Soil Geography • Soil geographers focus on the relationships between soils and landscapes. – How and when were soils formed in a given area? – How are the physical properties of soils related to topography, climate, vegetation and fauna? – How do soils contribute to ecosystem function/health? • Pedologists are primarily concerned with the specific chemical and biological properties of soils, though some spatial analysis is still done. Functions of Soils Supports growth of higher plants a. medium b. nutrient elements Hydrological regulation a. supply b. purification Nature’s recycling system a. role in life cycle b. global climate Habitat for living organisms mammals, reptiles, insects, bacteria Engineering medium a. building material b. foundation Volume composition of a loam surface soil Soil as a Medium for Plant Growth Physical support anchor root system Ventilation CO2 & O2 for root respiration Water high water-holding capacity promotes cooling, nutrient transport, turgor & photosynthesis processes) Temperature Moderation amplitude of temperature wave decreases with depth Protection from Toxins gas ventilation & decomposition or adsorption of organic toxins Nutrient Element Supply Dissolved ions: metallic – K, Ca, Fe & Cu; non-metallic – N, S, P & B; Plants acquire nutrients directly – animals indirectly through plants Regulation of Water Supplies •Nearly all water in lakes, rivers and aquifers passes through or over soils. Consider the impact of soil removal on pathway and timing of water delivered to a stream in a mountainous catchment. •Storage in soils, usage by vegetation, seepage to groundwater Groundwater may take months or years to reach a water body as baseflow. •Water is purified and cleansed while passing through soils. •Contrast with destructive flash flood of muddy water with shallow soil of low permeability Recycler of Raw Materials Nutrients must be reused to maintain productivity Environments with poor recycling end up with deep organic layer The most productive environments have soils that recycle rapidly (tropical rainforest) Organic waste is converted to useful, nutrient-rich humus Mineral nutrients re-converted to forms useful to plants Carbon returned to atmosphere as CO2, the required gas for photosynthesis, and an important greenhouse gas Habitat for soil organisms A handful of soil may contain billions of organisms belonging to thousands of species How is this possible? Range of niches and habitats (anoxic vs. aerated pores, temperature variation, pH variation etc.) Organic matter and plant roots (a) promote the growth of microbes and higher plants. Soils low in organic matter generally are associated with lower productivity and biodiversity. (a) High organic matter content (b) Low organic matter content Engineering Medium Designs for roadbeds or buildings need to account for soil properties Poor soil management and population pressure are often cited as reasons for the downfall of great civilizations Is same happening today on a larger scale? SOIL HORIZONS Partially decomposed organic material dominates ELUVIATION E Horizon may be present ILLUVIATION The exposed wall of a soil pit or road cut is called the soil profile Good mix of mineral and organic particles (mainly mineral) Silicate clays, iron oxides, aluminium oxides, and calcium carbonates accumulate (little organic matter) Least weathered part of the soil profile Regolith (above bedrock) May be transported (ie., can be distinct from parent material) http://www.physicalgeography.net It is not always easy to differentiate between distinct soil horizons Taking samples from each level identified can help (b) (a) Topsoil •The organically-enriched A horizon at the soil surface in a cultivated soil •Most nutrient-rich portion of cultivated soils •Contains the majority of plant roots Subsoil •The soils that underlie the topsoil •Lower in most nutrients •Drainage properties important in determining susceptibility to waterlogging and soil moisture stress Notice the concentration of roots in the more nutrient-rich, aerated, looser organic layers near the surface No crop residues or fertilizers Fertilizers and crop residues received Mineral constituents of soils * * The smallest clays (<0.001 mm) display colloidal properties, as does very fine organic matter Soil Texture Particle Size Distribution Particle Size Differences • Different properties based on the size of the particles, even if same mineral. • Function of surface area. LARGE SAND CLAST mm2*6 LARGE CLAY CLAST mm2 4 = 24 Surface area: 24 x 106 m2 4 um2*6 = 24 m2 Potential surface area within sand grain volume: 24 x 109 m2 Note: Most clasts are not square and would not fit together, leaving pore space. Soil texture is of great significance to plant growth Eg. Clays hold water more tightly than do sands Later, we’ll learn why loamy soils with a high organic fraction provide the most ‘available’ water Hand Texturing (see Box 4.2) • Used to determine the relative contributions of the fine fraction. • Very useful in the field to determine soil texture. • Based on physical properties and “feel”. • Sand feels gritty as you can feel the individual particles. Silts are smooth, and clays are sticky. Start by Making a Ball 1. Falls apart? SAND (or not enough water) Does not fall apart? Continue by making a ribbon. 2. Will not form ribbon? LOAMY SAND 3. Ribbon breaks <2.5cm SANDY LOAM, SILTY LOAM or LOAM 4. Ribbon moderately sticky, firm, 2.5 – 5.0 cm SANDY CLAY LOAM, SILTY CLAY LOAM or CLAY LOAM 5. Ribbon sticky and firm, >5.0 cm SANDY CLAY, SILTY CLAY or CLAY Ribbon Test SILT LOAM SANDY LOAM CLAY Why Hand Texturing Works: SAND Lowest surface area (weak particle attraction). Won’t hold together unless saturated Loses water easily SILT Particles are small enough to hold water well (0.05 – 0.002 mm Too large to feel sticky, just smooth CLAY Clay particles are the smallest (<0.002 mm) Cohesive particles are so small, that they feel sticky. Soil Texture • Different relative amounts of sand, silt, and clay (see soil texture triangle). • Coarse fraction not considered in texture assessment. – Not important for soil texture. – Important for soil structure. • Fine fraction describes the soils ability to hold moisture and store nutrients. Soil Structure •Particles sometimes remain independent •May also form aggregates - roundish granules - cube-like blocks - flat plates •Both texture and structure affect water and air movement within soils •Important for plant growth Soil Organic Matter What is organic matter? •remains of plants, animals and microorganisms •soil biomass (living organisms) •Organic compounds produced by floral and faunal metabolism Relevance to carbon balance •atmospheric CO2 sequestered by plants and stored in soils •CO2 is also lost to atmosphere via microbial decomposition Organic matter as a ‘glue’ •plant roots and soil organisms produce gluelike substances •mineral particles are bound by this ‘glue,’ resulting in a granular soil structure •causes productive, loose, easily managed soil Organic matter as a ‘sponge’ •Increases volume of water that can be held •Increases proportion of water a plant can use (difference between wilting point and field capacity) Organic matter as a ‘fertilizer’ •primary source of N, P and S •nutrients released as soluble ions as organic matter decays •food and energy source for soil organisms What is humus? •stable, colloidal fraction of organic matter •acts as contact bridge between larger particles •surface charges hold soluble nutrients •water held tightly when pores small •stimulates plant growth more effectively than colloidal fraction of clays What is humus? •stable, colloidal fraction of organic matter •acts as contact bridge between larger particles •surface charges hold soluble nutrients SUCTION •water held tightly when pores small, especially when soil is dry (see figure) •stimulates plant growth more effectively than colloidal fraction of clays Figure 1.21 The Soil Solution •Contains soluble, inorganic compounds that supply elements for plant growth •Organic and inorganic colloidal particles release these elements to the soil solution Acidity vs. Alkalinity •H+ and OH- ions in soil solution •Affects solubility and availability of soil nutrients •pH is the negative logarithm of H+ ion activity (pH=6 has 100 times more H+ ions than pH=8) Nutrients taken up through hydrophilic channels (binding sites on protein carrier molecules) (soil water flows) (roots grow) Soil Air •Pores filled either with air or water •High [CO2]; Low [O2] •Effects exacerbated if pore size is small or if soil moisture is high Soil Formation FACTORS AFFECTING SOIL FORMATION 1. 2. 3. 4. 5. Parent Materials (resistance, composition) Climate (precipitation, temperature) Biota (vegetation, microbes, soil fauna) Topography (slope, aspect, hillslope position) Time (period since parent material exposed) 1. PARENT MATERIAL Review of Minerals • Basic building blocks of rocks. • All started as igneous rocks (even metamorphic and sedimentary rocks), but most have been altered and redistributed at surface. • Chemical composition is a reflection of environmental conditions & parent material. • Different levels of stability. – Quartz (SiO2) more stable than Olivine (Mg2SiO4). Time for a quick review of Geography 1010/2030 – the rock cycle… Mineral A natural, inorganic compound with a specific chemical formula and a crystalline structure Examples silicates (quartz, feldspar, clay minerals), oxides (eg., hematite) carbonates (eg., calcite) A rock is an assemblage of minerals bound together • Igneous (solidify and crystallize from molten magma) • Sedimentary (settling) • Metamorphic (altered under pressure) Existing rock is digested by weathering, picked up by erosion, moved by transportation, and deposited at river, beach and ocean sites. Lithification follows (cementation, compaction and hardening) Laid down in horizontally-layered beds Conglomerate Sandstone Siltstone Shale Limestone Coal largest clasts sand cemented together derived from silt mud/clay compacted into rock calcium carbonate, bones and shells cemented or precipitated in ocean waters ancient plant remains compacted into rock Any type of rock is transformed, under pressure and increased temperature • Often harder and more resistant to weathering • Compressional forces: (i) collision of plates, (ii) rock thrust under crust, (iii) weight of sediment above Shale Slate Granite Gneiss Basalt Schist Limestone, dolomite Marble Sandstone Quartzite Mineral composition affects resistance to weathering Most Common Elements Oxygen Silicon Aluminium Iron Calcium Magnesium Sodium Potassium Percentage by Weight Relative susceptibility to weathering Ca Mg K, Al Si Al Fe K, Al Sample minerals and their products Mineral Residual Products Material in Solution Quartz quartz grains silica Feldspar clay minerals silica, K +, Na+, Ca2+ Amphibole (hornblende) clay minerals, limonite, hematite silica, Mg2+, Ca2+ Olivine limonite, hematite silica, Mg2+ (SiO2) PHYSICAL WEATHERING Rocks broken down into smaller rocks, sand, silt and clay (i) Temperature (cracking, exfoliation, freeze-thaw) Expansion and contraction Differential stresses since mineral composition varies Cracking or exfoliation may occur Freeze-thaw weathering in temperate and arctic regions (ii) Abrasion (water, ice and wind) Sediment carried by water, ice and wind abrades (iii)Plants and animals Roots enter cracks and pry apart rock Burrowing animals Frost Wedging •Adequate moisture •Cracks in rocks •Freeze/thaw cycles Glacier National Park, USA – formed due to freeze-thaw weathering) Abrasion by sediments carried by wind Freeze-thaw weathering SLATE RESISTANT SILICATE CLAY MINERALS MARBLE LESS RESISTANT CALCITE Biological Wedging • Biological wedging – plant roots penetrate into cracks causing cracks to widen. • Must have: – Climate hospitable for plants. – Adequate moisture and temperature. Trees (Pinus flexilis and Pinus contorta) growing on very little soil Roots grow into cracks, prying them apart Lakeview Ridge, Waterton Lakes National Park Unloading Removal of pressure of deep burial. Exfoliation Dome Abrasion and Plucking Glacial ice is not clean…loaded with sediment that abrades the surface. Transport by Ice Wind Erosion Particles of sand and dust wear away relatively soft rock. More resistant Less resistant BIOGEOCHEMICAL WEATHERING (i) Hydration H2O molecules bind to a mineral through HYDRATION Oxides of Fe and Al are common (ii) Hydrolysis Water molecules split into hydrogen and hydroxyl components H often replaces a cation in the mineral Releases nutrients (eg. K+) and forms secondary minerals (iii) Dissolution Cations and anions hydrated until they dissociate (iv) Carbonation Acids such as carbonic, nitric and sulphuric acid accelerate dissolution (v) Oxidation-reduction Fe, Mn and S can be oxidized (loses and electron) in the presence of air and water during soil formation Causes destabilizing adjustments in crystal structure May be visible as a change in colour Iron-rich rock weathered by oxidation: Trout River, NL Photo source: http://www.stmarys.ca/conted/webcourses/GEO/GEO99/pubweather/chemcombined.html Crustal warping (eg. due to compressional forces) followed by weathering and erosion near surface Leads to abrupt changes in parent material (complexity), soil quality and even vegetation composition Parent material sediment can be classified by its method of deposition Alluvial/fluvial sediments deposited in a floodplain Alluvial Fans Glacial Deposits 1 2 3 4 – – – – till glaciolacustrine deposits loessial blanket (aeolian) unglaciated (loess) *nearly all of Canada was glaciated! Glaciated, U-shaped Valley Deposition from Outwash Plain Aeolian Deposits Organic Deposits Stages in peatland formation N.B. Many wetland ecologists now believe that forested peat is not necessarily the final stage! Mer Bleue Bog, Ontario Climate • Most influential of the five soil forming factors over large areas. • Determines the nature and intensity of weathering. • Greater precipitation = greater degrees of weathering. • Water percolates through the profile transporting soluble ions and suspended materials (clays). Climate • Water deficiencies can cause problems. – Soluble salts are not carried away. – Over time, these salts can cause salinity problems. • What are the dominant climatic characteristics of Lethbridge? • How do these conditions affect soil development? From de Blij & Miller, 1996, Physical Geography of the Global Environment. Adaptation by M.J. Pidwirny,Okanagan University College Credit: Government of Alberta, 2002 Different Dimensions Soil Zones of Western Canada Black Dark Brown Brown Grey Dark Grey Alberta Saskatchewan Manitoba Temperature & Moisture • For every 10° rise in temperature, biochemical reactions more than double. • Temperature and moisture influence the amount of organic matter. • If you have moisture and temperature present at the same time, weathering and leaching are maximized. • Is this the case in our environment? Biota • Biological activity is the primary contributor to the organic constituent of the soil. • Organisms play a strong role in profile mixing and nutrient cycling. Which ones? • Grassland soils have large accumulations of organic matter. – Beneficial for moisture retention, nutrient storage, and defense against fire. Biota • Forested soils. – Generally lower in soil organic matter. – Not really necessary as the environment has plenty of moisture. – Leaves on forest floor are the principal source of OM. • Very acidic, inhibits the action of soil organisms used to decompose. • Most trees can withstand low pH. Same parent material. Different environment. Crotovinas Topography • Three essential factors – Elevation, slope, landscape position. • Can change in response to climate factors. – More gentle slopes in warm, moist climates. • Causes change in local microclimate. – Different slope aspects. – Lateral changes in soil moisture conditions. Soil Catena Poorly developed B Development of B Deeply weathered B • Depressions also have greater depths of weathering. • Can get the development of very different soils along a slope from top to base. • Same parent material…just different topographic position / characteristics. • Milne (1935) recognized this property and called it a catena (chain). • Steeper slopes have larger amounts of soil loss due to erosion. • Less complete vegetation cover. • Shallower soil development. • Depressions tend to accumulate runoff of moisture and sediment. – Not generally connected to external drainage networks. Time • Takes time to form soils. • Difficult property to gauge. • Over what sort of time scales are soil forming processes significant enough to develop a soil. • Complex system. • Easier to solve if we can control the time factor…known disturbance. Soil Formation in Loess Over Time. Time: Buried Horizons Soil Forming Processes • So we have the five factors…what are the processes that create a soil. • Also known as pedogenic processes. • All processes are in action, but the relative importance is variable. • Transformations, translocations, additions, losses. SYNERGISTIC INTERACTIONS OF MULTIPLE VARIABLES OVER TIME Transformations • Soil constituents are chemically or physically modified. • Primary minerals are converted into secondary products. • Decomposition of organic material into organic matter. • Change of particle sizes. Translocations • Movement of inorganic and organic materials laterally within a horizon or vertically from one horizon to another. – Percolation down (vertically and laterally due to gravity and slope). – Capillary action drawing materials to the surface. • Incorporation of surface organic material into A and B horizons. Losses • Loss of material due to groundwater flow, and erosion of surface materials. – Erosion affects clays and silts more than sands Net effect: Leaves a more sandy profile – Agricultural activities can lead to the removal of large amounts of OM. The Master Horizons