Wetting Agent

Happy New Year 2018.
Extremely excited this year as I had been stuck in "InBetweenProjects" for quite a while and things are beginning to fall into places. Hope to get busy soon.

Since it's drizzling today and have to cancel my trial for spraying AgroSol Pure Plant Energy, had some time to sit back and reflect on "wetting agent" I was also discussing this with my Principle a few weeks ago and i was made to realize that this is a huge market and billions are used to funds this research.

My initial perception was there are the same (almost) products; wetting agent, surfactants, sticking agents, adjuvants, dispersant, penetrants...Agrosol recommend a wetting agent to be used with every application, unless already present in another product. I had tried applying without wetting agents, with wetting agent and with Too Much wetting agent. Found out that Agrosol works from without wetting agents depending on plants and environmental condition to with wetting agent. It causes plant damage when Too Much wetting agent.

The waxy surfaces of many insects, fungi, and plants make it difficult for most water-based spray solutions to penetrate their target. To overcome this barrier, adjuvants have been developed, however it can determine how well the spray works. When used inappropriately, they can cause crop damage. Adjuvant is a broad term describing any additive to a spray tank that enhances it's activity. Examples of adjuvants are surfactants, spreader stickers, crop oils, anti-foaming materials, buffering agents, and compatibility agents. Surfactants are adjuvants that facilitate and accentuate the emulsifying, dispersing, spreading, wetting, or other surface modifying properties of liquids.

Many pesticides require the addition of an adjuvant, and some do not. When applying fungicides, insecticides or herbicides without a recommended adjuvant, 30 percent to 50 percent reduction in pest control can be expected. Same goes fro Agrosol. Adjuvants may cause damage to a plant if the wrong adjuvant is used or if it is used at too high a concentration.

Today’s Adjuvant Menu   Surfactants Surfactants are adjuvants that reduce surface tension within the external surface layers of water. There are four different types of surfactants:

Anionic Surfactants are negatively charged, and enhance foaming and other spreading properties. For example, shampoo for hair contains sodium or ammonium laureth sulfate, which is the preferred anionic surfactant for hair. Using an anionic surfactant in the greenhouse can cause problems with sprayers that have an agitator, or any system where the foam could disrupt water flow or pump suction.

Cationic Surfactants are positively charged, and are often very toxic to plants as they can disrupt membrane ion balance. Cationic surfactants are not widely used for pest control, but they are more commonly used in heavy-duty cleaning compounds. Don’t grab a bottle of engine wash surfactant used to clean the tractor and add it to your pesticides when spraying Easter lilies. The results can be devastating.

Amphoteric Surfactants are unusual in that they will form either a positive or negative charge in water,

depending upon the pH of the solution. Their use in horticulture crop protection is rare. These products are used very specifically to match the properties of specific pesticide formulations to carrier components or other materials, and are generally not available for use in the greenhouse as a stand-alone product.

Nonionic Surfactants do not have a charge in solution and are the most commonly used surfactants for the horticulture industry. When used properly, they as a class do not harm plants, remain stable, and do a good job of breaking water surface tension. However, application rate is critical. When applied at too high a rate plant injury may result.

Nonionic surfactants are now being researched in relation to controlling fungal infection, especially in hydroponic systems. When a fungal zoospore is coated with a nonionic surfactant, it does not function well. Dr. Ann Chase (pathologist at the University of Florida) and others are currently reviewing the effect of these products on fungi.

Wetting Agents are commonly mixed in growing media. They allow the media, such as peat moss, which is often hydrophobic (water-hating) when dry, to accept water into its collective structure. Wetting agents work much like surfactants, breaking the surface tension of water and helping the water transfer from particle to particle. However, their chemistry is different from most surfactants. Many are made up of polyoxyethylene esters, ethoxy sulfates, or derivations of these components mixed with nonionic surfactants.

When applied at too high a rate, a wetting agent can cause membrane permeability problems and cause toxicities that kill roots and leaves.

Occasionally, media from commercial companies contain too much wetting agent. This can cause disfigured, off-color, slow growing plants. Temperature and weather can affect how the plant will react to the presence of a large amount of wetting agent in bark or peat soils.

Other Adjuvants

Penetrants dissolve or penetrate waxy layers on leaves and allow other chemicals to interface with plant cells or insect epidermal tissue and enter the spaces between the epidermal cells, sometimes called “cell free space.” Penetrants can contain petroleum by-products, crop oils, complex alcohols, and other hydrocarbon-based materials. They work well under very specific conditions and with very specific crops grown outdoors. In the greenhouse, stand-alone products are rare.

Anti-condensates

Greenhouse walls made of various films, especially in poly houses with poor ventilation, have condensate problems and drip in the most inopportune places. Anti-condensates act like surfactants, making it easier for water to spread throughout the surface of the film instead of collecting as droplets on the plastic and dripping on plants. By creating a film, the water can be carried off as a thin sheet along the pipe or plastic film. They work great, but should never, ever be used on plants or on soil.

Thickeners are used to reduce drift of sprays

They may contain polyacrylamide, polyethylene polymers, polysaccharides (long-chain sugars), or vegetable oils. These products not only help volatile pesticides become less volatile, they also cause the carrier solution to become more viscous and heavier. This is beneficial when spraying an outdoor production area near a housing subdivision. It reduces drift, odor, and waste. However, when thickeners are applied at too high a dosage, they can cause surface deposits on foliage, excessive exposure to the pesticide, or clog spray nozzles. Use these adjuvants only in outdoor situations and only after reading the label for information about compatibility and phytotoxicity.

Emulsifiers

Emulsifier agents work by coating tiny particles or groups of the liquid molecules and preventing them from coagulating with other like molecules. Unlike oil and vinegar, the emulsifiers allow oil and water solutions to mix. These products are usually added by the manufacturer and are commonly mixed with petroleum-based pesticides to help them mix more readily with water.

Spreader and Stickers

Nonionic surfactant damage to pansy (Viola spp.), Note regrowth.

Spreaders are compounds that cause the surface tension of the pesticide to be reduced in such a way that it easily spreads into a very thin film over a surface. Like surfactants, spreaders and stickers increase the efficiency of the pesticide dramatically. They may contain fatty acids, latex, aliphatic alcohols, crop oils such as cottonseed, or inorganic oils. Each formulation is very different.

Stickers are very much like thickening agents or oils in that they cause the pesticide solution to adhere to the leaf surface, resisting rain, evaporation and runoff. Some products use emulsified polyetheylenes, others use polymerized resins, fatty acids or petroleum distillates. Stickers are commonly used in field crops (like corn and soybeans) where residue on leaves is not a problem. However, in greenhouses, they can cause a mess, especially on leaves with indentations such as Pileas, or hairy plants such as Dusty Miller. Some spreader/sticker combinations cause phytotoxicity in tender annuals and herbs.

The effect of excess soil wetting agent on pansy (Viola spp.) foliage.

Oils

There are two types of oil: crop oils that are derived from soybean and other crops, and inorganic oils that come from petroleum refineries. Some are used as suffocates, which cover the insect and cut of its air supply. Others are used as penetrants to break apart the chitin layers (such as with scales) and cause the insect to die. Still others are used like surfactants, forming film over the leaf, breaking down the cuticle, and allowing the pesticide to enter its target. Some oils are blended with surfactants, to take advantage of the properties of both adjuvants. Oils are rarely recommended for greenhouse use.

New Product Classes

Alkyl polyglucosides. As complex as this term sounds, it simply refers to modified sugars. It has been found that some modified sugar molecules have surfactant-like properties and may be used as spreader/stickers. Although this class of adjuvant has been around for some time, it is only now becoming popular due to its organic origins, biodegradability, and the fact that it is environmentally friendly. There are low foaming and high foaming types, and many are very good wetting agents. Originally developed as environmentally safe cleaning agents (car wash cleaners) in England, they have transitioned to being used in laundry detergents and as agronomic adjuvants. These products have very low potential for phytotoxicity because they are derived from plant sugars. Research on these materials is on-going. Current work indicates they work well with glyphosate herbicide.

Organosilicone surfactant damage to pansy (Viola spp.) leaves when applied in hot (>32ºC) sunny weather

Horticultural oil damage to pansy flower and foliage.

Organosilicates are not exactly new; they were developed in the 1970s, and have many uses including silicone-based sprays for waterproofing. About 10 years ago, their use as spray adjuvants for crop production was discovered. Organosilicate surfactants are very good at increasing the “rainfastness” of pesticides. They also reduce the surface tension and allow everything from micronutrients to fungicides to enter the leaf stomates. These products have phenomenal wetting abilities. Depending on the pesticide they are used with and the application rate, results may be good or bad, so be careful when using these products. Phytotoxicity can occur if these products are used at too high a rate or used when temperatures are above 32 degrees C. Some research suggests that the wetting properties of these surfactants are so good that they can also allow bacteria and fungi to more easily invade plants (via stomata). A sanitary facility, careful applications, and rotation with other surfactants is required to realize the benefits with these products. 

Inorganic Salts

There is continuing research on the use of certain inorganic salts as surfactants. However, most of this work is related to herbicide applications. Many of these products are salts of sodium, potassium and ammonium. Others contain calcium, iron, zinc and magnesium salts and are used in industrial cleaning agents and adjuvants. They also cause plant problems, particularly on greenhouse crops.

So Why Not Just Use Common Kitchen Soaps and Detergents?

orticultural oil / dishwashing liquid damage to pansies.

There are very few adjuvant “soaps” on the market today. Most soaps are in bars and are used for bathing. Also, soaps react with cations in soil and fertilizer and can leave a precipitate residue on foliage. Most greenhouse workers remember gray precipitate on foliage resulting from soap residue.

Today, dishwashing liquids contain both anionic and nonionic surfactants. In most circumstances, their combined effects are synergistic and very potent. None are labeled for use on plants.

Natural Surfactants

Natural surfactants are biodegradable, wetting agents and oils that are processed differently from “crop oils” and alkylated sugars. Materials such as coconut oils, palm oils, castor oils, lanolins, wheat amino acids, and many others have been used in the past, but there is little research to verify these products are effective when used in combination with pesticides or in a greenhouses environment. Furthermore, there is evidence that these products may serve as food sources for bacteria and fungi. Until research gives us confidence in these products, exercise caution when using them.

Bottom Line?

Certain pesticides are recommended to be applied with oils, others with only non-ionic surfactants. The pesticide label specifies whether an adjuvant is needed and which class of adjuvants to use. These recommendations are strict for a reason. Experimenting with surfactants is a risky business. If, after reading the label, you are still unclear about which adjuvant to use, ask the company that produces the pesticide, which is rather difficult especially if you are a small scale farmer. They will tell you if a surfactant is present in the pesticide. There has been much research conducted with adjuvants and adjuvant / pesticide interaction. 

Personally I am using WetPol 800 at their recommended dosage of  5 ml to 8 ml for 18 liters of water. I am purchasing WetPol 800 at RM$18.00 for 4 liters.
#SelfAppointedAgroSolAmbassador
#Agrosol #Organic #Natural #BeeFriendly #PurePlantEnergy
Tested in Malaysia for #AvocadoFriendly #GrapeFriendly #DurianFriendly#MangoFriendly #RockmelonFriendly #PapayaFriendly #TurfFriendly #FigFriendly#BlueButterFlyPeaFriendly #BananaFriendly #ChilliFriendly #LettuceFriendly#BrinjalFriendly #GuavaFriendly #MexicanMintFriendly

Golf Course Turf Grass

Hotel Bangi-Putrajaya

Turf Repairing in progress

Let's go have a round of Golf!
Did a presentation with the Course management people and started a trial for Turf at Bangi Golf Course Resort on the 4th October 2017. Went around the course to orientate myself with the Assistant Course Superintendent. A big thank you. I understand a little more as Turf to a layman like me is weeds.

I found out that Turf needs to be repaired and lots of efforts and steps are taken to to that. Let along using machines that I had not encountered before.

Turf is practically planted in sand and I was made to understand that there is a sub soil level, which include drainage as well. In-fact layers had to be prepared one by one.

There are also different Turf for different area, like greens, fairways, putting & etc. Name of the turf also sounds so alien to me, as I normally refer them as weeds or grass.


As I had never planted grass before, and had a long though on how to go about this.

Irregular Turf.

I can out with an idea of making a marked area and do it at a different concentration. After a couple of trails with other plants in Malaysia, I have a hunch that we don't require a high concentration as stated by our principle, or was it that I calculate wrongly...

This is what I came up with. Bought some PVC
pipes and raffles string. I guess yellow is easier to see. We did this in the nursery in 3 sections. Concentration from 1:200 to 1:600. I then sprinkle in some compost, our Richfield, formulation with Micorriza and Super Nano Gel.

Took me about 2 horse to complete. We were recommended to apply AgroSol either in the morning or evening. Most of the time all my trials, my application time is away from the recommended time, as by the time I finished preparing, it's most probably late morning or afternoon.

I left, and schedule my next schedule in 14 days' time.

Note the Turf is practically growing on sand.

In the mean time I was reckoning, what else can we do for Golf course? I then took time to find out why do they need to grow Turf on sand, which is a poor growing media. It needs lots of nutrients and water to support the Turf. Due to continuous irrigation, we need to manage fungus disease.  I found out that Turf is practically growing in a hydroponic method, because it need to drain off water from the course way. Easier to walk for the golfer with soil/ mud sticking onto their shoes.

Green is turf, Red is root zone and Blue is sand.
On the right, we insert in a layer of BioRichar

Can we make the Golf course more green as in less chemical? Can we reduce the workforce required? After discussing with the management, they came up wit a magic number, 30%. If we can have a saving of 30%, yes , they can explore working with us.

After corresponding with the Assistant Superintendent. I proposed that we work with 2 approach. On the top we treat the turf with our Pure Plant Energy, AroSol. On the bottom we try to amend the sand (Soil). Our Richfield is a good candidate. Germany technology, the Mycorriza promotes root growth, right in the root zone. Porosity and Moisture retention is great. Rich with organic matter, inoculated with good effective microbes shall manifest the growth of the EM. Super Nano gel absorb water, retain and release slowly shall greatly reduce irrigation and energy cost. Introducing a thin layer of say 10 to 20 mm in the root zone should have very good long term effect. Hope this shall help us reach our magic figure. Decided to incorporate this on my next visit.

23rd October. As anticipated, the 1:600 shows better performance.

This is the first time I used an auguring tool of this sort. I had initially scheduled half a day for this task. With this tool, it was a breeze and managed to complete in a very short time. But still, age had caught up with me. Needed plenty of rest in between.

I aimed for the root zone depth, replaced some sand with Richfield. 4 holes per slot.

My visit today 3rd November . Check out my video. The round patch is visible. It is effective

The 200, note the round patches.

The 400, note the round patches.

The 600, note the round patches.

Closer up of the 600.

My visit today, it's drizzling and not suitable for spray AgroSol. Shall come back and continue the trial later part of the month. I personally is very excited as am getting remarkable improvements in 28 days.

Looking forward to optimize further, maybe with a higher range of 1:500, 1:700 and 1:900.

Well, can only do this after my vacation. Stay tune.



AgroSol Grapes results in Malaysia
#Agrosol #Organic #Natural #BeeFriendly 
Tested in Malaysia for #AvocadoFriendly #GrapeFriendly #DurianFriendly #MangoFriendly #RockmelonFriendly #PapayaFriendly
 #TurfFriendly #FigFriendly

Carbon Dioxide Enrichment

CO2 and Plants

It’s important to note that a plant needs and uses CO2 only during daylight hours. And the

more light that’s made available to a plant, the more CO2 it needs for photosynthesis. It is in this process that the carbon-fixing reaction occurs, splitting CO2 molecules into carbon (C) and hydrogen (H) to create food for the plant in the form of sugars and starches.

CO2 is measured in ppm (parts per million). Ambient CO2 levels in the outdoor atmosphere average about 300 to 400 ppm, which is adequate for plants growing in nature. 

With the advent of home greenhouses and indoor growing under artificial lights and the developments in hydroponics in recent years, the need for CO2 generation has drastically increased. Plants growing in a sealed greenhouse or indoor grow room will often deplete the available CO2 and stop growing. The following graph will show what depletion and enrichment does to plant growth:

Below 200 PPM, plants do not have enough CO2 to carry on the photosynthesis process and essentially stop growing. Above 2,000 PPM, CO2 starts to become toxic to plants and above 4,000 PPM it becomes toxic to people.

It had also been ascertained that at higher light intensity, the plants can process more of CO2. Starting from sun rise,  photosynthesis increases and peak during midday, goes through a midday depression, recovers, then drop down and stop at sun set.

There are several common methods of generating extra amounts of CO2:

1. Burning hydrocarbon fuels2. Compressed, bottled CO23. Dry ice4. Fermentation5. Decomposition of organic matter
6. AgroSol Pure Plant Energy.

What is AgroSol?

AGROSOLution is a mixture of finely ground minerals containing a high concentration of CO2

Click HERE to find out more about AgroSol. Or contact me for collaboration. Thank you..