Suspended load
Suspended load is the portion of sediment transport in rivers, streams, and other water bodies where fine particles such as silt, clay, and sometimes fine sand are carried aloft within the water column by the action of turbulent flow, preventing them from settling to the bed under normal conditions.[1][2] These particles typically range in size from less than 0.063 mm for clay and silt to occasionally including fine sand up to 0.25 mm, and their suspension is maintained by fluid eddies that counteract gravitational settling.[3][2] The transport of suspended load occurs primarily during periods of higher flow velocity and turbulence, such as during storm events or peak discharges, where the energy of the water keeps particles dispersed throughout the water column rather than allowing them to interact directly with the streambed.[4] Unlike coarser sediments, which move near the bed, suspended particles can be wafted high into the flow, with concentration decreasing from the bed toward the surface in a pattern described by the Rouse profile, influenced by factors like particle fall velocity and shear velocity.[5][2] This mechanism allows suspended load to constitute a significant fraction—often the majority—of total sediment transport in many river systems, especially those with fine-grained substrates.[4] Suspended load differs from bed load, which involves coarser particles (typically sand, gravel, or larger) that roll, slide, or saltate along the streambed due to bottom shear stress without being lifted far into the water column.[6][7] It also contrasts with wash load, a subset of suspended load comprising very fine particles (like clay) that are not derived from the bed material and remain uniformly distributed in low concentrations.[8] In gravel-bed rivers, bed load may dominate channel morphology, but suspended load often exceeds it volumetrically in sand- or silt-bed systems, with particles potentially alternating between modes based on flow conditions.[9][10] Measurement of suspended load involves collecting water samples using depth-integrated samplers to capture representative concentrations across the flow profile, often analyzed in laboratories for particle mass per unit volume (e.g., in milligrams per liter or parts per million).[1][11] Turbidity sensors provide real-time proxies by correlating light scattering with sediment concentration, while the U.S. Geological Survey monitors suspended sediment at thousands of streamgages nationwide, with suspended-sediment samples collected at hundreds of sites, revealing loads like the approximately 200 million tons per year in the Mississippi River (as of the 2010s).[12][13][14] Environmentally, suspended load plays a critical role in shaping riverine ecosystems and water quality, as excessive amounts from sources like erosion, agriculture, construction, and dam releases can reduce water clarity, impair filter-feeding organisms, abrade fish gills, and smother habitats for aquatic biota.[3][1] It also fills reservoirs, alters downstream channels, and transports associated pollutants like nutrients or contaminants, making it a major nonpoint source pollutant regulated under frameworks such as the Clean Water Act.[15][4] In geomorphic terms, suspended load influences sediment budgets, floodplain deposition, and delta formation, with its flux reflecting basin-wide processes like land use changes and climate variability.[16][17]Fundamentals
Definition
Suspended load refers to the portion of sediment transport in which fine particles are held aloft in the water column by fluid turbulence, preventing prolonged contact with the streambed. These particles, typically silt and clay, are kept in motion through the upward and downward fluctuations generated by turbulent eddies in the flow, allowing them to be carried downstream over extended distances without settling.[1][4] The term "suspended load" was introduced in the early 20th century by geologist Grove Karl Gilbert in his seminal work on debris transport by running water, where he distinguished it from coarser material moved along the bed. Gilbert's 1914 analysis described suspended load as the finer debris borne aloft in streams, contrasting it with bedload swept along the channel bottom, a framework that laid the groundwork for modern sedimentology in rivers and coastal environments.[18] In the broader context of sediment transport, the total load comprises bed load, suspended load, and wash load, with the latter often considered a subset of suspended material consisting of the finest particles. Suspended load typically accounts for 50-90% of the total sediment transport in many rivers, underscoring its dominance in fine-grained systems.[4]Role in Sediment Transport
Suspended load plays a critical role in shaping river morphology by depositing fine sediments that influence channel evolution and floodplain development over time. In rivers with significant suspended sediment transport, these particles contribute to aggradation, altering channel capacity and promoting the formation of levees and point bars. For instance, in the Mississippi River, a fine-grained system where suspended load dominates the total sediment flux, this process has historically driven the progradation of delta lobes, building extensive landforms over millennia through the deposition of silt and clay. The reduction in suspended sediment load by approximately 50% since the mid-20th century, primarily due to upstream dams, has shifted the delta toward retrogradation, with shoreline retreat rates exceeding 20 meters per year in key areas.[19][20] Beyond fluvial systems, suspended load facilitates coastal sedimentation by supplying fine particles to nearshore environments, where they settle to form mudflats and influence shoreline stability. In oceanic settings, suspended sediments are integral to turbidity currents, dense underflows that transport material across continental shelves and into deep basins, redistributing vast quantities of silt and clay far from river mouths. Additionally, suspended load serves as a vector for nutrient and pollutant dispersal in water bodies, binding phosphorus, nitrogen, and contaminants like heavy metals during transport, which can affect water quality and aquatic ecosystems downstream or in coastal zones. For example, episodic river discharges in regions like Southern California deliver suspended sediments laden with nutrients and pollutants via hypopycnal plumes and gravity currents, impacting biogeochemical cycles over broad shelves.[21][22] In gravel-bed rivers, suspended load often significantly outpaces bed load, with ratios ranging from 10 to 100 or higher, leading to long-term adjustments in channel geometry as fine sediments fill interstices and reduce hydraulic roughness. This disparity underscores suspended load's dominance in total sediment budgets for such systems, where it can constitute over 90% of transport during floods, thereby exerting greater control on overall morphology than coarser bed load components.[23]Characteristics
Composition
The suspended load in rivers and streams primarily consists of fine inorganic particles such as silt (0.002–0.062 mm), clay (<0.002 mm), and fine sand (0.062–0.125 mm), which together dominate the transportable fraction kept aloft by turbulence.[24] These particles often include minerals like quartz and feldspar, which are resistant to weathering and common in eroded bedrock, alongside lesser amounts of organic matter such as fine particulate organic material derived from terrestrial and aquatic sources.[25][26] Sources of these materials vary by landscape but generally stem from the erosion of upstream soils and bedrock, collapse of riverbanks during high flows, and atmospheric deposition of dust or volcanic ash.[24] In urban environments, suspended load additionally incorporates anthropogenic pollutants, including heavy metals, microplastics, and chemical residues from stormwater runoff, which bind to fine particles and alter the overall makeup.[27] Composition exhibits significant variability across environmental settings and temporal scales; glacial meltwater, for instance, features elevated clay content from finely ground rock flour produced by glacial abrasion.[28] In contrast, rivers in arid regions tend toward sandier loads, with greater proportions of fine sand influenced by wind-blown eolian inputs and sparse vegetation allowing more coarse fines to enter suspension.[29] Seasonal fluctuations, driven by rainfall events that mobilize fine soils, further modify these proportions, often increasing silt and clay fractions during wet periods.[24]Particle Properties
Particles in suspended load are typically fine-grained sediments that remain aloft in the water column due to turbulent flow overcoming their settling tendencies. These particles predominantly fall within the size range of silt and clay, less than 0.063 mm in diameter, allowing them to be transported over long distances without rapid deposition.[3] This fine size fraction is characteristic of suspended load in rivers and coastal waters, where coarser materials are more likely to move as bed load. The settling behavior of these particles is primarily governed by Stokes' law for spherical particles in laminar flow conditions, which applies to the fine sizes encountered in suspended load. The formula for settling velocity v_s is given by: v_s = \frac{2}{9} \frac{(\rho_s - \rho) g r^2}{\mu} where \rho_s is the particle density, \rho is the fluid density, g is gravitational acceleration, r is the particle radius, and \mu is the dynamic viscosity of the fluid.[30] This equation highlights how settling velocity scales with the square of particle radius, explaining why finer particles (<0.063 mm) have low settling rates (often <1 mm/s) that turbulence can counteract.[31] Particle shape and density further influence suspension dynamics. Quartz, a common mineral in suspended sediments, has a typical density of 2.65 g/cm³, which affects the buoyancy and settling rate in water.[32] For cohesive clays, flocculation through aggregation into larger but lower-density flocs significantly alters settling; flocculated particles settle much faster than individual clay grains—often by a factor of a thousand or more—due to increased effective size despite reduced density.[33] This process enhances deposition in low-turbulence zones while maintaining suspension in turbulent flows. In natural suspensions, particle size distributions often follow a log-normal pattern, with finer particles dominating the volume concentration in turbid waters. This distribution reflects the heterogeneous origins of sediments and selective transport, where clays and silts prevail in the suspended fraction.[34] Such spectra are evident in riverine and estuarine environments, underscoring the prevalence of sub-micron to silt-sized materials in suspended load.[35]Transport Mechanisms
Turbulence and Suspension
In sediment-laden flows, turbulence plays a pivotal role in maintaining particles in suspension by generating vertical velocity fluctuations that counteract gravitational settling. Turbulent eddies, arising from shear in the fluid flow, produce upward momentum that lifts sediment particles away from the bed; suspension is sustained when the root-mean-square of these upward turbulent velocities exceeds the particles' settling velocity.[36][37] The vertical distribution of suspended sediment concentration is governed by turbulent mixing, which balances diffusive transport against settling. A foundational model for this distribution is the Rouse profile, derived from an analogy to turbulent diffusion in steady, uniform flows. The concentration C(z) at height z above the bed is given by C(z) = C_a \left( \frac{h - z}{z} \cdot \frac{a}{h - a} \right)^Z, where C_a is the reference concentration at a reference height a near the bed, h is the flow depth, and the Rouse exponent Z = \frac{v_s}{\kappa u_*}, with v_s as the particle settling velocity, \kappa \approx 0.4 as the von Kármán constant, and u_* as the shear velocity. This profile predicts a decrease in concentration with height, reflecting the dominance of settling over turbulent diffusion farther from the bed.[38][37] The onset of suspension begins with bed entrainment, where near-bed turbulence bursts provide the initial lift for particles to enter the flow. This process occurs when the intensity of turbulent fluctuations—particularly coherent structures like sweeps and ejections—reaches levels sufficient to overcome particle settling and bed adhesion, transitioning particles from bedload to suspended states.[39][40]Velocity and Flow Conditions
The threshold velocity for suspended load transport represents the minimum flow speed at which turbulent forces exceed the settling velocity of sediment particles, enabling their entrainment into the water column rather than allowing deposition on the bed. This threshold is derived from the balance between upward turbulent diffusion and downward gravitational settling, with values typically ranging from 10 to 50 cm/s for silt-sized particles (0.002–0.063 mm), increasing progressively with particle size as larger grains demand stronger flows to counteract their higher fall velocities. For instance, fine silts around 0.01 mm may suspend at near 10–20 cm/s in turbulent conditions, while coarser silts approaching 0.06 mm require up to 40–50 cm/s.[41][42] In open-channel flows, the vertical distribution of velocity follows a logarithmic profile, governed by the law of the wall, where flow speed u(z) = \frac{u_*}{\kappa} \ln \left( \frac{z}{z_0} \right) increases logarithmically with height z above the bed, with u_* as the shear velocity, \kappa as von Kármán's constant (≈0.4), and z_0 as the roughness length. This profile creates higher velocities in the upper water column compared to near-bed regions, promoting the upward transport and sustained suspension of particles through enhanced shear and turbulence away from the bed. Such distributions are particularly effective in maintaining suspended loads over extended depths, as the accelerating flow near the surface reduces settling rates.[43][44] Environmental factors significantly modulate these velocity conditions in natural systems, where flows are overwhelmingly turbulent, allowing suspension at the aforementioned thresholds via effective vertical mixing. Laminar flows, though uncommon in rivers due to high Reynolds numbers, would necessitate substantially higher velocities—potentially exceeding 100 cm/s for silts—to generate sufficient lift without turbulent eddies, limiting suspended transport in such regimes. Channel slope and depth further influence conditions: steeper slopes elevate mean velocities per Manning's equation (V = \frac{1}{n} R^{2/3} S^{1/2}, where S is slope and R is hydraulic radius), thereby lowering the relative threshold for initiation; deeper flows develop fuller logarithmic profiles, supporting greater suspended loads by extending the zone of high-velocity mixing.[5][45]Comparisons
Suspended Load vs. Suspended Sediment
In sediment transport dynamics, the term "suspended load" specifically denotes the fraction of bed-material sediment—typically coarser particles such as silt—that is actively entrained from the streambed and maintained in suspension by turbulent eddies, allowing for potential re-deposition and interaction with the bed. In contrast, "suspended sediment" refers to the broader assemblage of all particulate matter held aloft in the water column through turbulence or colloidal suspension, encompassing not only the suspended load but also the wash load of ultra-fine particles (e.g., clay and fine silt) sourced from upstream erosion and transported without significant bed exchange. This distinction arises because wash load particles are too fine to settle under typical flow conditions and are not represented in appreciable quantities within the local bed material.[46][47] In the scientific literature, "suspended load" underscores the flow's capacity to mobilize and transport sediment comparable in size to the bed, often calculated via predictive equations tied to shear stress or velocity, whereas "suspended sediment" emphasizes empirical measurements of concentration profiles, such as those obtained from depth-integrated sampling. This terminological nuance traces back to foundational studies like Hjulström's (1935) analysis of river morphology, where the eponymous curve delineates velocity thresholds for particle entrainment and deposition, revealing historical debates on the flow competencies required to initiate suspension of coarser grains versus the persistent transport of fines—a conceptual tension that influenced later refinements in transport mode classifications.[48][49] Practically, this differentiation is vital in river engineering and environmental modeling: suspended load calculations are essential for assessing bed scour, aggradation, and channel stability, as these particles directly influence morphodynamic evolution, while total suspended sediment concentrations—dominated by wash load in many systems—govern impacts on water quality, light attenuation, and ecological habitats through effects on turbidity and downstream siltation. Particle size ranges show overlap, with suspended load often spanning 0.002–0.063 mm (silt) and wash load below 0.002 mm, though boundaries vary by flow regime.[11]Suspended Load vs. Bed Load
Suspended load and bed load represent two distinct modes of sediment transport in aquatic environments, differing fundamentally in how particles interact with the flow and the channel bed. Suspended load involves fine sediment particles that are lifted into and maintained within the water column by turbulent eddies, allowing them to travel throughout the full depth of the flow without significant contact with the bed surface. This mode requires ongoing turbulent energy to counteract gravitational settling, enabling particles to be dispersed vertically and horizontally over extended periods. In contrast, bed load transport occurs when coarser particles move along or very near the bed through mechanisms such as rolling, sliding, or saltation—short jumps where particles are briefly lifted but quickly return to the bed due to their higher settling velocity. These movements are driven primarily by bed shear stress exceeding a critical threshold, resulting in traction-dominated transport that is confined to a thin layer adjacent to the substrate.[50][51] The primary distinction in particle characteristics further delineates these transport modes, with size serving as a key partitioning factor. Suspended load is dominated by fine-grained sediments, typically silt and clay particles smaller than 0.063 mm in diameter, which have low settling velocities and can remain aloft in even moderate flows. Bed load, conversely, consists of coarser materials such as sand (0.063–2 mm) and gravel (>2 mm), which are too heavy to be fully suspended and instead interact continuously with the bed. This size-based separation is not absolute but is well-illustrated by the Hjulström-Sundborg diagram, a seminal graphical representation developed from empirical data on stream velocities and particle entrainment. The diagram demonstrates that for particles finer than about 0.1 mm, the velocity required for deposition exceeds that for erosion, favoring sustained suspension, whereas coarser grains exhibit the opposite trend, promoting bed-confined transport once mobilized.[3][52][53] In terms of environmental roles, these modes exert contrasting influences on geomorphic processes and sediment budgets. Suspended load facilitates high vertical flux and long-distance advection, often comprising the majority of total sediment discharge in rivers and allowing fines to bypass local reaches and contribute to widespread deposition in floodplains, estuaries, or coastal zones. This transport is particularly pronounced during high-flow events, where turbulence amplifies suspension and enables sediment to travel hundreds of kilometers from source areas. Bed load, by comparison, drives localized bed evolution through the formation of morphological features like ripples, dunes, and bars, which modulate flow hydraulics, increase channel roughness, and shape habitat complexity in gravel-bed streams. Although bed load typically accounts for a smaller fraction of overall sediment flux—often 5–20% in sand-bed rivers—its near-bed dynamics are critical for maintaining channel stability and influencing short-term adjustments to discharge variations.[54][51]Measurement and Calculation
Field Techniques
Field techniques for measuring suspended load in natural aquatic environments primarily involve direct sampling and indirect acoustic profiling to capture sediment concentrations and distributions across stream cross-sections or over time. These methods ensure representative data collection under varying flow conditions, with a focus on isokinetic sampling to match intake velocities to stream flows and minimize bias in particle entrainment. The U.S. Geological Survey (USGS) has standardized many of these approaches through its Techniques of Water-Resources Investigations, emphasizing practical deployment in rivers and streams.[55] Direct sampling relies on depth-integrated samplers, such as the US DH-48, which collect water-sediment mixtures along a vertical traverse to obtain discharge-weighted averages of suspended load. This aluminum sampler, weighing 4.5 pounds and equipped with nozzles of 1/8- to 1/4-inch diameters, draws samples into pint or quart bottles while maintaining isokinetic conditions—critical for particles larger than 0.062 mm to avoid over- or under-sampling coarser fractions. Deployment involves traversing the stream cross-section using equal-width-increment or equal-discharge-increment methods, with transit rates adjusted to 0.4 times the mean velocity (typically 0.56 ft/s for a 10-ft depth at 2 ft/s flow) to ensure adequate volume without exceeding permissible limits. For sand-laden streams, multiple integrations per vertical are recommended to enhance accuracy.[55][55][55] Indirect measurement uses acoustic Doppler current profilers (ADCPs), which map velocity profiles and infer suspended load via acoustic backscatter intensity from sediment particles. Down-looking or side-looking ADCPs, such as 614-kHz models deployed on tripods 65 cm above the bed, provide continuous profiles with 0.5-m bin sizes and pings every 15 minutes, enabling time-series data in dynamic settings like tidal rivers. Calibration against physical samples collected with isokinetic samplers (e.g., USGS P-61) correlates backscatter to concentrations, achieving correlations up to R² = 0.86 after temperature adjustments, though single-frequency limitations prevent distinguishing particle size variations. These instruments excel in complex flows where manual sampling is infeasible, offering simultaneous velocity and concentration data across depths.[56][56][56] Deployment strategies vary by site and conditions: fixed-point pumps, like the US PS-69 or ISCO 1680 models, enable automated time-series sampling from a single depth (ideally at mean concentration levels) with capacities for up to 72 samples and lifts to 17 ft, suitable for remote monitoring. In shallow streams, pump-sip systems withdraw samples horizontally or downstream-oriented to optimize intake efficiency, though non-isokinetic biases necessitate cross-section corrections. High-turbidity events, such as floods exceeding 15 ft depths, pose challenges including partial vertical integration (e.g., 0.2 of depth), debris clogging, and ice formation in cold climates, where specialized samplers like the DH-75 are used to prevent nozzle blockage. Site selection prioritizes stable cross-sections free from backwater or excessive turbulence to ensure data reliability.[55][55][55] Post-collection data processing begins with field inspection for sand content and labeling to maintain integrity, followed by laboratory filtration to separate sediment from water. Samples are dried and weighed to compute concentrations in mg/L, requiring a minimum of 1 g for reliable fine-particle analysis; compositing multiple aliquots improves precision for low-yield samples. Particle size distribution is calibrated using laser diffraction instruments, such as the LISST-SL2, which measure in-situ scattering for sizes from 1.2 to 226 μm during field deployment or post-filtration in labs, providing volume-based distributions insensitive to water color. These steps yield empirical concentration profiles, often adjusted with cross-section coefficients to estimate total suspended load without relying on theoretical shear stress derivations.[55][55][57]| Sampler Type | Key Features | Typical Deployment | Limitations |
|---|---|---|---|
| US DH-48 (Depth-Integrated) | Isokinetic, 1/8-1/4" nozzles, 350-800 mL bottles | Hand-held traverses in <15 ft depths | Manual operation; unsuitable for very high flows |
| ADCP (e.g., 614 kHz) | Backscatter for concentration, 0.5 m bins | Tripod-mounted for continuous profiling | Calibration needed; size discrimination issues |
| US PS-69/ISCO 1680 (Pumping) | Automated, up to 72 samples, 17 ft lift | Fixed-point in remote sites | Non-isokinetic bias; single-depth sampling |