Water and Development Part 2c: Sub-surface and Groundwater Milind Sohoni www.cse.iitb.ac.in/ sohoni email: sohoni@cse.iitb.ac.in () August 12, 2017 1 / 29
Objectives Sub-surface and Groundwater: Stocks and Flows. How does GW and SSW function as stocks? Sub-surface water (a.k.a. Soil Moisture) in the top few meters. Groundwater: deeper, saturated. Complex interaction between SSW and GW. What are the basic mechanisms (laws and models) by which they work? What are the key parameters to describe these and how are these measured? () August 12, 2017 2 / 29
Groundwater Deep. Accessed through wells and bore-wells. Water-Table: important concept. How much water is available through-out the year? Specific Yield Does it depend on the nature of soil/rock underneath? Aquifer How do different wells interact? Conductivity Ground Well WaterTable 000 111 000 111 000 111 000 111 000 111 () August 12, 2017 3 / 29
Porosity: Soil as a container Porosity: The fraction of empty space with a soil. em Depends on configuration. Porosity depends on the regularity of particle size. The more sorted the particles, the higher the porosity. May change across different areas and different depths. High Porosity Low Sand 0.1mm-1mm Silt 0.005mm-0.1mm Clay < 0.005mm () August 12, 2017 4 / 29
Moisture Moisture: The volume fraction of wet soil which is water. Water exists in within the voids and is either (i) loosely held, or (ii) tightly held by soil particles. Soil moisture n increases with depth and reaches its theoretical maximum of proposity p. This is called saturation. At this point, soil moisture equals porosity. depth p moisture saturation () August 12, 2017 5 / 29
Saturation The region below is called the saturated region. The region above is the unsaturated region. This depth is called the depth of the water-table. At this depth, water appears spontaneously in a dug-well. Saturated water can be extracted easily. Unsaturated region: important for plants and microbes. Groundwater also flows just as ordinary water, albeit at different rates. Groundwater flows eventually go to streams, rivers and oceans. Ground Well WaterTable 000 111 000 111 000 111 000 111 000 111 () August 12, 2017 6 / 29
Moisture when it rains: When the rain falls (a) Before Rains: surface moisture less than porosity. (b) Start of Rain: surface mosture starts increasing: Infiltration phase. (c) Saturation: Surface saturates: Run-Off phase. (d) Rain Stops: Moisture descends and joins water-table by gravity. Depth Water Table (a) (b) (c) (d) () August 12, 2017 7 / 29
Porosity and Soil Moisture Key Quantites Soil Moisture: Fraction of soil-volume filled with water. Porosity of a soil: Maximum possible value of soil moisture. Take a fixed volume V sample of soil. Use a standard gouge, scoop, screw or core. Let W s be its weight. Let W d be the weight of the sample after oven-drying. Let W w be the weight of the sample after immersing it in water till it gets saturated. Let ρ be the density of water. Porosity p = W w W d ρv Moisture n = W s W d ρv () August 12, 2017 8 / 29
Porosity and Specific Yield Porosity: The volume fraction of void to solid in dried sample. Saturation: When these voids are fully filled with water. Specific Yield S y : the ration of the colume of water that drains from a rock owing to gravity, to the total rock volumne. h1 h2 Q h 1, h 2 resp., are the heights of the saturated layer. Q is the volume of the water discharged to reach h 2 from h 1. Q S y = (h 1 h 2 )A Caution: rock above h i is wet, but unsaturated. Lab. setup: Takes a lot of time for water to drip. () August 12, 2017 9 / 29
Specific Yield Importance: This is actually the fraction which is accessible. Note 1: In accessible voids are NOT counted in porosity. Note 2: To access full n-fraction, oven heating was required. Clearly S y n, the porosity and S r = n S y S r is called the Specific Retentivity. S r is largely due to the adhesion of water molecules to the rock layer. Specific Yield of a well : to be done later. Some Specific Yields Clay 2 Sandy Clay 7 Silt 18 Fine Sand 21 Medium Sand 26 Fine Gravel 25 () August 12, 2017 10 / 29
How much GW in a region? Farm Road Silt Basalt Rock Clay Forest regional features impact water balance surface features affect infiltration. underground features affect the accumulation and movement Soil parameters: Porosity, specific yield n, S y : the maximum available volume fraction Conductivity K: The ability of the soil to allow the movement of water. Aquifer An aquifer is an underground soil-strata which allows storage and movement of water. K > 0.1cm/s and S y > 0.1 Roughly coarse silts and sands. () August 12, 2017 11 / 29
Larger Picture In general, we would like to analyse groundwater and surface water prescribe corrective measures understand sustainable use Farm Road Silt Basalt Rock Clay Forest A real-life scenario Various surface features such as farmslands, forests, built-up areas, which affect infiltration. Similar soils appearing as layers, and their geological properties. climactic data such as rainfall, evaporation, etc. Water requirements and usage, such as for irrigation, domestic use. () August 12, 2017 12 / 29
DATE : 11 / 05 / 2009 DRN. BY : Ulhas APPROVED BY: Bore-logs R.L IN METER 100.00 99.00 0.00 99.20 98.00 97.00 96.00 95.00 0.00 95.085 0.00 1.40 94.91 V O V V O V 94.00 1.20 93.885 CR V O V RQD V O V ( %) ( %) V O V V O V 93.00 V O V 20.00 16.66 V O V 4.00 V O V 92.00 57.50 37.50 3.35 91.735 44.00 Nil 91.00 84.00 84.00 90.00 95.33 95.33 89.00 88.00 7.20 87.885 92.94 92.94 9.00 87.00 91.42 91.42 10.05 86.00 98.00 98.00 85.00 10.10 84.985 96.31 92.31 87.31 86.26 CR ( %) RQD ( %) 100.00 98.66 92.50 92.50 95.48 95.48 97.41 97.41 98.09 98.09 0.00 97.65 1.50 96.15 4.70 92.95 5.00 V O V 92.65 V O V V O V 5.80 V O V 91.85 9.00 10.20 88.65 87.45 CR ( %) 96.87 89.09 76.00 14.61 99.33 100.00 RQD ( %) 91.25 66.36 76.00 14.61 99.33 100.00 100.00 100.00 2.00 3.20 97.20 7.00 92.20 7.70 91.50 10.00 89.20 CR ( %) 61.66 96.00 79.00 87.77 85.71 84.00 93.12 94.28 RQD ( %) 30.00 79.00 87.77 85.71 84.00 93.12 94.28 LEGEND - Soil & Boulder (Overburdan) - Jointed Basalt Rock (MW) - Basalt Rock (SW) - Amygdoloidal Basalt Rock (SW) 84.00 83.00 V X X V X X V O X V O X - HTAB - Very Highly weathered Rock (Murrum) 82.00 81.00 Surface Profile 80.00 BH. NO BH -1 Depth 10.10 m BH- 2 10.05 m BH -3 10.20 m BH- 4 10.00 m SOHAMS FOUNDATION ENGINEERING PVT. LTD. SFE 301,THAPAR COMPLEX SEC-15, CBD-BELAPUR, NAVI-MUMBAI Tel. 27565562 / 27560882 Email:sohamsfoundation@vsnl.net RL. M. Chainage 95.085 m 15.00 m 96.31 m 35.00 m 97.65 m 55.00m 99.20 m 75.00 m Project :- Soil Investigation at Gudvanwadi Check Dam. Subject :- Surface Profile () August 12, 2017 13 / 29
Measuring Groundwater stocks Groundwater Survey and Development Agency (GSDA), Over 5000 observation wells. Dug-wells observed quarterly, Bore-wells monthly. () August 12, 2017 14 / 29
Close-up-Nasik What is available Levels in various times of the year, nearby rainfall, depth of well. Specific yield? Depth of aquifer? () August 12, 2017 15 / 29
Water-table at a well (Rahul Gokhale) () August 12, 2017 16 / 29
Water-table at a well (Rahul Gokhale) The model WT (p, t, r): The water-table at the point p on date t (i.e., days after September 1, in year with annual rainfall r. WT (p, t, r) = a p + b p t + c p r ± σ p The numbers (a p, b p, c p, σ p ) computed for all observation wells. () August 12, 2017 17 / 29
A calculation well Depth of well September 15 May 31st 18m-bgl 8m-bgl 14m-bgl level on Sept 1 level on May31 Aquifer Bottom S y = 2%. This implies that 1m of water-table=20mm of water. September stock = (18 8) 0.02 = 200mm. May stock = (18 14) 0.02 = 80mm. Comsumption =120mm. Total GW stock = Area 200mm. () August 12, 2017 18 / 29
India s Aquifers blue green beige high-porosity porosity due to fractures little/no porosity Indian aquifers: The Gangetic Plain: porous, shallow aquifer. The Deccan Trap: moderately deep and fractured. The Kutch: Silt/Clay shallow. Mostly unconfined () August 12, 2017 19 / 29
Groundwater and Recharge source: UNESCO and whymap.org (BGR) () August 12, 2017 20 / 29
Movement of GW Let p 1 and p 2 be points on the water table. Thus h(p 1 ) > h(p 2 ) and groundwater flows from p 1 to p 2. A well from which water is drawn causes a dip in the water table, called the draw-down cone. This cone causes the well to recharge. The strength of the recharge is given by the angle of attack. If the water-table falls below the well-bottom the well runs dry. well p1 p2 water flow water table () August 12, 2017 21 / 29
Two wells Wt1 Wt2 Wt3 W1 W2 Two wells W 1 and W 2. Well W 2 is a drinking water well and W 1 is an irrigation bore-well. As W 1 extracts q 1 = 0, q 2, q 3, where q 1 < q 2 << q 3, the water-table gets lower as wt 1 to wt 2 to wt 3. At extraction q 3, the drinking water well goes dry. () August 12, 2017 22 / 29
A pond in summer and after rains Wt1 0000000000000000000000000000 1111111111111111111111111111 00000000000000000000000 11111111111111111111111 0000000000000000000 1111111111111111111 0000000000000 1111111111111 A pond losing to groundwater Wt2 00000000000000000000000000000 11111111111111111111111111111 0000000000000000000000000000 1111111111111111111111111111 00000000000000000000000 11111111111111111111111 0000000000000000000 1111111111111111111 0000000000000 1111111111111 A pond gaining groundwater () August 12, 2017 23 / 29
Groundwater and Rains WT 0000000000000000000000 0000000000000000000000 0000000000000000000000 1111111111111111111111 1111111111111111111111 1111111111111111111111 Rain 0000000000000000000000 1111111111111111111111 Infil. WT 0000000000000000000000 1111111111111111111111 0000000000000000000000 1111111111111111111111 0000000000000000000000 1111111111111111111111 Rain 0000000000000000000000 1111111111111111111111 WT GW GW An example terrain. Water Table following the topography. Rains cause infiltration. Since in the depression, the thickness is small, WT rises faster here. A significant Groundwater flows away from the depression. Still more rains causes the water-table to touch the surface and this creates a pond. Eventually scenario (i) returns. () August 12, 2017 24 / 29
Soil-Moisture Soil Moisture. The water-content in the top 1m of the surface. In farms with good soils, could be upto 20-30% by volume. Largely a stabilizing buffer for kharif agriculture. Black cotton soils: Enough water for most of the rabi crop. Complex interaction with Rainfall on one side, ET and GW on the other. water kharif soil moisture rabbi irrigation rainfall year () August 12, 2017 25 / 29
Soil-moisture Equations ET R I Farm 000000000 111111111 000000000 111111111 000000000 111111111 00000000 11111111 Soil Top Soil Moisture Soil Bottom Parameters. L: Soil Thickness θ: Soil Moisture Fraction. Various Rates (mm/day) Rch Revap R Rain Infiltration I Irrigation Water Table ET Evapo-transpiration Revap Reverse Evap. θ: The determinining variable. Rch Recharge L dθ = R + I + Revap ET Rch dt () August 12, 2017 26 / 29
Bad soil Thin soil (< 50cm), drains quickly, large particle-size. Inability to hold on moisture and offer it to crops. Frequent irrigation required. Dry spells may cause crop loss. Where is irrigation water to come from? Wells, farm-ponds, lift-irrigation. water kharif soil moisture irrigation rabbi irrigation rainfall DRY SPELL protective irrigation year () August 12, 2017 27 / 29
How to Analyse Supply Side Soil type and soil thickness. GSDA maps, test-pits. Existence of wells, streams, seasonality-access to water. Inspection and Interview. Demand Side Crop-sowing for Kharif and Rabbi. Annual crops. Yields (kg/hectare) and price obtained (Rs./kg). Indicative of water-stress. Allocation Number of irrigations required. Coping with dry spells. Interview Farm-ponds, irrigation pumps and systems, wells, access to nearby bandharas. The Household. House-hold assets. Indicative of recent history, ability to invest. Education levels, salaried people, number of farm-workers. Farm inputs. Access to market. Knowledge. () August 12, 2017 28 / 29
Thanks () August 12, 2017 29 / 29