or build your own system. If there’s interest, I hope to focus on hydroponics and controlled environment agriculture over my next few blog posts – tell me what you’re interested in learning.
Most people are familiar with the concept of hydroponics. This technique relies on roots being submerged in a nutrient-rich solution where the nutrient content is engineered from a variety of mineral sources. There are a variety of different systems (that will hopefully be the subject of an upcoming blog) where the root zone interacts directly with the solution. In some cases, roots are submerged in a large volume of solution while in others a film or shallow stream of water flows through the root zone. Systems where roots are submerged in the solution may simply be a large reservoir where the plants float on top where systems relying on flow may involve a pump. Movement of water adds another plant need -oxygen, which is required for respiration by the roots. In systems where there is no flow, air is often pumped in to provide oxygen.
Most flowing systems are recirculating, where the solution returns to a reservoir and is pumped back into a reservoir to be reused. While it may seem counterintuitive, these recirculating water based growing systems have been touted as production methods that conserve water. That’s why some of the leading hydroponic production and research comes from areas of the world where water is scarce. Less common are flow through systems where water and nutrients are not recaptured but discarded after initial use.
Aeroponic systems have much of the same basic setup but instead of the roots interfacing directly with water solution it is applied as a pressurized mist. These systems generally use a much smaller volume of water, but there are some drawbacks. Failure of the system, such as an electric outage or clogging of the nozzles that pressurize the mist (which is a common occurrence) can quickly result in plant failure since roots can dry out quickly. Several systems that are sold commercially that market themselves as aeroponic, such as the AeroGarden or Tower Gardens, are more similar to a flowing hydroponic system than a pressurized mist aeroponic system.
The plant growing structures of aquaponics are similar to those of hydroponics, with the addition of larger reservoirs to accommodate the addition of aquatic livestock such as fish (or sometimes crustaceans). The waste produced by the stock provide the nutrients needed by the plants rather than an engineered nutrient solution. These systems require having the technical knowledge to meet the needs of the aquatic stock and balancing those with the needs of the plants. The addition of the aquatic stock also introduces a microbiome of bacteria and fungi, many of which are required for animal health but can also introduce pathogens that can negatively affect human health.
Are you interested in learning more about these systems? What do you want learn about in hydroponic or other systems? Let me know in the comments and I’ll try to base some future articles on what our readers are interested in.
In the fall a gardener’s fancy lightly turns to thoughts of pruning (with apologies to Alfred, Lord Tennyson). In particular, people worry that pruning too late in the summer or early fall will stimulate plants to send out new growth, which is then damaged by freezing temperatures. Let’s dissect what actually happens when woody plants are pruned during this time.
First, we need to separate temperate trees and shrubs from tropical and subtropical species. For the most part, the latter don’t become winter dormant: pruning them at any time means you will have regrowth as long as there are sufficient resources. If planted in more temperate zones, they will continue to grow until they are killed by freeze damage. Instead, we’ll look at temperate species and how they are adapted to surviving winter conditions.
I wrote a couple of posts last year on cold hardiness (here and here), so I won’t repeat those discussions on how plants survive freezing. Instead, we’ll focus on the process of HOW plants enter winter dormancy and become cold hardy. It’s a two-step process that depends on two different environmental factors: one that never changes from year to year, and one that certainly can.
The first step to dormancy is initiated right after the summer solstice. Plants are exquisitely adapted to changes in the light-to-dark ratio, and days begin shortening after the summer solstice. The changes that occur are largely biochemical, but you can also see some changes in plants themselves. Many trees and shrubs slow their growth during this time so that fewer young leaves and shoots are produced. Instead, resources are put into the existing foliage, or flowers for summer bloomers. Excess resources are routed to woody parts of the plant for storage.
From a practical standpoint, this means that when you prune trees and shrubs where growth has stopped, you will NOT get regrowth. The vegetative buds below the pruning cut are dormant. The tricky thing is that the exact time when the switch is thrown varies by species and is affected by environmental conditions. Careful observation will allow you to estimate when the plants will no longer produce new growth.
The second step begins when night temperatures cool to near freezing, which is not a predictable date. Because many of the biochemical and physiological processes have already begun or are finished, the response to cold night temperatures is rapid and visible. Leaf colors change as the plant begins breaking down leaf materials for mobilization and storage elsewhere in preparation for winter dormancy.
This process, honed over millions of years, is unfortunately not infallible especially under abnormal environmental conditions. Two examples spring to mind:
High intensity street lights. If the normal light-to-dark ratio change is interrupted by significant levels of night light, the first step of dormancy is hijacked. You can see what happens in these previous blog posts here and here.
Unseasonably cold weather. With climate change, we are seeing wild shifts in all sorts of weather patterns, including the date of the first hard freeze. Hard, early freezes are not the same as a light evening frost. You can see what happens here:
Given normal conditions, however, temperate trees and shrubs are well on their way to full winter dormancy by late summer and early fall. Pruning them is not going to induce new growth.
Arborists, Professional Credentials, and Designating Bodies
The Merriam-Webster dictionary defines arboriculture as “the cultivation of trees and shrubs especially for ornamental purposes” (2019a) and arborists as the specialists that care for those trees (2019b). In the US there are two primary certifications for arborists. Arborists can become a Registered Consulting Arborist (RCA) through the American Society of Consulting Arborists (ASCA) (ASCA, 2019a) and/or become an International Society of Arboriculture (ISA) Certified Arborist (ISA, 2019a). The ISA also offers a range of associated certifications, including ISA Certified Arborist Utility Specialist, Arborist Municipal Specialist, Tree Worker Climber Specialist, Tree Worker Aerial Lift Specialist, Board Certified Master Arborist, and ISA Tree Risk Assessment Qualification. For the sake brevity, the focus of this post will be on the flagship programs from each organization, ASCA’s Registered Consulting Arborist and the ISA Certified Arborist credentials.
Relevance for Gardeners
Many gardeners who have trees are likely familiar with arborists, or at least with a local “tree guy”. While trees are beautiful, they can also suffer from disease, nutrient deficiencies, and other plant health issues. In addition, trees often require maintenance and pruning to ensure safety, avoid damage to houses or other property from falling branches, or to allow more light through the tree canopy to reach the ground and garden. Maintenance and pruning of trees requires experience and expertise to ensure that trees aren’t damaged in the process, and that pruning is done safely. When their services are needed, hiring an arborist with professional credentials can be an excellent way to ensure that trees are properly cared for and that nobody is hurt in the process.
In my personal experience, certified arborists in my community charge more per hour. However, the extra cost in exchange for ensuring the 60 year old pin oak that is the same age as my house lives on for another 60 years is worth it.
Other Considerations in Choosing an Arborist
Whether an arborist is certified or not, it is a good idea to check that the arborist is insured. That is because if they or one of their crew is injured on your property, you as the property owner may be liable for any injuries that occur while tending to the trees on your property.
Also, as with hiring any professional for home repairs or improvements, it’s important to check their references or get recommendations from colleagues and friends. You should also check whether your local government has any regulations on tree management within city limits. If so, be sure that who you hire has experience with following those regulations, and has all of the business registrations and approval from the local government.
It is also important what your needs are. If you need a large specimen tree pruned and the potential for tree injury or death would be devastating, then hiring someone with documented expertise is important. If you’re instead just trying to get the half-dead tree in the back yard chopped down and there’s no risk of falling a tree onto a power line or structure, then documented expertise might be less important (though insurance might be, see above).
In addition, if you are getting a large tree taken down, consider the value of the wood in your tree. Large hardwood trees may have significant value. Some tree guys will offer to take it down for free in exchange for the wood. While this may sound like a good deal, I know people who were shorted thousands of dollars from such transactions when considering the value of the wood and the per hour cost of an arborist.
Type of Credential: Professional Certificate
Both the RCA and ISA Certified Arborist credentials are considered professional certificates. This means that these are optional credentials. Arborists are not required by law to be certified. This means that an arborist can operate without certification. Arborists that are certified have had their credentials reviewed, and meet or abide by the criteria described below.
Education and Professional Experience Requirements
Registered Consulting Arborists must be a current ASCA member, and be a graduate of the ASCA’s Consulting Academy (ASCA, 2019b). No additional education or work experience is required.
ISA Certified Arborist must have three or more years of experience in arboriculture and/or a degree in the field of arboriculture, horticulture, landscape architecture, or forestry from an accredited institution of higher education (ISA, 2019b).
Registered Consulting Arborists must pass an open-book exam as part of the ASCA’s Consulting Academy, which also includes other assignments before, during, and after the academy (ASCA, 2019c).
ISA Certified Arborists must pass a qualifying exam (ISA, 2018).
Code of Ethics
The ISA Certified Arborist program has a code of ethics that all certified arborists must abide by (ISA, 2019c). The RCA program does not have a code of ethics.
Registered Consulting Arborists must complete 420 continuing education units (CEUs) to be eligible for the RCA credential (ASCA, 2019b). Their website does not specify if additional CEUs are required in order to maintain the RCA credential.
ISA Certified Arborists are required to complete 30 CEUs in a three-year period in order to maintain their certification (ISA, 2019d).
ASCA. 2019a. The RCA. American Society of Consulting Arborists. https://www.asca-consultants.org/page/RCA (accessed 25 September 2019).
ASCA. 2019b. Eligibility/Fees. American Society of Consulting Arborists. https://www.asca-consultants.org/page/EligibilityFeesRCAs (accessed 25 September 2019).
ASCA. 2019c. ASCA’s Consulting Academy. American Society of Consulting Arborists. https://www.asca-consultants.org/page/ConsultingAcademy (accessed 25 September 2019).
ISA. 2018. ISA Certified Arborist Application Guide. https://www.isa-arbor.com/Portals/0/Assets/PDF/Certification-Applications/cert-Application-Certified-Arborist.pdf.
ISA. 2019a. Types of Credentials. International Society of Arboriculture. https://www.isa-arbor.com/Credentials/Which-Credential-is-Right-for-You (accessed 25 September 2019).
ISA. 2019b. ISA Certified Arborist. International Society of Arboriculture. https://www.isa-arbor.com/Credentials/Types-of-Credentials/ISA-Certified-Arborist (accessed 25 September 2019).
ISA. 2019c. Code of Ethics. International Society of Arboriculture. https://www.isa-arbor.com/Credentials/ISA-Ethics-and-Integrity/Code-of-Ethics (accessed 25 September 2019).
ISA. 2019d. Maintaining Credentials. International Society of Arboriculture. https://www.isa-arbor.com/Credentials/Maintaining-Credentials (accessed 25 September 2019).
Merriam-Webster. 2019a. Definition of Arboriculture. Merriam-Webster. https://www.merriam-webster.com/dictionary/arboriculture (accessed 25 September 2019).
Merriam-Webster. 2019b. Definition of Arborist. Merriam-Webster. https://www.merriam-webster.com/dictionary/arborist (accessed 25 September 2019).
Gardeners are assaulted with marketing campaigns nowhere better than in the fertilizer aisle of a garden center. There are so many choices and the labels suggest that fertilizing garden plants is a complicated process that requires specialized products.
Laws require that fertilizers list the proportion of the most important macronutrients on the front of the bag. Nitrogen, Phosphorus and Potassium abbreviated N, P, K, respectively, will always be shown with the ratio of their concentrations such as 5-10-15. This indicates the bag contains 5% nitrogen, 10% phosphorus and 15% potassium. The bag will also specify the weight of fertilizer contained in it, usually in pounds here in the United States. Of course, labeling requirements vary in other countries. Since fertilizers are not drugs or pesticides the labeling requirements are relatively lax and thus are open to extensive marketing. With fertilizers, as long as the contents are labeled and the proportion of N P and K are somewhere on the bag, any other claim can seemingly be made.
For years fertilizers have been designed specifically for certain plants. You can commonly purchase citrus food, camellia and azalea food, vegetable fertilizer, and of course turfgrass fertilizers which have been widely marketed for decades. Some fertilizer blends are based on research. Turfgrasses have a high requirement for both Nitrogen and Potassium and you often see elevated percentages of these in turfgrass fertilizers. Palms also require more potassium than Phosphorus and products have been developed that are “palm special” fertilizers. Despite all the research, manufacturers still throw in some phosphorus even though phosphorus is abundant in the United states in most soils. It is not clear to me what makes citrus food different from any other fertilizer, although claims that it is best for citrus can usually be found on the product. We grow more citrus in Ventura County, particularly lemons than anywhere in California, but none of the growers apply “citrus food”.
Some fertilizers are marketed for acid loving plants. Acid forming fertilizers have the ability to temporarily reduce pH in media or soil to which they are applied. This is because they have a high amount of ammonium or urea as the nitrogen source. Microbes in soil oxidize the nitrogen to nitrate and release hydrogen ions that make the soil more acid. Continual use of acid forming fertilizers can drop soil pH to dangerously low levels and make nutrients unavailable to many plants. This is especially the case in high rainfall climates where mineral nutrients are easily leached from soil. Another product often used to lower pH is aluminum sulfate. Often marketed as “hydrangea food” it helps to promote blue flowers in this plant. Special care should be given here as aluminum can easily be applied to toxic levels.
For as long as fertilizers have been sold they have been marketed as products that make plants grow better. When the importance of mycorrhizae were discovered, manufacturers found a new marketing angle that could be used to sell fertilizers. Now countless manufacturers include mycorrhizal inoculants as part of their fertilizer blend. Not only are we able to feed the plant but we can also feed the soil with beneficial micro-organisms. This all sounds great but often the inoculant, if present in the bag, is not viable. In many cases garden soils already have plenty of mycorrhizal fungi in them so they really are not needed in fertilizer products. Other fertilizers include growth stimulants such as humic acid, fulvic acid or humates. Research does not support their efficacy in horticulture.
Fertilizer manufacturers feel that it is important that we gardeners use things that are “all natural”. I don’t know what is natural to you but for me it is natural to challenge claims that have no scientific basis. The very practice of fertilizing plants is NOT NATURAL! But the products are often purported to be. Sometimes natural is synonymous with organic. There are an amazing number of organic fertilizers, so much so that it becomes bewildering as to which one to choose. Organic fertilizers may or may not be ‘certified’ by an agency such as OMRI as meeting some standard. Generally speaking organic fertilizers are made from some carbon based source. They can be sourced as manures or as plant or animal based meals or products. The N-P-K ratios vary widely.
I am always careful to avoid manure-based organic fertilizer products as they can be unnecessarily salty. While many organic fertilizers may be rather “slow release” as they need to mineralize from organic to soluble forms, this is often not the case with manure based products which can easily burn plants if over-applied. Some organic fertilizers are made from rock like substances such as leonardite which are very slow releasers of nitrogen. These products are mined and are similar to coal but have fertilizer value. In trials I have conducted on containerized plants some of these products were top performers.
Another common type of organic fertilizer are the biosolids products such as Milorganite. These are processed sewage sludge products that are de-watered and made into fertilizer. They are very effective nitrogen sources. Some biosolids fertilizers have also been sources of metals, such as zinc, lead and cadmium. Metal contents are closely monitored by manufacturers but since these products come through municipal systems, zinc, copper and other metals such as lead are often elevated. Slow release and organic fertilizers are useful if they are applied with understanding of the mineral needs of the plants they are applied to.
Most plants grow fine without fertilization and the main fertilizer element that plants respond to is nitrogen. So despite all the marketing claims seen on fertilizer bags, a fertilizer with an adequate source of nitrogen will likely benefit plants in need of that element. Specialized fertilizers that promote flowers or roots are not substantiated by research. Elements other than nitrogen are usually not required and ratios of N P and K are not tuned for more blooms or more roots. Adding phosphorus to your fertilizer does not promote flowering unless your soil is deficient in phosphorus (a rare condition). Gardens in high rainfall areas will likely need more potassium and nitrogen, but Phosphorus is hardly ever limiting to plant growth. Most plants do not need or require special fertilizers but will respond to fertilizers that contain an element they and soils they are growing in are lacking.
For gardens that have a loam soil texture, little fertilizer will be needed. Soil types often determine fertilizer needs for plants. Sandy soils likely need the most fertilizer because they do not hold nutrients well. They are also the most likely soils to lead to pollution because fertilizer elements will leach easily. Plants growing in sandy soils are also at greatest risk from injury of overfertilization. Plants growing in clay soils are least likely to require fertilization because clays hold and retain cations so well. An informed way to fertilize your garden is to obtain a soils test and base your fertilizer program on the results you obtain. For more on technical details of fertilizing see John Porter’s column in this blog archive.
When you think you need to fertilize garden plants follow these suggestions:
-Base your fertilizer program on a soils test
-Fertilize sandy soils more frequently than clay soils but with smaller amounts
-Most gardens require some nitrogen but not Phosphorus or Potassium so look for NPK ratios with X-0-0 as these products will only supply nitrogen.
-Some plants such as palms and turfgrass benefit from potassium so use a product with X-0-X
-Do not fertilize at planting time, wait until plants establish
-Always apply water after applying soluble fertilizers so they are dissolved
-If using Organic fertilizers chose one with a higher N content
-Never over-fertilize. Landscape fertilization can impair natural waterways resulting in algal blooms that kill fish and other aquatic life.
The Annual Meeting and Professional Improvement Conference of the National Association of County Extension Agents is that one time of year where extension agriculture professionals gather to share ideas, give talks, network, and let their hair down. The name of the organization is a bit outmoded: many states no longer call their extension personnel agents, but rather educators, experts, professionals, area specialists, and the like. Most aspects of agriculture are included: from the traditional cows and plows of animal science and agronomy to horticulture and sustainable agriculture (I’m the outgoing national chair of that committee). There’s also sharing on agriculture issues like seminars on engaging audiences about genetic engineering, teaching and technology like utilizing social media and interactive apps, and leadership skills.
It is the one time every year or so that Linda Chalker-Scott, grand founder of the Garden Professors, and I get to hang out. If we’re lucky we’ll meet up in some sessions, chat in the hallways, or grab a drink. But one of our favorite conference activities is taking a turn around the trade show floor. This is where companies and organizations are vying for the attention of extension educators to show them their newest equipment and products….we are, after all, the people that share growing and production information with a great number of potential clients across the country.
Since the organization runs on money, almost no company that comes calling with the money for a trade show spot is turned away. This means that the products may or may not stand up to the rigors of scientific accuracy. In years past we’ve found snake oil aplenty, like magical humic acid that is supposed to be this natural elixir of life for plant growth. The only problem is that humates don’t exist in nature and there’s little documentation of any effect on plant growth. The product that was supposed to be this magic potion was created from fossil fuels and no actual peer-reviewed research was offered by the company – hardly convincing. There were magic plastic rings that supposedly acted as protective mulch around mature trees and could slowly release water, except that mature trees don’t really need protective mulch and the amount of water would be negligible to a tree that size. So will we be smiling or scowling when we’ve made our way through the trade show.
Right off we set our sites on a company starting with “Bio”, which can be a good indicator of questionable rationale. That lit up the first indicator on our woo-ometer. Beneficial bacteria you apply to plants/soil: woo-ometer level two. So LCS and I engaged the representative. Asking about the product and what it does. We learned about their different products that could help increase the rate of decomposition of crop residues in farm fields, of turfgrass improvement, increased crop production, and treatment of manure pits on dairy and hog farms (which, if you’ve ever experienced one, you’d know would benefit from any help they can get in terms of smell).
Most of the products like this give vague descriptions of the beneficial bacteria it contains. They’re akin to compost teas that can have any number of good, bad, and downright ugly bacteria and fungi in them. Since you don’t know what’s in these products, any claims on soils or plants are suspect at best. However…our rep went on to tell us that the company created blends of bacteria from specific strains that had been researched for their effects on decomposition, soil nutrient availability, and plant growth. There was a brochure with the specific bacteria listed, along with studies the company had conducted.
We asked about peer-reviewed research, which is our standard for evidence here at the GP, and while he had no results to share he assured us that university-led research is currently in the works. And as we’ve stated in regards to applying of beneficial bacteria to soil – while there’s little evidence showing the effectiveness of applying non-specific bacteria to plants, using directed applications of specific bacteria which have been tested for specific functions are supported by research. So our woo-meter didn’t fully light up. We reset it and continued the hunt.
We scoured the rest of the trade show and found one other soil additive that lit up the first lights of our woo-meter, but the rep must have been out for lunch so without anyone to talk to we couldn’t confirm woo or no-woo.
However…..we did find something spectacular! The local employees of the USDA NRCS (Natural Resources Conservation Service) had an interactive demonstration of soil, specifically showing the benefits of reducing or eliminating tillage. The NRCS works with many farmers to incorporate conservation practices on farms, including no-till production, by providing technical assistance, farm plans, and even grants, cost-share, and easement programs. Many farmers have benefitted from their grant for season extension high tunnels (which are seen as a soil conservation technique, since they shelter soil). We were so enamored with the demonstration, we asked them to do it again…so we could record it. So, for your viewing pleasure check out the video below where you can see how well no-till soil holds its structure while tilled soil falls apart. This effect is from the exudates from all the beneficial microbes in the soil that act like glue to promote good soil structure. We’ll let the video speak for itself……
So not only does the trade show get a smile instead of a scowl from us, but also two thumbs up! Either there has been some weeding out of the trade show sponsors, maybe the snake oil salesmen didn’t get the traction they were hoping for at the conference, or hopefully some of these companies have failed to reach an audience with their pseudoscience.
This isn’t the first time I’ve ranted about bad mulch choices and it certainly won’t be the last. But this pictorial cautionary tale is too important to pass up.
We already know that sheet mulches can be death to microbes, plant roots and animals living in the soil underneath. Our newly published research shows that landscape fabric reduces carbon dioxide movement between the soil and atmosphere about 1,000 times more than wood chip mulches do: plastic mulches are even worse. Oxygen movement will be likewise affected. And while gaps and holes in these barriers can lessen the impact, the question remains: why would you use ANY mulch that reduces gas movement? Yet people persist in using fabrics and plastics, usually to “smother” weeds (and that verb should set off alarm bells for anyone thinking about collateral damage to soil life). But weeds are weeds for a reason, and they will eventually colonize the surface of sheet mulches as soil, organic matter, and water collect over time.
So without further ado, here is a case study of what happens when sheet mulch is used for landscape weed control.
These irrigated landscape beds are in Wenatchee, Washington, which has hot, dry summers. As you can see, bark mulch has been used to hide the shame of sheet mulching. And from a distance it looks…okay.
Upon closer inspection, you can see the shroud of death emerging from the bark mulch (which has no means of staying in place, especially on a slope).
And even close you can see the soil that’s blown in, along with the bark and other organic matter. Just add water, and you get weeds!
Weeds, weeds, weeds! Lots of weeds. Sunny weeds!
And shady weeds!
The weeds are thriving – but the trees are not. The crowns are dying…
…and the trunks are suckering.
But you’ll note that the trees in the first photo outside of the beds are thriving.
And it’s all because of that “weed control fabric.” Which is working so well that this landscape had to be treated with herbicide the day I was there – to control the weeds.
I was taught in horticulture school that the ideal soil is composed of 50% solids and 50% voids or spaces which are themselves composed of a variable amount of water from small amounts to as much as 25% water when the soil is at field capacity or the amount of water left in soil after gravity has pulled all the free water down in the profile. So the “ideal” soil always has 25% pore spaces or more depending on how much water is present. These conditions are vital for root growth since roots go through the chemical process of respiration which involves absorbing oxygen and giving off carbon dioxide. For gas exchange to happen in this ideal soil, spaces or voids are important, and necessary. A well-structured soil has micro aggregates (pea sized or smaller clumps of soil) in high concentrations which creates many of these spaces and is said to have high porosity.
Porosity – the amount and types of voids – is determined by two major factors: 1) The size and distribution of the soil particles; and 2), how those particles are arranged. Sand, silt, and clay particles can be arranged and formed into pathways that help move air and water. These paths are formed by past root channels and the movement of organisms like worms and insects. These channels are glued together by exudates from roots, bacteria and fungi. This organic, both living and dead, soil fraction also add and stabilizes porosity. All together, soil particles, plant residues and microorganisms create a fragile structure that adds more porosity than just the pores and voids created by spaces between the soil mineral particles.
Structure and porosity can be physically destroyed or crushed. The soil can be squished by heavy equipment or constant foot traffic of animals, such as humans or horses, or others that constantly tread over the same soil. Compacted soil can be near the surface (the worst for trees since their roots are mostly near the surface), or lower down in the profile. A “plow pan” is actually a compacted zone at the depth of plow or ripping agricultural implements where soil structure is constantly destroyed at the same depth over and over. As soon as roots and worms create a new pathway and reinforce it with micro-aggregates and glues, it is destroyed again, creating a zone of loosened soil where the implement has traveled, but a zone immediately below what which has been compacted by the pressure of the implement.
Most horticulturists and many gardeners know that compacted soils are bad for plants growing in them. Shade trees frequently have restricted growth in these kinds of soils. This can happen at a young age when trees are just planted or on large specimen trees, such as in parks that have the soil compacted around them by visitors. Footpaths, picnic tables, playground equipment or any publicly attractive park feature will often have compacted soils in the area.
Deprivation of litterfall and mulch layers, either through wearing out (grinding of organic matter by foot traffic) of the mulch or by mulch/litter removal through raking will promote compaction by removing the cushioning effect of that mulch layer. Sadly, the tree itself can be the feature that attracts people to it, resulting in compacted soils all around its base that limits its health.
What is not so well known is why growth is slowed in compacted soils. The effects of compaction are multi-fold. Compacted soils are less porous because the compaction literally reduces the air pockets in the soil, making it more dense with lower oxygen diffusion rates. Soil with destroyed structure becomes less permeable to water infiltration and holds less water. Under these conditions tree roots may not be adequately hydrated, and cannot physically penetrate the highly compacted soil. Thus, they are not able to develop and expand and explore enough to supply the needs of the tree. Reduced soil oxygen, along with other site, soil, and tree variables such as water and nutrient uptake, are all reasons for restricted tree growth.
There is compelling evidence that different species of trees can exert greater pressure at their root tips to break through compacted soils. Different tree species also have different root architectures – finer, deeper, shallower, etc. Thus, there is a genetic factor in a tree’s ability to deal with this soil problem.
Soils are more or less compactable depending on their texture, structure and moisture status. Generally a dry soil is harder to compact that a moist one. Dry soils resist compaction (but still can be compacted) because the soil aggregates stiffen as they dry. Wet soils are easily compacted but people and machinery also easily sink in very wet soils. Waterlogged soils may or may not have structure, but the water in the pores, prevents further collapse of the soil structure. Soils that are moist (at field capacity) are just right for growing plants, and are also perfect for compacting and thus must be protected from compaction.
Soil compaction is measured by calculating what’s called bulk density (Bd). Bulk density is the weight of soil in a given volume, and is measured in grams/cubic centimeter. In order to measure bulk density a special soil sampling device called an “intact soil core sampler” is used. This device extracts a core of soil while preserving its structure. The volume of the sample is a constant. The soil sample is removed and dried to drive off all the water and then the weight of dry soil is divided by the known sample volume giving the bulk density.
Bulk densities vary depending on the soil texture (%Sand:Silt:Clay) and to a smaller extent on the organic matter content. Sands generally have very large particles, more pore spaces and lower bulk densities than silts, loams and clays which will
A Comparison of Root Limiting Bulk Density for Different Soil Types (NRCS 1998 in Dallas and Lewandowski, 2003)have the highest bulk densities. Thus compaction is determined by measuring both bulk density and soil texture. Generally, pure rock has a bulk density over 2.65 g/cc. Uncompacted sands may have bulk densities of 1.2-1.4, while loams and clays may have Bd from 1.5-1.8 g/cc. A sand may be compact at 1.4 but a clay may have a higher Bd of 1.5 and not be considered compacted. Organic soils can have Bd that are much lower – 0.02-.9 g/cc. Generally, soils (average of all textures) with bulk densities over 1.5 can be suspected to be compacted and will limit tree growth.
Bulk density for a given soil is not a fixed property, it can change depending on the history of what has happened to the soil. For instance, in an annual color bed or vegetable garden bed, the soil may be turned or tilled by the gardener, amended, and replanted. During this process structure is destroyed, but the organic matter, growth of the crop, and time foster a new soil structure, perhaps even more porous than the soil was previously. This can happen in one growing season. In the case of compacted soils around trees, it can take years for a mulch laid over a compacted soil to correct the compaction.
Another way of looking at this is: if you can get the sampler into the soil, its likely not compacted, but if you have to use a hammer to get it into the soil it might be compacted (or dry). Pressure required is going to depend on the soil moisture, as well as the state of compaction. Compaction can also be measured by a device called a penetrometer which quantifies resistance to penetration. We as gardeners can use a screwdriver, if you can push it into soil; it is less compacted than if you can’t. The screwdriver test is also used to test for moisture content–when soils dry out, they resist penetration. The depth of water penetration in an irrigated soil is the depth to where the screwdriver stops when pushed in. So, it is easy to confuse a compacted soil with a dry soil. Also, if a soil is compacted, water will not easily enter, so many compacted soils are also perennially dry soils since irrigation does not easily penetrate them. This can be seen as increased runoff when you try to irrigate or ponding if the compacted zone does not drain away.
How do we fix compacted soils with high bulk densities? I was always taught that chemical fixers like gypsum, soil penetrants, or other chemical means will not affect a structurally damaged and compacted soil. The only way to fix them is to physically un-compact them. So, further destroying structure by ripping, drilling, trenching, air spading, or in some other way breaking up the compacted layers is the thing to do. Basuk (1994) cites cases where soil modified to treat compaction actually re-compacts (bulk density increases) over time (2-3 years after a compaction relieving treatment is applied). Numerous studies indicate that breakdown of arborist chip mulches will lead to reduced bulk density, but little is known about actual bulk density reductions with mulch applications over time. I am confident mulches will reduce bulk density, but given the diversity of soils, textures and compaction levels, I can only imagine this is a variable response. Removing the cause of the compaction, (foot traffic, machine usage etc) is the first step. Mulching following some kind of “soil fluffing” procedure should begin the process of increasing soil porosity and reducing bulk density. It may take years to relieve compaction passively through the action of mulching. If soil can be mechanically broken up, the compaction issue is solved and soil structure will slowly be reformed in time depending on what is grown thereafter.
Bassuk, N. 1994. A review of the effects of soil compaction and amelioration treatments on landscape trees. Journal of Arboriculture 20:9-17.
Entomologists, Professional Credentials, and Designating Body
Entomology is the study of insects, and is a field within zoology, the study of animals. In the US, the primary professional and scientific society of entomologists is the Ecological Society of America (ESA), which formed in 1889 (ESA, 2019a). The ESA developed the Board Certified Entomologist (BCE) professional certification for professional entomologists with a bachelor’s degree or higher in entomology or a closely related discipline (ESA Certification Corporation, 2019a). The ESA later created the Associate Professional Entomologists (ACE) for those who don’t meet the education requirements of the BCE credential, but do have professional experience and training and work in the pest management industry (ESA Certification Corporation, 2019b). Both credentials are administered by the ESA Certification Corporation (ESA Certification Corporation, 2019a).
Relevance for Gardeners
Gardeners are likely to encounter entomologists in a few different capacities. First, professional certification of an entomologist is a sign of authority. This can be especially important when evaluating the credibility of information available online and reviewing the qualifications of authors. Gardeners should seek information from BCEs or ACEs, in addition to traditional sources of information on insect control like extension publications or peer-reviewed literature. Gardeners are also likely to encounter an ACE in the event that a professional is needed for helping with pest control – whether that be in the garden or in the home. If gardeners are seeking an insect control professional, an ACE professional credential is a good indicator of professional experience and training.
Type of Credential: professional certificate
The BCE and ACE credentials are professional certificates, which means that it is a voluntary program (Knapp and Knapp, 2002). Being a voluntary program, it is legal for entomologists to practice without the certificate. However, it will be up to gardeners to evaluate the experience, training, and education of the entomologist.
Education and Professional Experience Requirements
A bachelor’s degree or higher in entomology or closely related discipline (ecology, zoology, biology, etc.) is required for the BCE credential, while the ACE credential does require a college degree (ESA Certification Corporation, 2019c). BCEs are required to have three years of professional experience if their highest degree is a BS, two years of experience with an MS, and one year of experience with a PhD. ACEs must have 5 years of verified professional experience in pest management. In addition, ACEs must also have an active license or certificate that allows them to apply pesticides without supervision.
BCE certified entomologist must past the BCE Qualifying exam with a score of 70% or higher (ESA Certification Corporation, 2019d), while ACEs must pass the ACE exam with a 75% or higher (ESA Certification Corporation, 2019e).
Code of Ethics
BCEs and ACEs are bound by codes of ethics for the respective programs (ESA Certification Corporation, 2019f; g).
BCEs are required to complete 120 hours of continuing education units via continuing education or professional participation over a three-year reporting period (ESA, 2019b). At least 72 hours of those CEUs must be from continuing education for each reporting period. ACEs are required to complete 18 CEUs over a three-year reporting cycle (ESA Certification Corporation, 2019f).
ESA. 2019a. About ESA. Entomological Society of America. https://www.entsoc.org/about/esa (accessed 27 August 2019).
ESA. 2019b. CEU Requirements. ESA Certification Corporation. https://www.entocert.org/ceu-requirements (accessed 27 August 2019).
ESA Certification Corporation. 2019a. About. ESA Certification Corporationf. https://www.entocert.org/about (accessed 27 August 2019).
ESA Certification Corporation. 2019b. ACE Certification. ESA Certification Corporation. https://www.entocert.org/ace-certification (accessed 27 August 2019).
ESA Certification Corporation. 2019c. BCE Requirements. ESA Certification Corporation. https://www.entocert.org/bce-requirements (accessed 27 August 2019).
ESA Certification Corporation. 2019d. BCE Examinations. ESA Certification Corporation. https://www.entocert.org/bce-examinations (accessed 27 August 2019).
ESA Certification Corporation. 2019e. Studying for the ACE Exams. ESA Certification Corporation. https://www.entocert.org/studying-ace-exams (accessed 27 August 2019).
ESA Certification Corporation. 2019f. Maintain my ACE Certification. ESA Certification Corporation. https://www.entocert.org/maintain-my-ace-certification (accessed 27 August 2019).
Knapp, L., and J. Knapp. 2002. The Business of Certification: Creating and Sustaining a Successful Program. 2nd Revised edition edition. Association Management Press,U.S., Washington, D.C.