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Infiltrometer

An infiltrometer is a device designed to measure the rate at which water or other liquids penetrate into a porous medium, such as soil, under controlled conditions. This instrument is essential in hydrology and soil science for quantifying infiltration rates, which represent the volume of water entering the soil per unit area over time.^[1] The concept of measuring soil infiltration dates back to the early 20th century, with foundational work like the Green-Ampt model proposed in 1911 for estimating infiltration. Ring infiltrometers were developed in the mid-20th century, evolving from single-ring designs in the 1930s to double-ring versions by the 1950s to improve accuracy.^[2] Common types of infiltrometers include single-ring and double-ring models, which consist of metal cylinders driven into the ground and filled with water to simulate ponded conditions.^[2] The double-ring infiltrometer, featuring an outer ring to minimize lateral flow and an inner ring for direct measurement, provides a more accurate estimate of vertical infiltration by isolating one-dimensional flow through the soil.^[3] Tension infiltrometers, on the other hand, apply negative pressure to measure infiltration into unsaturated soils, offering insights into capillary forces and preferential flow paths.^[4] Infiltrometers are widely applied in agriculture to optimize irrigation practices and assess soil tilth, in environmental engineering for stormwater management and infiltration basin design, and in hydrological studies to predict runoff, erosion, and groundwater recharge.^[5] These measurements help evaluate soil health, guide land-use planning, and support sustainable water resource management by revealing how factors like soil texture, structure, and compaction influence water movement.^[1]

Overview

Definition and Purpose

An infiltrometer is a device designed to measure the rate at which water enters soil or other porous media under controlled conditions.^[6]^[7] This instrument quantifies infiltration, which is the process of water moving downward into soil pores from the surface, primarily driven by gravity and capillary forces that draw water into unsaturated voids.^[8]^[9] The primary purpose of an infiltrometer is to assess soil infiltration capacity, providing critical data for managing water resources effectively.^[10] This measurement informs irrigation scheduling to optimize water application and prevent runoff, evaluates flood risk by modeling surface water absorption, and determines soil permeability for applications in agriculture and environmental engineering.^[11]^[12]^[13] Basic components of an infiltrometer typically include a ring or chamber inserted into the soil to isolate the infiltration area, a water supply system such as a reservoir or constant-head mechanism to maintain ponded water, and tools for measuring volume or depth changes, often via graduated scales or sensors.^[14]^[15] Common configurations, such as single-ring and double-ring designs, adapt these elements to minimize lateral flow and ensure accurate vertical infiltration rates.^[16]

Historical Development

Early assessments of soil infiltration relied on qualitative observations, such as monitoring water ponding in agricultural basins or furrows, which were common practices in farming before the 20th century to gauge irrigation needs and runoff potential. A foundational theoretical milestone came in 1911 with the Green-Ampt infiltration model, which applied Darcy's law to describe water movement into homogeneous soils assuming a sharp wetting front, providing the basis for quantitative infiltration predictions.^[17] In the 1930s and 1940s, researchers like Willard Gardner advanced practical measurement techniques, including the development of a negative-head permeameter in 1939 to quantify unsaturated flow, laying groundwork for field devices that addressed lateral water spread in soils.^[18] By the mid-20th century, single-ring infiltrometers emerged in the early 1950s as portable field tools for direct infiltration rate measurement, with early designs documented by Bower et al. in 1951, allowing researchers to simulate ponded water conditions on site.^[19] To mitigate errors from lateral flow, the double-ring infiltrometer was introduced shortly after, around 1960 by Parr and Bertrand, using concentric rings to promote one-dimensional vertical infiltration for more accurate saturated hydraulic conductivity estimates.^[20] In the late 20th century, tension infiltrometers appeared in the 1980s, enabling measurements under unsaturated conditions by applying controlled suction at the soil surface; Perroux and White's 1988 disc permeameter design became influential for studying near-saturated soil properties without ponding.^[21] Prototypes for automation emerged in the 1990s, such as Maheshwari's 1996 constant-head double-ring infiltrometer using electrode-based water level sensors to reduce manual intervention and improve data precision during extended tests.^[22] Entering the 21st century, infiltrometer technology integrated sensors for real-time monitoring, with post-2000 automated double-ring systems incorporating ultrasonic or pressure transducers to log infiltration dynamically, enhancing reliability in variable field conditions as seen in designs from the 2010s.^[23]

Types

Single-Ring Infiltrometer

The single-ring infiltrometer is a fundamental device for measuring soil infiltration rates under ponded conditions, consisting of a single open-ended cylinder typically constructed from metal or plastic to ensure durability and corrosion resistance. The ring's design features a diameter ranging from 20 to 30 cm and a height of approximately 20-60 cm, allowing it to be driven partially into the soil surface to a depth of 5-15 cm, which helps seal the interface and minimize edge flow effects during testing.^[24] This setup assumes primarily one-dimensional vertical flow through the soil, with negligible lateral divergence, enabling the estimation of field-saturated hydraulic conductivity based on the vertical movement of water. To conduct a measurement, the ring is inserted into the soil at the test site, often sealed with bentonite or grout to prevent leakage along the sides, and then filled with a known volume of water to establish a constant or falling head, typically maintaining a ponding depth of 3-10 cm above the soil surface.^[25] The water level is monitored and recorded at regular time intervals—such as every 1-5 minutes—until a steady-state infiltration rate is achieved, which may take several hours depending on soil properties; the rate is calculated from the cumulative volume of water added to maintain the head or the drop in level over time.^[24] This procedure relies on the soil being initially unsaturated but capable of rapid wetting, with the assumption that flow remains dominated by vertical components until an impermeable layer or saturation front is encountered.^[25] The primary advantages of the single-ring infiltrometer include its low cost, high portability, and simplicity, making it suitable for rapid field assessments without requiring specialized equipment or extensive site preparation. It tests a relatively large soil volume compared to laboratory methods, providing representative in situ data for preliminary evaluations.^[25] Typical applications encompass initial soil surveys in agricultural settings to assess irrigation needs and water retention, as well as broader environmental contexts like stormwater management planning.^[24] However, the assumption of purely vertical flow can lead to overestimation of infiltration rates if significant lateral components occur, particularly in heterogeneous soils.

Double-Ring Infiltrometer

The double-ring infiltrometer represents an advancement in field measurement techniques for assessing saturated soil infiltration rates, developed in the early 1960s to address limitations in earlier designs by confining water flow more effectively. Introduced by Parr and Bertrand in their comprehensive review of infiltration processes, this device uses two concentric rings to promote primarily vertical water movement into the soil, thereby reducing the influence of lateral divergence that can overestimate rates in simpler setups.^[26] The instrument's design features an inner ring, typically 20-30 cm in diameter, for direct measurement of infiltration, surrounded by a larger outer ring of 40-50 cm in diameter that maintains a constant water head and directs flow downward around the inner ring. Both rings are constructed from durable materials such as stainless steel or PVC to resist corrosion and ensure longevity in field conditions. To set up the device, the rings are driven approximately 10 cm into the soil surface using a driving plate and hammer, ensuring a seal without excessive disturbance; the outer ring is then filled with water to saturate the surrounding soil, followed by filling the inner ring to a constant head level, where the volume of water depleted over time intervals is recorded to calculate the infiltration rate.^[27] This configuration offers key advantages, including minimization of three-dimensional flow effects that cause non-vertical divergence, resulting in infiltration rates that more closely approximate one-dimensional vertical flow under saturated conditions. As a result, the double-ring infiltrometer has become a standard method for regulatory testing in soil hydrology, widely adopted for its reliability in applications requiring precise saturated hydraulic conductivity estimates.^[28]

Tension and Disc Infiltrometers

Tension infiltrometers represent an advanced class of devices designed to measure soil infiltration rates under controlled negative pressure, simulating unsaturated conditions without surface ponding. These instruments apply suction at the soil-water interface to drive capillary flow, providing insights into near-saturated hydraulic properties that more closely mimic natural rainfall infiltration compared to ponded methods like the double-ring infiltrometer, which focus on saturated conditions. The tension infiltrometer typically employs a Mariotte bottle system to maintain a constant negative pressure, ranging from 0 to -15 cm of water suction, at the base of a porous plate or membrane in contact with the soil surface. This setup ensures steady-state flow driven primarily by capillary forces in the unsaturated zone, avoiding the lateral divergence and preferential flow often associated with positive-head ponding. The device records the volume of water infiltrated over time, allowing estimation of unsaturated hydraulic conductivity at low matric potentials. Disc infiltrometers, a specific variant of tension infiltrometers, feature a flat, circular disc—typically 10 to 20 cm in diameter—placed directly on the soil surface to minimize edge effects and enhance contact. Adjustable tension is achieved through bubbler tubes connected to the water reservoir, enabling precise control of suction levels and facilitating multiple measurements at sequential tensions on the same site. Their compact and portable design makes them particularly suitable for assessing spatial variability in field soils, such as across agricultural plots or landscapes. Setup involves leveling the disc on the prepared soil surface, saturating the contact material (e.g., fine sand), applying the desired tension, and monitoring cumulative infiltration volumes at regular intervals, often using automated recording systems for accuracy. Key advantages of tension and disc infiltrometers include their ability to capture capillary-driven infiltration in unsaturated soils, which is critical for understanding water movement in the vadose zone under natural conditions. They are especially valuable for estimating hydraulic conductivity at low pressure heads, providing data that inform models of preferential flow and macropore contributions without disturbing the soil structure.^[29] Development of tension infiltrometers began in the 1980s with foundational designs emphasizing automation and precise suction control, such as the automated system introduced by Ankeny et al. in 1988. Disc variants were further refined in the 1990s to improve field efficiency, incorporating portable components and simplified data collection for broader application in spatial hydraulic assessments.

Principles of Operation

Infiltration Measurement

Infiltration measurement using infiltrometers relies on fundamental physical principles governing water flow through porous soil media. The process is primarily described by Darcy's law, which states that the flux q of water through saturated soil is proportional to the hydraulic gradient:

q = -K \frac{dh}{dl}

where K is the hydraulic conductivity, dh is the change in hydraulic head, and dl is the distance along the flow path.^[30] This law assumes one-dimensional, laminar flow under saturated or near-saturated conditions, with infiltrometers applying water to the soil surface to create a measurable head gradient that drives infiltration.^[30] As water infiltrates, the soil transitions from an initial unsaturated state to saturation, eventually reaching a steady-state condition where the infiltration rate stabilizes and reflects the soil's saturated hydraulic conductivity.^[30] The general procedure for conducting infiltration tests begins with thorough site preparation to ensure accurate representation of natural soil conditions. This involves clearing the test area of surface debris, vegetation, and loose material, then leveling the soil surface to promote uniform contact with the infiltrometer.^[31] Rings are inserted gently into the soil using a flat board and mallet to a depth of at least 2 inches, avoiding compaction that could alter soil structure and porosity.^[31] An initial pre-wetting phase follows, where water is added to both inner and outer rings (for double-ring setups) to a depth of about 4 inches, allowing the soil to saturate over 1 hour with periodic refilling at 30-minute intervals; this step minimizes air entrapment and establishes a representative moisture profile.^[31] Subsequent water application can use a constant-head method, maintaining a fixed water level by refilling at set intervals, or a falling-head method, recording the natural decline in water level until stabilization.^[31] Several soil properties and environmental conditions influence the accuracy and variability of infiltration measurements. Soil texture, determined by the proportions of sand, silt, and clay, is a primary inherent factor, with coarser sandy soils exhibiting higher initial rates (often exceeding 0.8 inches per hour) due to larger pores, while finer clayey soils show slower rates (0.04–0.2 inches per hour) from smaller pore sizes and potential surface sealing.^[32] Soil structure, including aggregation and macropore continuity, further modulates flow; well-aggregated soils with stable pores enhance infiltration, whereas compaction reduces it by collapsing voids.^[32] Antecedent soil moisture content dynamically affects rates, as drier soils allow faster initial entry through cracks and pores, slowing to a steady-state as saturation increases.^[32] Temperature indirectly influences measurements by altering water viscosity, which decreases with rising temperature and thereby increases infiltration rates in warmer conditions.^[32] Infiltration tests typically exhibit distinct transient and steady-state phases. The transient phase involves initial rapid infiltration, driven by displacement of air and filling of macropores, which can vary significantly with soil heterogeneity and often lasts from minutes to hours.^[33] This is followed by the steady-state phase, where the rate becomes constant, representing the soil's equilibrium capacity under the applied head and primarily governed by matrix flow.^[33] Analysis methods differ accordingly: transient approaches linearize cumulative infiltration data from early stages to estimate conductivity, while steady-state methods focus on the stabilized rate for more reliable, lower-variability results in heterogeneous soils.^[33]

Data Collection and Analysis

Data collection in infiltrometer tests involves recording the volume of water added to maintain a constant head or the drop in water level within the device at regular timed intervals, typically every 5 to 15 minutes, to capture the transient phase of infiltration.^[34]^[35] Measurements continue until steady-state conditions are reached, defined as a constant infiltration rate maintained for 30 to 60 minutes, often verified by four consecutive readings where the water level drop varies by no more than 0.25 inches.^[34]^[36] This process ensures the data reflect both initial high-rate infiltration and the eventual quasi-steady flow approximating saturated hydraulic conductivity. The basic infiltration rate is calculated as I = \frac{\Delta V}{A \cdot \Delta t}, where I is the infiltration rate (e.g., in cm/h), \Delta V is the change in water volume (cm³), A is the cross-sectional area of the inner ring (cm²), and \Delta t is the time interval (h).^[35] For double-ring infiltrometers, the rate from the inner ring is preferred if it differs from the annular space, with corrections applied for ring geometry to account for the effective infiltration area.^[35] During steady-state, the average rate over the constant period provides the field-saturated hydraulic conductivity estimate.^[35] Advanced analysis employs empirical and physically based models to interpret the full dataset. The Horton equation models cumulative infiltration as I(t) = i_c t + \frac{i_0 - i_c}{m} (1 - e^{-m t}), where i_0 is the initial infiltration rate, i_c is the steady-state rate (approximating saturated hydraulic conductivity), and m is the decay constant; parameters are fitted to time-series data from infiltrometers using least-squares optimization. The Green-Ampt model describes the instantaneous infiltration rate as I = [K_{sat}](/page/Hydraulic_conductivity) \left(1 + \frac{\Delta \theta \cdot S}{F}\right), where K_{sat} is saturated hydraulic conductivity, \Delta \theta is the change in soil water content, S is the wetting front suction head, and F is cumulative infiltration; this requires estimating soil-specific parameters like sorptivity from early-time data.^[37]^[38] Curve fitting involves plotting cumulative infiltration against time, where the initial nonlinear portion informs transient parameters and the linear steady-state slope yields K_{sat}. Area corrections for ring geometry, such as adjusting for lateral spread in single-ring tests, ensure accurate scaling of rates to field conditions.^[39] Modern infiltrometer setups increasingly incorporate data loggers and automated systems, such as low-cost microcontrollers with sensors for real-time volume and head monitoring, enabling precise, continuous recording without manual intervention.^[40] These tools facilitate direct integration with software like MATLAB for model fitting and parameter estimation.

Applications

In Soil and Water Management

Infiltrometers play a crucial role in agricultural applications by assessing soil suitability for crops through measurement of infiltration rates, which determine water retention and drainage capacity. Soils with high infiltration rates, often exceeding 2 cm/h, support crops like corn and soybeans that require adequate aeration and rapid drainage to prevent waterlogging, while lower rates indicate suitability for crops tolerant of wetter conditions, such as rice.^[41] These measurements guide crop selection and rotation strategies to optimize yield and soil health.^[42] In irrigation system design, infiltrometer data ensures systems match soil infiltration characteristics, minimizing water loss through runoff or deep percolation. For furrow irrigation, infiltration parameters derived from cylinder infiltrometers, such as cumulative intake functions (e.g., I_cum = 2.596 t^0.566 mm), inform optimal inflow rates (0.50–2.00 L/s) and furrow lengths to achieve uniform wetting.^[43] In contrast, drip irrigation is preferred for soils with low infiltration rates (<1 cm/h) to deliver water directly to roots, reducing evaporation in arid conditions, whereas furrow systems suit higher-rate soils for efficient surface application. For water management, infiltrometers quantify recharge rates essential for groundwater modeling by estimating field-saturated hydraulic conductivity (K_s). Double-ring infiltrometer tests in stormwater ponds, for instance, yielded K_s values from 0.3 to 19.9 cm/h, enabling simulations of recharge volumes up to 182% higher than initial estimates for managed aquifer recharge.^[44] Additionally, they evaluate tillage-induced compaction effects on infiltration; moldboard plowing increased saturated hydraulic conductivity to 0.0471 cm/s compared to 0.03104 cm/s under no-tillage, reducing compaction-related restrictions on water movement in semiarid soils.^[45] Tillage alone can elevate infiltration rates by over three times in compacted subsoils, sustaining improvements for up to 30 months.^[46] In erosion control, low infiltration rates below 0.5 cm/h signal heightened runoff risk, prompting interventions like cover cropping to enhance soil stability. Infiltrometer measurements integrate with the Universal Soil Loss Equation (USLE) by refining the soil erodibility K-factor; double-ring tests across watersheds produced K values of 0.0010–0.0077 (ton·ha·h·ha⁻¹·MJ⁻¹·mm⁻¹), reducing the average error in USLE erosion estimates by 22 percentage points compared to standard values and improving conservation planning accuracy.^[47] Case examples highlight these applications in arid regions, where infiltrometers support deficit irrigation by calibrating water application to measured rates. In the United Arab Emirates, disc infiltrometers assessed drip irrigation efficiency using wastewater effluent, revealing infiltration improvements that sustained desert forest growth with 20–30% water deficits, preserving groundwater resources.^[48] For post-harvest soil recovery, monitoring with infiltrometers tracks infiltration recovery on compacted harvest tracks, with rates approximately doubling over 5 years through natural processes, informing management to mitigate long-term erosion.^[49]

In Environmental and Engineering Contexts

Infiltrometers play a crucial role in environmental assessments by evaluating the success of wetland restoration projects through measurements of changes in soil infiltration rates. In restored wetlands, these devices help quantify improvements in subsurface hydraulic conductivity, revealing how restoration efforts enhance water retention and flow dynamics compared to pre-restoration conditions. For instance, infiltration tests combined with geophysical imaging have been used to assess subsurface heterogeneity and infiltration capacity at restored wetlands, aiding in the verification of ecosystem functionality and long-term sustainability.^[50] In monitoring pollutant transport within vadose zones, infiltrometers provide essential data on infiltration rates that influence contaminant migration from surface applications to groundwater. By simulating water flow through unsaturated soils, these measurements assess how pollutants, such as those from stormwater runoff, percolate and interact with soil matrices, informing models of solute transport and risk to aquifers. This application is particularly vital in areas with shallow groundwater, where high infiltration rates can accelerate pollutant leaching, necessitating targeted remediation strategies.^[51]^[52] In engineering contexts, infiltrometers are employed for site characterization at landfills, where permeability testing ensures the integrity of lining and capping materials to prevent leachate migration. Double-ring infiltrometers, for example, measure hydraulic conductivity in compacted low-permeability soils, confirming that values remain below regulatory thresholds like 10^{-7} cm/s to minimize environmental risks. Similarly, single-ring infiltrometer tests evaluate the performance of waterproofing barriers in landfill tanks, correlating field infiltration data with laboratory permeability results to validate construction quality.^[53]^[54] For stormwater management in low-impact development (LID), infiltrometers assess the infiltration capacity of permeable pavements, which are designed to reduce runoff by allowing water to percolate through porous surfaces into underlying stone reservoirs. Single-ring infiltrometer evaluations on permeable block pavements with varying joint fillers have shown infiltration rates ranging from 100 to 500 mm/h, supporting the selection of materials that maintain hydraulic performance over time. These tests guide the integration of permeable pavements into urban designs, promoting groundwater recharge and mitigating flood risks in densely developed areas.^[55]^[56] Regulatory frameworks mandate infiltrometer use for compliance, such as ASTM D3385, which standardizes double-ring infiltrometer testing for infiltration rates in geotechnical reports to ensure site suitability for infrastructure projects. This method provides reliable field data on soil hydraulic properties, often required in environmental impact assessments to demonstrate adequate drainage and erosion control. Additionally, infiltration testing with cylinder or double-ring infiltrometers is essential for septic system design, determining soil loading rates to prevent system failure and groundwater contamination in onsite wastewater treatment.^[57]^[31] Case examples illustrate these applications in urban green infrastructure planning, where infiltrometers monitor bioinfiltration basins to optimize stormwater capture and quality improvement. In Lancaster, Pennsylvania, repeated surface infiltration tests on eight bioinfiltration projects have tracked rates over time, informing maintenance protocols and scaling up green infrastructure to cover larger impervious areas. Post-construction assessments of soil amendments, such as adding organic matter to enhance permeability, rely on infiltrometer verification within amended layers to confirm design rates, as seen in stormwater management plans requiring at least three tests per site to validate performance. Tension infiltrometers are occasionally referenced here for simulating natural unsaturated flow in these evaluations.^[58]^[59]^[3]^[60]

Limitations

Measurement Errors and Biases

Soil disturbance during ring insertion is a primary source of error in infiltrometer measurements, as the process can cause soil compaction near the ring walls or create preferential flow paths along the insertion interface, leading to underestimation or overestimation of infiltration rates. Compaction typically reduces measured rates by altering soil structure and pore connectivity, while preferential paths allow excessive lateral leakage, resulting in rate variations of 20-50% compared to undisturbed conditions.^[61]^[62]^[63] Lateral flow bias arises from three-dimensional flow effects beneath the infiltrometer, particularly in single-ring designs, where water diverges horizontally into unsaturated soil, causing overestimation of vertical infiltration rates by 30-70%. Double-ring infiltrometers mitigate this by confining flow to the inner ring, reducing the lateral component to approximately 10-12%, though residual bias persists due to incomplete isolation.^[64]^[65]^[66] Environmental factors significantly influence measurement accuracy; for instance, temperature affects water viscosity, with infiltration rates generally increasing by about 2-3% for each 1°C rise due to decreased viscosity facilitating flow, though other soil-specific factors (e.g., evaporation, microbial activity) may modulate this effect in field conditions.^[67]^[68]^[69] In dry soils, air entrapment ahead of the wetting front compresses trapped air pockets, reducing hydraulic conductivity and infiltration rates by factors of 3 to 10, exacerbating errors during initial wetting.^[70] Operator errors, such as inconsistent maintenance of constant water head or inadequate pre-wetting of the soil, compromise the reliability of transient phase data, where initial high rates may not reflect steady-state conditions and lead to skewed cumulative infiltration estimates. Incomplete pre-wetting fails to establish uniform initial moisture, prolonging the transient phase and introducing variability in rate calculations by up to 50% in heterogeneous soils.^[2]^[71] Spatial variability poses a fundamental bias, as infiltrometers provide point-scale measurements that often fail to capture field-scale soil heterogeneity, including textural gradients, macropores, or layering, resulting in coefficients of variation exceeding 50-100% over distances of 1-10 meters. This mismatch between local readings and broader landscape conditions can misrepresent average infiltration, particularly in structured or anisotropic soils.^[72]^[73]^[74]

Modern Improvements

Since the early 2000s, automation has significantly enhanced infiltrometer usability through sensor-integrated systems that enable real-time monitoring and data logging, thereby minimizing manual intervention and associated errors such as inconsistent readings or transcription mistakes. For instance, Internet of Things (IoT)-enabled double-ring infiltrometers incorporate microcontrollers like ESP-32, conductance-based water level sensors, solenoid valves, and GPS modules to automate water addition, record infiltration rates with timestamps and geolocation, and upload data to the cloud, achieving a reliability of R² = 0.99 compared to manual methods while costing only $115. Similarly, automated tension infiltrometers utilize time-of-flight sensors (e.g., VL53L0X) and supervisory control and data acquisition (SCADA) systems with Arduino and MATLAB interfaces to capture water height every 10 seconds, reducing data processing time from 0.85 hours to 0.01 hours per test and limiting sensor errors to under 11.5% within a 0–400 mm range. These advancements, powered by batteries and solar panels, facilitate continuous field deployment without constant human oversight, improving accuracy in variable soil conditions. Hybrid designs have emerged to combine features of tension and double-ring infiltrometers, allowing multi-head or simultaneous testing for more comprehensive hydraulic property assessment. The concentric-disk tension infiltrometer (CDTI), for example, features an inner disk (50 mm radius) within a larger disk (107.5 mm radius) to measure both confined (Kc) and unconfined (Ku) near-saturated hydraulic conductivity under tensions of -30 to -120 mm, enabling multipotential experiments that reveal Kc/Ku ratios of 0.96–1.45 across clay, sandy loam, and gravelly soils with equivalent results from simultaneous equation and piecewise exponential methods. Complementary approaches integrate double-ring and tension infiltrometers at the same site with dye tracers (e.g., Brilliant Blue FCF) for steady-state infiltration followed by pulse applications of 25–100 mm, yielding saturated conductivity (Ks) estimates where double-ring values (820–2,020 cm/d) exceed tension results by 7–33 times, highlighting vertical versus lateral flow differences while minimizing disturbance. Additionally, mini-disk infiltrometers, with their compact 4.5 cm porous disks, support high-resolution spatial mapping by permitting numerous rapid measurements (e.g., one-minute tests) across heterogeneous landscapes, as in low-cost 3D-printed autonomous versions costing €218 that match commercial performance for scalable hydraulic conductivity profiling in diverse soils. Post-2010, non-invasive techniques like ground-penetrating radar (GPR) have been developed to calibrate and monitor infiltrometer data without soil disturbance, enhancing accuracy for unsaturated properties. Time-lapse GPR surveys during artificial infiltration experiments track wetting fronts and fixed reflectors (e.g., at 120 cm depth), coupled with hydrogeophysical inversion via Markov chain Monte Carlo methods to estimate parameters such as saturated conductivity (Ks), residual water content (θr), and van Genuchten α and n, reducing posterior distribution uncertainties (e.g., Ks by 46 times) when combining moving and fixed data, with errors under 5%. Remote sensing integration further refines these calibrations by assimilating satellite-derived soil moisture with GPR for vadose zone property estimation, as demonstrated in joint data assimilation frameworks that improve infiltration front tracking and hydraulic parameter retrieval since 2014. Software enhancements, particularly AI-driven tools, have improved data analysis by automating curve fitting for models like Green-Ampt, while GIS enables scaling point measurements to larger areas. Artificial neural networks (ANNs) benchmarked against Gaussian processes, support vector machines, and others predict infiltration rates from Green-Ampt inputs (e.g., time, soil texture, porosity) with correlation coefficients up to 0.9366 (training) and 0.8624 (testing), outperforming traditional empirical models by capturing non-linearities in 190 field datasets from Iranian watersheds, with time as the most sensitive parameter. For scaling, GIS-based inverse distance weighting (IDW) interpolation of double-ring infiltrometer data from 25 points across the 154,547-ha Cisadane Watershed generates continuous infiltration maps (rates 0.639–8.668 cm/h), aligning closely with recharge zones derived from soil and land-use characteristics to support groundwater management at watershed scales without exhaustive sampling. Standardization efforts in the 2010s have promoted consistent reporting through updated protocols, such as ISO 22282-5:2012, which specifies equipment, procedures, and result formats for infiltrometer tests to assess ground infiltration capacity for geotechnical and hydrogeological applications, ensuring comparability across studies in civil engineering and waste management contexts.

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Water Infiltration Into Soils - ScienceDirect.com
1960, Pages 311-363. Advances in Agronomy. Water Infiltration Into Soils. Author links open overlay panel J.F. Parr , A.R. Bertrand. Show more. Add to Mendeley.
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[PDF] Double-Ring Infiltrometer - Humboldt
It consists of two (2) stainless steel rings, measuring 12" and 24" diameter x 20" high. The rings incorporate a welded, double edge on the top for increased ...Missing: dimensions | Show results with:dimensions
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Comparison of Single‐ and Double‐Ring Infiltrometer Methods on ...
May 1, 2010 · This study addressed the question of how comparable are two different measurement methods, the single-ring infiltrometer (SR) and double-ring infiltrometer (DR ...Abstract · Materials and Methods · Results and Discussion · Conclusions
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Determination of Hydraulic Conductivity Using a Tension Infiltrometer
May 1, 1991 · Some important practical features of the method are that it does not require measurement of the often-difficult square-root-of-time infiltration ...
[30]
https://doi.org/10.2136/vzj2007.0159
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[PDF] SOIL INFILTRATION TESTING PROTOCOL - IN.gov
The soil infiltration testing protocol describes evaluation and field testing procedures to determine if infiltration BMPs are suitable at a site, as well as to.
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### Summary of Inherent and Dynamic Factors Affecting Soil Infiltration Rates
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Comparing Transient and Steady-State Analysis of Single-Ring ...
With this aim, we sampled both a burned and an unburned site and compared transient and steady-state analysis of single-ring infiltrometer data. The bottomless ...
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Infiltration Testing: Low-impact development fact sheet
The double-ring infiltrometer test measures the infiltration rate of a very small and specific area. Multiple measurements at different areas of the site may be ...
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None
### Summary of ASTM D3385-18: Infiltration Rate of Soils Using Double-Ring Infiltrometer
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Infiltration - Stormwater Treatment: Assessment and Maintenance
The Modified Philip Dunne (MPD) Infiltrometer is a new technique to measure the saturated hydraulic conductivity of surface soil. It is a falling head ...
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6.2 Green-Ampt Infiltration Model – Rain or Shine - OPEN OKSTATE
In 1911, they published physically-based equations describing downward infiltration, upward infiltration (as from a water table), and horizontal ...
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[PDF] Simplified Method to Estimate the Green–Ampt Wetting Front ...
May 13, 2005 · Sensitivity analysis of Ks , #, and S (OY axes) to variations of parameters: ho, tmax , tmed , !", and gc (represented by different line types).
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[PDF] Double ring infiltrometer paper - GeoSystems Analysis
Predicting infiltration rates is among the most important aspects in planning, designing, and managing groundwater recharge systems, flood water retention.Missing: risk | Show results with:risk
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Automated single ring infiltrometer with a low-cost microcontroller ...
A method to automate data collection with a compact infiltrometer under constant head conditions was developed. The infiltrometer consists of a containment ...
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Soil Infiltration | Agronomic Crops Network - The Ohio State University
Infiltration is the downward entry of water into the soil, measured in inches per hour, and is affected by soil organic matter and soil aggregates.Missing: qualitative 1900<|separator|>
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[PDF] MEASURiNG SOiL iNFiLTRATiON RATES iN CULTivATED LAND
The infiltration rates based on crop type (maize and rice) originate from measurements in different environments, ranging from tropical to temperate and dry to ...
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[PDF] INFILTRATION CHARACTERISTICS OF FURROW IRRIGATION IN ...
better basis for design criteria of surface irrigation, as well as for the irrigation practices at the farm level. The main purpose of irrigation is to ...
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Estimation of Infiltration Parameters for Groundwater Augmentation ...
This study evaluated infiltration rates and hydraulic properties of three representative stormwater ponds in the Zeekoe Catchment, Cape Town<|separator|>
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Impacts of Different Tillage Practices on Soil Water Infiltration for ...
Mar 13, 2021 · This study investigates the impact of different tillage managements on the infiltration rate of sandy clay loam soil under a semiarid environment.
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A multi-year study of tillage and amendment effects on compacted ...
Dec 1, 2017 · Tillage alone significantly improved infiltration by a factor of >3 for up to 30 months. •. Amendments generally had no effect on infiltration, ...
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Improvement of the K-Factor of USLE and Soil Erosion Estimation in ...
This study establishes additional values of K-factor by utilizing the double rings infiltration test and measures of soil physical–chemical properties.Missing: infiltrometer | Show results with:infiltrometer<|separator|>
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https://metergroup.com/case-studies/can-wastewater-save-the-united-arab-emirates-groundwater/
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Soil recovery from track construction and harvesting changes in ...
Here we quantify trends in surface soil recovery following timber harvesting activities, specifically snig track (skid trail) construction and logging.
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(PDF) Assessing subsurface heterogeneity and infiltration capacity ...
Mar 30, 2025 · Assessing subsurface heterogeneity and infiltration capacity at a restored wetland using geophysical imaging and infiltration tests. March ...
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Vadose Zone Monitoring as a Key to Groundwater Protection
Dec 13, 2020 · The figure emphasizes the link between water infiltration and contaminant transport through the unsaturated zone to the groundwater below.Abstract · Introduction · Discussion · Author's Note
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Pollutant fate and transport in stormwater infiltration systems
The fate and transport of these pollutants into soil, the vadose zone and ultimately groundwater depends on the type and amount of pollutant present, the volume ...
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The hydraulic conductivity of low permeability wet soils used as ...
The analysis of pressure infiltrometer measurements on low permeability wet soils used for landfill lining and capping material provided an estimate of values ...Missing: characterization | Show results with:characterization
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(PDF) Laboratory Permeability and Single Ring Infiltration Tests for ...
Jul 26, 2020 · We report on the results of several permeability tests carried out both in situ with single-ring infiltrometric tests and in the laboratory with ...
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[PDF] Stormwater Best Management Practice, Permeable Pavements
Permeable pavements are a stormwater control that allows stormwater to infiltrate through the surface of the pavement to the ground below—a green infrastructure.
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Evaluation of surface infiltration rate of permeable block pavements ...
To assess the applicability of single-ring infiltrometer to permeable block pavements, the permeable block pavements with two different joint filler materials ...
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D3385 Standard Test Method for Infiltration Rate of Soils in Field ...
Apr 12, 2018 · This test method describes a procedure for field measurement of the rate of infiltration of liquid (typically water) into soils using double-ring infiltrometer.
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Using Cost-Effective Tools for Assessment of Infiltration at Green ...
Mar 18, 2020 · Helping communities decide which green infrastructure tools are worth the investment of money and maintenance.
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[PDF] Green Infrastructure Monitoring Plan - City of Lancaster, PA
As of December 2018, the City has conducted 65 surface infiltration tests on eight bioinfiltration projects. They have also conducted 27 surface infiltration ...
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[PDF] Design and Construction of Infiltration Facilities
This study used 7 single ring infiltrometer tests and found the geometric mean was within an order of magnitude of the basin wide infiltration rate and more ...
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Using the single-ring infiltrometer method to detect temporal ...
The objective of this study was to compare temporal changes in K fs obtained in the surface layer of a clayey soil using two application procedures of the ...
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Soil Infiltration - Landscape Toolbox
Infiltration rate is important when estimates of runoff are necessary. An infiltrometer is the device used to measure the rate of water infiltration into soil.Description And Uses · Advantages And Limitations · Data Forms
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Surface-positioned double-ring to improve traditional infiltrometer for ...
Jan 30, 2020 · The first method is adding a buffer ring outside the measuring ring, thereby obtaining an accurate measurement in the inner ring (Hillel 1998).
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Study of infiltration process under different experimental conditions
The lateral component ranged from 31.8 to 67.9% for the case of single ring infiltrometers and 11.7–11.92% for the case of double ring infiltrometer with 0.07 m ...Missing: overestimation percentage
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[PDF] Impact of Preferential and Lateral Flows of Water on Single-Ring ...
Aug 19, 2016 · Chowdary et al. (2006) showed that the lateral flow component accounted for 43.7 to 67.9% of cumulative in- filtration measured using a single- ...Missing: percentage | Show results with:percentage
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[PDF] NUMERICAL EVALUATION OF RING-INFILTROMETERS UNDER ...
Jan 11, 2018 · We found that the infiltration rates of a single-ring infiltrometer were f times greater than the 1-D infiltration, where f is a correction ...<|control11|><|separator|>
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Temperature and Time of Day Influence on Double‐Ring ... - ACSESS
Jan 1, 2011 · Steady-state infiltration rates (IRs) correlate well with temperature. They have been observed, however, to have values 1.5 to 2.5 times higher ...
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Temperature dependence of infiltration rate during large scale water ...
Aug 9, 2025 · The study demonstrated that water viscosity increases by 2 % per each one degree decrease in temperature measured in units of Celsius for the ...
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Air entrapment effects on infiltration rate and flow instability
The volume of residual entrapped air in the air-confining condition increased 7% on average, and the infiltration rate decreased threefold to tenfold as ...
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Determining soil infiltration rates - Minnesota Stormwater Manual
Various devices are available for measurement of infiltration within a proposed SCM, including the single ring infiltrometer, double ring infiltrometer, Philip- ...
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Soil infiltration variability across diverse soil reference groups ...
For drier conditions, gravity and Darcian resistance dominate capillary forces, and film flow may be more pertinent than classical capillarity. Future ...
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Assessing Variability of Infiltration Characteristics and Reliability of ...
Jan 30, 2020 · The Horton equation for cumulative infiltration is as follows: I ( t ) ... Analysis of measured data and model parameters. This study has ...
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Determination of Spatial and Temporal Variability of Soil Hydraulic ...
May 5, 2019 · In this study, three measuring techniques for determination of soil hydraulic conductivity were compared in an urban catchment in Ljubljana, Slovenia.