Agricultural surfactants:"efficiency amplifier"of modern agriculture

Agricultural surfactants: "efficiency amplifier" of modern agriculture

At the moment when the spray droplets of pesticides come into contact with the leaves of crops, a "battle of attack and defense" in the microscopic world is being staged. Whether the liquid medicine can break through the defense line of the wax layer of the leaves and whether it can adhere to the leaves for a long time in the wind and rain directly affects the effect of pest control. In this battle, agricultural surfactants are playing a crucial "strategic support" role.

1. Solving the micron-level challenge of "liquid medicine contact"

The surface of crop leaves is covered with a waxy cuticle, and the contact angle can reach more than 120°, which is equivalent to a "natural bulletproof vest". Traditional liquid medicine often forms a "water drop marathon" and rolls off before penetration. Surfactants solve the problem through three mechanisms:

Wetting breakthrough

Non-ionic surfactants (such as fatty alcohol polyoxyethylene ether) reduce the contact angle of the liquid medicine to below 30°, so that the liquid medicine spreads like a "water film". A rice field herbicide experiment showed that the liquid medicine coverage rate increased from 45% to 88% after adding a wetting agent.

Adhesive reinforcement

Cationic surfactants (such as hexadecyl trimethyl ammonium chloride) produce electrostatic adsorption with negatively charged leaves to form "molecular anchor points". In the simulated rainstorm scouring experiment, the residual amount of insecticide containing adhesives was 70% higher than that of conventional pesticides.

Penetration promotion

Siloxane spreading agents can penetrate the stomatal channels and transport the liquid to the leaf flesh tissue. A citrus red spider control experiment showed that the penetration efficiency of the agent increased by 65% and the insect population reduction rate increased by 40% after adding spreading agents.

2. "Smart Partner" of Precision Agriculture

Flying spraying efficiency enhancement

When drones apply pesticides, the atomized particle size of the liquid is often less than 100μm. Adding anti-drift agents (such as polyacrylates) can extend the anti-evaporation time of droplets by 3 times and reduce drift losses by more than 50%. Data from a wheat field aerial spraying operation showed that the pesticide utilization rate increased from 35% to 60% after using anti-drift agents.

Seed treatment

Adding film-forming agents (such as polyvinyl alcohol) to seed coating agents can form "semi-permeable protective clothing" on the surface of seeds. It not only ensures seed respiration, but also controls the slow release of the agent. Experiments show that the germination rate of treated corn seeds increases by 20%, and the underground pest control period is extended by 45 days.

Nano pesticide carrier

Surfactants, as stabilizers of nanoparticles, can prevent the aggregation of active ingredients of pesticides. The particle size of a certain nanopesticide is controlled at 50-80nm. After adding anionic dispersants, the suspension stability reaches 98%, and the duration of the drug effect is extended by 3 times.

3. "Environmental Protection Guardian" of Green Agriculture

Reducing the amount and increasing the efficiency

By optimizing the combination of surfactants, the amount of pesticides can be reduced by 30% while maintaining the control effect. In a demonstration field for the control of rice sheath blight, the cost of pesticides per mu was reduced by 42 yuan after the use of new synergists, and the yield increased by 7.5%.

Directed release

Environmentally responsive surfactants can intelligently control the release timing. For example, pH-sensitive emulsifiers disintegrate in the acidic environment of the pest intestine, improving the targeting of the agent. Field trials of a certain insecticide showed that directed release reduced the amount of bees exposed by 85%, significantly improving ecological safety.

Residue degradation

Biological surfactants (such as rhamnolipids) not only significantly enhance the efficacy, but also accelerate the degradation of pesticides. Experiments show that the half-life of imidacloprid in soil is shortened from 28 days to 14 days after the addition of rhamnolipids, reducing the risk of soil pollution.

4. Future innovation direction

Bionic interface materials

Imitate the reverse design of the super-hydrophobic structure of plant leaves and develop "super-adhesive" surfactants to form a lasting protective layer on the surface of specific crops.

AI-assisted formulation

By predicting the optimal surfactant ratio for different crop/pest combinations through machine learning, an agricultural technology company has developed an intelligent formulation system that makes the efficacy prediction accuracy exceed 90%.

Carbon-based material fusion

The composite system of nanocarbon materials such as graphene quantum dots and surfactants may realize the integration of drugs and machinery, and simultaneously complete the activation of the drug solution and the penetration of the leaves during the spraying process.

From the microscopic interface to the macroscopic farmland, agricultural surfactants are reshaping the "efficiency boundary" of modern agriculture. With the development of precision agriculture technology, these "molecular assistants" will promote the evolution of pesticide use from "extensive coverage" to "intelligent interaction", providing dual guarantees for food security and ecological sustainability. The next time you see a drone flying over a field through a blue fog belt, perhaps it is these invisible "chemical commanders" quietly writing a new chapter in agricultural efficiency.