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Agricultura y Agrociencia Industria
The Practical Guide to Surface Science (2026)

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Esta es una guía práctica de la Ciencia de Superficies para investigadores que trabajan en la industria de la agricultura y la agrociencia.

En esta nueva guía aprenderás todo sobre:

  • Principios cruciales de la ciencia de superficies
  • La importancia de las mediciones de la ciencia de superficie para la industria agrícola y agrocientífica
  • Normas y directrices ASTM aplicables

Vamos a sumergirnos en ello.

Agricultura y Agrociencia

Contenido

medición

Medición del ángulo de contacto

tensión

Medición de tensión superficial

energía

Medición de energía superficial

Ángulo de deslizamiento

Medición del ángulo de deslizamiento

Mundo real

Aplicaciones en el mundo real

Guía Standardand

Normas y directrices

Executive Summary

What it covers: A practical, Farming & Agriscience–focused playbook for measuring and applying four key surface properties—contact angle, surface tension (including dynamic), surface energy, and sliding angle—to understand wetting, spreading, adhesion, and runoff on real agricultural materials and plant/soil surfaces. It connects the fundamentals to instrument methods, benchmarking data, and real-world use cases like pesticide performance, irrigation efficiency, and seed coatings.
Key insights: Real agricultural surfaces rarely have a single “true” contact angle—advancing/receding (dynamic) angles capture hysteresis and give a more reliable picture of wetting, cleanliness, roughness, and heterogeneity than a single static value. For liquids, dynamic surface tension matters whenever interfaces change quickly (droplet/bubble formation, foams, drying/evaporation), and method choice (Young–Laplace vs. polynomial fits for droplet shape; force tensiometry vs. optical methods for tension) directly impacts consistency and what you can claim for compliance.
Business value: Use surface measurements to engineer better on-leaf coverage and retention (reduced runoff, improved pest control), tune adjuvants and tank mixes for consistent spray behavior, and improve soil/seed technologies that boost moisture management and germination—raising yield while cutting chemical and water waste. The included benchmark datasets and reporting guardrails help teams spot contamination, treatment drift, and formulation variability early, before they become field failures.
Standards to follow: Follow ASTM D1331 when you must report surface/interfacial tension via Du Noüy ring or Wilhelmy plate force tensiometry, and do not label optical pendant-drop results as “ASTM D1331” without a validated bridging correlation and ongoing verification. For defensible QC and R&D, standardize and document sample prep (water quality, dilution order, equilibration time), temperature control, cleaning/conditioning, replicate statistics, and any deviations in an internal SOP aligned to the guide’s minimum reporting checklist.
Bottom line: This guide shows how to select and run the right surface measurements—and interpret them correctly—to optimize agricultural formulations and surfaces for wetting, adhesion, infiltration, and slip behavior in the real world. Done with the right methods and standards language, surface science becomes a fast, quantitative decision system for improving performance, sustainability, and reproducibility across agriscience workflows.

Capítulo 1: Introducción

Comprender las propiedades físicas y químicas de las superficies es crucial en la agricultura. Por ejemplo, saber cómo se comportan las gotas de agua en las hojas de las plantas, cómo se adhieren los pesticidas a los cultivos y qué tan eficientemente funcionan los sistemas de riego puede afectar significativamente los resultados agrícolas, la sostenibilidad y la productividad.

We use the following surface properties to understand the behavior of Farming & Agriscience products and improve their quality.

Capítulo 2: Medición del ángulo de contacto

El ángulo de contacto cuantifica la humectabilidad de una superficie representando el ángulo entre la superficie de un líquido y una superficie sólida.
Investigación de Dropletlab

Sample Image taken from Droplet Lab Tensiometer.

Joven – Método Laplace

  • 1. Este método utiliza todo el perfil de caída para calcular el valor del ángulo de contacto.
  • 2. This method is only compatible with an axisymmetric drop, which is not always seen in practice because a needle is typically inserted into the drop to increase or decrease the drop volume.
  • 3. This method yields more consistent results than the polynomial fitting method.

Método polinómico

  • 1. This method uses only a portion of the drop profile to calculate the contact angle value.
  • 2. Este método es compatible con caídas axisimétricas y no axisimétricas.
  • 3. The measurement results of this method are less consistent, as they can be influenced by local surface imperfections.
Ángulo de contacto dinámico

Ideally, when we place a drop on a solid surface, a unique angle exists between the liquid and the solid surface. We can calculate the value of this ideal contact angle (the so-called Young’s contact angle) using Young’s equation. In practice, due to surface geometry, roughness, heterogeneity, contamination, and deformation, the contact angle value on a surface is not necessarily a single consistent value but rather falls within a range. The upper and lower limits of this range are known as the advancing and receding contact angles, respectively. The values of advancing and receding contact angles for a solid surface are highly sensitive to many parameters, such as temperature, humidity, homogeneity, and minor contamination of the surface and liquid. For example, the advancing and receding contact angles of a surface can differ at different locations.

Ángulo de contacto dinámico frente a ángulo de contacto estático

Las superficies y los recubrimientos prácticos muestran naturalmente histéresis de ángulo de contacto, lo que indica un rango de valores de equilibrio. Cuando medimos ángulos de contacto estáticos, obtenemos un solo valor dentro de este rango. Confiar únicamente en mediciones estáticas plantea problemas, como una repetibilidad deficiente y una evaluación incompleta de la superficie con respecto a la adherencia, la limpieza, la rugosidad y la homogeneidad.

In practical applications, we need to understand how easily a liquid spreads (advancing angle) and how easily it is removed (receding angle), such as in painting and cleaning. Measuring advancing and receding angles offers a holistic view of liquid-solid interaction, unlike static measurements, which yield an arbitrary value within the range.

Esta información es crucial para las superficies del mundo real con variaciones, rugosidad y dinámica, lo que ayuda a industrias como la cosmética, la ciencia de los materiales y la biotecnología a diseñar superficies efectivas y optimizar los procesos.

Aprenda cómo se realiza la medición del ángulo de contacto en nuestro tensiómetro

Para una comprensión más completa de la medición del ángulo de contacto, lea nuestra medición del ángulo de contacto: la guía definitiva

Medición del ángulo de contacto: la guía definitiva

Open Benchmark Data: Contact Angle & Surface Energy

These reference measurements show how deionized water wets four standard substrates measured with the Droplet Lab Dropometer. Use them as visual and numerical benchmarks when you're checking your own sample preparation, treatments, and chemistry.

Full contact angle and surface energy datasets (including additional liquids and statistics) are available on our dataset hub.

Glass - DI Water
Glass - DI Water
Nylon - DI Water
Nylon - DI Water
PMMA - DI Water
PMMA - DI Water
Teflon - DI Water
Teflon - DI Water

The droplet images above are taken from the same benchmark series as our open dataset. For each substrate and probe liquid we report:

● Advancing and receding contact angles (and hysteresis)
● Derived surface energy (SFE) values based on multi-liquid measurements
● Measurement conditions, uncertainties, and sample preparation details

Comparing your own droplet shapes and angles against these references is a fast way to spot contamination, treatment drift, or unexpected changes in wettability.

Explore the full benchmark datasets (contact angle + surface energy)

Measurements were performed with the Droplet Lab Dropometer under controlled laboratory conditions. Treat these values as sanity checks and starting points for your own process targets, not as product specifications.

Capítulo 3: Medición de la tensión superficial

Esta propiedad mide la fuerza que actúa sobre la superficie de un líquido, con el objetivo de minimizar su superficie.

Medición de tensión superficial

Sample Image taken from Droplet Lab Tensiometer

Tensión superficial dinámica

La tensión superficial dinámica difiere de la tensión superficial estática, que se refiere a la energía superficial por unidad de área (o fuerza que actúa por unidad de longitud a lo largo del borde de una superficie líquida).

La tensión superficial estática caracteriza el estado de equilibrio de la interfaz líquida, mientras que la tensión superficial dinámica explica la cinética de los cambios en la interfaz. Estos cambios podrían implicar la presencia de tensioactivos, aditivos o variaciones en la temperatura, la presión y la composición en la interfaz.

Cuándo utilizar la medición dinámica de la tensión superficial

Dynamic surface tension is essential for processes that involve rapid changes at the liquid-gas or liquid-liquid interface, such as droplet and bubble formation, coalescence (change in surface area), the behavior of foams, and the drying of paints (change in composition, e.g., evaporation of solvent). It is measured by analyzing the shape of a hanging droplet over time.

La tensión superficial dinámica se aplica a diversas industrias, incluidas las cosméticas, los recubrimientos, los productos farmacéuticos, la pintura, los alimentos y las bebidas, y los procesos industriales, donde la comprensión y el control del comportamiento de las interfaces líquidas son esenciales para la calidad del producto y la eficiencia del proceso.

Aprenda cómo se realiza la medición de la tensión superficial en nuestro tensiómetro

Para una comprensión más completa de la medición de la energía superficial, lea nuestra medición de la tensión superficial: la guía definitiva

Medición de la tensión superficial: la guía definitiva

Capítulo 4: Medición de la energía superficial

La energía superficial se refiere a la energía requerida para crear una unidad de área de una nueva superficie.
231

Sample Image taken from Droplet Lab Tensiometer

Aprenda cómo se realiza la medición de la energía superficial en nuestro tensiómetro

Para una comprensión más completa de la medición de la energía superficial, lea nuestra medición de la energía superficial: la guía definitiva

Medición de energía superficial: la guía definitiva

For benchmark contact angle and surface energy values on glass, nylon, PMMA, and Teflon, see the Open Benchmark Data panel above or visit our Dataset Hub for full CSV downloads.

Dataset Hub

Capítulo 5: Medición del ángulo de deslizamiento

El ángulo de deslizamiento mide el ángulo en el que una película líquida se desliza sobre una superficie sólida. Se emplea comúnmente para evaluar la resistencia al deslizamiento de una superficie.

Ángulo de deslizamiento 1

Sample Image taken from Droplet Lab Tensiometer

Aprenda cómo se realiza la medición del ángulo de deslizamiento en nuestro tensiómetro

Para una comprensión más completa de la medición del ángulo de deslizamiento, lea nuestra medición del ángulo de deslizamiento: la guía definitiva

Medición del ángulo de deslizamiento: la guía definitiva

Capítulo 6: Aplicaciones en el mundo real

Dentro de la industria de la agricultura y la agrociencia, varios estudios de caso ejemplifican las ventajas de realizar mediciones de las propiedades de la superficie.

Forestry & Agriscience: Using water contact angle to quantify functional surface recovery in refoliated quaking aspen after LDD moth defoliation

The paper investigates a severe mid-summer defoliation event (Ontario, Canada, 2021) where quaking aspen trees were completely stripped of leaves by LDD moth caterpillars, then refoliated within the same year. The regrown leaves were smaller, but still exhibited strong non-wetting behavior. The authors attribute the high water contact angles to a hierarchical “dual-scale” leaf surface: nanoscale epicuticular wax (ECW) crystals superimposed on microscale papillae, consistent with a Cassie–Baxter non-wetting state. Differences between refoliated vs. typical-season leaf surface morphology are discussed in relation to environmental growth conditions (notably seasonal temperature during development after budbreak).

Role of Droplet Lab Goniometer

The Droplet Lab Dropometer was used to quantify the wettability recovery of refoliated aspen leaves by measuring water contact angle (WCA) on the adaxial (upper) leaf surface during the regrowth period. Specifically:

  • In Section 2.3 (“Wetting characteristics”), the study describes WCA measurements performed with the Droplet Lab Dropometer using 10 µL deionized water droplets, with ≥9 measurements per sampling date and reporting mean ± standard deviation.
  • These WCA measurements provided the primary functional metric linking:
    (1) refoliation timing and leaf development, to
    (2) micro/nano surface morphology (SEM), and to
    (3) the onset and persistence of a superhydrophobic/non-wetting state.

Where contact angle is explicitly described in the paper:

  • Methods: Section 2.3 (Droplet Lab Dropometer, 10 µL DI water, replicate counts)

Results: Section 3.2, plus Fig. 2–4 and Table 1 (WCA values/trends and correlation to surface structures)

Key Findings

  • Same-season recovery is possible: Quaking aspen in the study could refoliate in the same year after complete LDD defoliation, though with smaller leaves than typical spring growth.
  • High hydrophobicity appears quickly: Refoliated leaves were already strongly hydrophobic within ~2 days after budbreak, rather than requiring a long “ramp-up” period.
  • Measured WCA range during refoliation: Reported average WCAs across the refoliation study window were approximately ~140° to ~150° (with date-to-date variation reported as mean ± SD). (See Section 3.2, Fig. 2–4, and Table 1.)
  • Mechanism confirmed by structure + WCA: SEM showed a dual-scale hierarchy (microscale papillae + nanoscale ECW crystals) consistent with a Cassie–Baxter non-wetting state, aligning with the high WCA measurements.
  • Ultra-low adhesion prevented roll-off testing: The team notes they could not accurately measure roll-off angle because droplets rolled off immediately with slight disturbance (stated in Section 2.3).
  • Environmental conditions likely tune morphology: The refoliated leaves showed subtle morphology differences versus normal-season leaves, plausibly linked to temperature during growth after budbreak.

Why It Matters

For forestry, tree health monitoring, and agriscience, this paper shows that contact angle can serve as a fast, quantitative “functional recovery” metric after insect-driven defoliation events. In practical terms, pairing WCA with microscopy allows researchers and land managers to distinguish between “leaf return” and return of critical surface function (water shedding/non-wetting), which can influence canopy water interception, surface cleanliness/pathogen interactions, and broader ecohydrology behaviors discussed by the authors.

Method Snapshot

  • Sample: Refoliated quaking aspen (Populus tremuloides) leaves collected repeatedly during July–Aug 2021 after complete defoliation.
  • Droplet: 10 µL deionized water dispensed on the adaxial leaf surface.
  • Angle type: Static water contact angle (WCA) (advancing/receding not reported).
  • Temperature: Not explicitly specified for the contact angle test conditions (study provides outdoor weather context for growth conditions).
  • Surface tension: Not measured/reported (DI water used as the probe liquid).

Data Note

Comparison of average WCAs (with standard deviations) on the adaxial surface of quaking aspen leaves from the refoliation period in 2021 (current study, July 18th -August 26th, 2021) and from the same period in a year for a normal growth season (July 18th – September 1st, 2012) (Tranquada and Erb, 2014). Averages are based on at least 9 contact angle measurements per leaf collection date. 

Figure

Citation (APA Format)

Sui, X., Tam, J., Keller, H., Liang, W., & Erb, U. (2023). Superhydrophobicity mechanism of refoliated quaking aspen leaves after complete defoliation by LDD (gypsy, spongy) moth caterpillars. Plant Science, 330, 111659. https://doi.org/10.1016/j.plantsci.2023.111659

View Publication →

Adhesión de plaguicidas

Desafiar : La distribución desigual de plaguicidas puede provocar infestaciones de plagas y enfermedades en la agricultura.

Importancia del ángulo de contacto : Los ángulos de contacto adecuados en las formulaciones de plaguicidas garantizan una cobertura equilibrada en las superficies de las plantas.

Solución : Una granja probó varias formulaciones de plaguicidas con diferentes ángulos de contacto. Descubrieron que las formulaciones con un ángulo de contacto cercano a cero se adherían mejor a las hojas de las plantas, lo que reducía la escorrentía de pesticidas y mejoraba el control de plagas, lo que conducía a cultivos más saludables.

Adhesión de plaguicidas

Control de plagas

Desafiar : Las gotas de plaguicidas deben esparcirse uniformemente en las superficies de las plantas para maximizar la efectividad.

Importancia de la tensión superficial : La tensión superficial optimizada en las formulaciones de plaguicidas garantiza una cobertura uniforme.

Solución : Los investigadores desarrollaron una nueva formulación de plaguicida con baja tensión superficial. Esta formulación produjo gotas más finas que se propagan de manera más uniforme en las hojas de las plantas, mejorando el control de plagas y reduciendo el uso de pesticidas.

Control de plagas

Manejo de la humedad del suelo

Desafiar : Mantener la humedad del suelo es fundamental para la salud de los cultivos.

Importancia de la energía superficial : Modificar el suelo con la energía superficial adecuada puede mejorar la retención de humedad.

Solución : Researchers created a soil amendment to optimize surface energy. This improved the soil's water-holding capacity, reduced the need for frequent irrigation, and enhanced crop resilience during droughts.

Manejo de la humedad del suelo

Germinación de semillas

Desafiar : La germinación ineficiente de las semillas puede reducir el rendimiento de los cultivos.

Importancia del ángulo de contacto : Los recubrimientos de semillas con ángulos de contacto específicos pueden mejorar la germinación al controlar la absorción y retención de agua.

Solución Los investigadores analizaron los ángulos de contacto de diferentes recubrimientos de semillas y descubrieron que los recubrimientos hidrofílicos (ángulos de contacto <90°) promovían una mejor germinación al acelerar las fases de imbibición y metabolismo activo. Esto mejoró la disponibilidad de agua y aire en regiones propensas a la sequía, lo que aumentó el rendimiento de los cultivos.

Germinación de semillas

Eficiencia del riego por goteo

Desafiar : La distribución desigual del agua en los sistemas de riego por goteo puede causar desperdicio de agua y un crecimiento inconsistente de los cultivos.

Importancia de la tensión superficial : El control de la tensión superficial de las gotas de agua de riego es crucial para un suministro uniforme.

Solución Un equipo de investigación descubrió que los tensioactivos se adsorbían en las partículas hidrofóbicas del suelo, lo que reducía la tensión superficial del agua y mejoraba la infiltración. Una granja agregó surfactantes a su agua de riego, lo que condujo a tamaños de gota más consistentes y una mejor distribución del agua, lo que mejoró el rendimiento de los cultivos y conservó el agua.

Eficiencia del riego por goteo

Somos sus socios en la resolución de su negocio y tecnología Desafíos

Si está interesado en implementar estas u otras aplicaciones, póngase en contacto con nosotros.

Contáctenos

Capítulo 7: Normas y directrices

In an industry where precision reigns supreme, how can Farming & Agriscience manufacturers ensure their products withstand scrutiny? The answer lies in standards and guidelines: the compass that guides them through the complex maze of quality and performance.

ASTM D1331 — Surface & Interfacial Tension of Solutions (Du Noüy Ring / Wilhelmy Plate Force Methods)

What it is

ASTM D1331 is a method-defined standard for measuring surface tension and interfacial tension of liquid materials using force tensiometry, where a Du Noüy ring or Wilhelmy plate is pulled from a liquid or across a liquid–liquid interface. Results should only be labeled “ASTM D1331” when produced using these ring/plate force methods (optical pendant-drop methods are not D1331 as-written).

When to use it

Formulation QC and supplier/customer specs for agrochemicals/adjuvants

Use when a product spec, COA language, or dispute-resolution test requires a ring/plate surface or interfacial tension value reported as ASTM D1331 (e.g., spray adjuvants, EC/ME concentrates, tank-mix additives).

R&D screening tied to spray performance and emulsion behavior

Use when optimizing wetting/spreading on leaves, coverage, compatibility, and emulsification (water/oil) where tension is a sensitive indicator of surfactant package changes or contamination.

In-scope / Out-of-scope

In scope
  • Surface tension of agriculture-relevant liquids (e.g., adjuvant concentrates, surfactant solutions, pesticide dilutions, fertilizer solutions, spray tank mixes) measured by Du Noüy ring or Wilhelmy plate.
  • Interfacial tension for systems with two liquid phases (e.g., water/oil or water/solvent) to support emulsion design, compatibility, and phase-separation troubleshooting.
  • Batch-to-batch trending when temperature, sample handling, and ring/plate cleanliness are controlled and documented.
  • Comparative studies across surfactant packages (nonionic/anionic, organosilicone, etc.) using consistent geometry and procedures.
Out of scope
  • Optical pendant-drop (Young–Laplace) measurements (e.g., Dropometer pendant drop) and other non-force optical methods—these are not ASTM D1331 compliant as-written.
  • Dynamic surface tension at short timescales relevant to spray atomization (may require other methods if you need milliseconds-to-seconds behavior).
  • Highly particulate, dirty, or solid-laden samples (e.g., suspensions/SCs, some biological slurries) where ring/plate wetting/contamination makes results unreliable without a validated sample-prep approach.
  • Leaf contact angle/retention on plant surfaces (use contact-angle/leaf-wetting protocols; D1331 measures liquid tension, not surface wetting on solids).

Minimum you must report (checklist)

  • Sample identity (product/formulation name, lot/batch; dilution rate and water quality if a tank-mix simulation is used—hardness, pH, ions).
  • Property measured (surface tension or interfacial tension; for interfacial, clearly identify both phases and their preparation).
  • Instrument + geometry (Du Noüy ring or Wilhelmy plate; material and relevant dimensions).
  • Temperature and equilibration time (setpoint/measured temperature; time since mixing/dilution—critical for surfactants).
  • Sample preparation and handling (mixing method, degassing/settling, filtration if used; bubble/foam controls).
  • Cleaning/conditioning protocol for ring/plate and vessels (including how you verify cleanliness with a reference check).
  • Replicates and statistics (n, mean/median, SD/IQR; outlier/rejection rule).
  • Any deviations from ASTM D1331 or your internal SOP (and why).

Note: Dropometer (optical pendant-drop Young–Laplace) can be a strong internal screening/trending tool for spray-mixture drift and contamination, but it must not be reported as “ASTM D1331” because it does not use ring/plate force tensiometry. If you want D1331-equivalent decision gates from a faster method, build and maintain a documented method-bridging correlation to a D1331 ring/plate reference.

How to interpret results (guardrails)

  • Method-specific means method-specific: do not assume pendant-drop γ equals D1331 γ without a validated correlation and ongoing verification.
  • Tie interpretation to the use case: lower surface/interfacial tension often supports wetting/emulsification, but real spray outcomes also depend on viscosity, formulation elasticity, droplet size distribution, and plant surface chemistry—validate against field/bench performance tests.
  • Use variability as a warning signal: rising scatter or unstable readings often indicate contamination (oils/silicones), foam/bubbles, poor cleaning, or phase instability—fix the cause before making formulation decisions.
  • Standardize “tank-mix realism”: if you’re testing diluted sprays, lock down water source/condition (hardness, pH), dilution order, and wait time, or you’ll measure process variation instead of formulation change.
View the official ASTM D1331 Standard

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We hope this guide showed you how to apply surface science in the Farming & Agriscience industry.

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