Preliminary Design of Water Balance Covers: A Method from the ACAP Data Set William H. Albright, PhD Desert Research Institute Reno, Nevada 89512 USA www.acap.dri.edu.

Slides:

Advertisements

Similar presentations

John Walton Fall, Grows over shallow water table areas High amount of evapotranspiration Water balance component Q out of reach = Q into.

Advertisements

Alternative Earthen Final Covers: A Regulatory Perspective Bill Albright Desert Research Institute University of Nevada for State of California Integrated.

Near Surface Disposal Facilities

Watershed Hydrology, a Hawaiian Prospective: Evapotranspiration Ali Fares, PhD Evaluation of Natural Resource Management, NREM 600 UHM-CTAHR-NREM.

Timber harvest effect on soil moisture in the southern Sierra Nevada: Is there a measurable impact? Matthew W Meadows 1, Roger Bales 1, Martha Conklin.

Hydrologic storage in seasonal, mineral flat wetlands across native prairie, farmed, and restored prairie land cover: structural controls and hydrologic.

Introduction The agricultural practice of field tillage has dramatic effects on surface hydrologic properties, significantly altering the processes of.

Designing Water Balance Covers (ET Covers) for Landfills and Waste Containment by Craig H. Benson, PhD, PE, DGE, NAE Geological Engineering University.

Bruno Basso Dept. Crop, Forest and Environmental Sciences University of Basilicata, Italy Contacts Joe T Ritchie: Bruno Basso :

Runoff Estimation, and Surface Erosion and Control Ali Fares, PhD NREM 600, Evaluation of Natural Resources Management.

Water Balance Jae K. (Jim) Park, Professor Dept. of Civil and Environmental Engineering University of Wisconsin-Madison.

Recharge on Non-irrigated Land Mike McVay 06/24/2010.

Long-range Forecasting of Climate and Water Resources in the Pacific Northwest, October 2001, Kelso, WA Tracking an Uncertain Climate for Water Supply.

Hydrologic Abstractions

Arne Grønlund and Daniel P. Rasse Norwegian Institute for Agricultural and Environmental Research Division for Soil and Environment Carbon loss from cultivated.

By Saleh A. Al-Hassoun Associate Professor Department of Civil Engineering College of Engineering King Saud University Riyadh, Saudi Arabia

School of Civil and Environmental Engineering Life Impact The University of Adelaide Water Balance and the Influence of Soil Structural Changes on Final.

Mid-Range Streamflow Forecasts for Water Supply Management in the Puget Sound Region Matthew Wiley Richard Palmer October 26, 2005.

School of Geography FACULTY OF ENVIRONMENT School of Geography FACULTY OF ENVIRONMENT GEOG5060 GIS and Environment Dr Steve Carver

FLUVIAL PROCESSES J. David Rogers. Part 1 THE WATER CYCLE and WATER BALANCE.

Groundwater Hydraulics Daene C. McKinney

Making sure we can handle the extremes! Carolyn Olson, Ph.D. 90 th Annual Outlook Forum February 20-21, 2014.

Applying Methods for Assessing the Costs and Benefits of CCA 2 nd Regional Training Agenda, 30 September – 4 October 2013 Priyanka Dissanayake- Regional.

Lecture 11 Evapotranspiration (4)

Arid Zone Hydrology.

RANGELAND HYDROLOGY BASIC CONCEPTS Lamar Smith Cascabel Ranch and Consulting Carta Valley, Texas.

EVAPOTRANSPIRATION.

Field water balance of final landfill covers: The USEPA’s Alternative Cover Assessment Program (ACAP) William H. Albright Desert Research Institute, University.

Jože PEZDIČ Department of Geology, NTF, University of Ljubljana, Aškerčeva 12, SI-1000 Ljubljana, Slovenia Key words: Slovenian Karst, karst hydrogeology,

Streamflow Predictability Tom Hopson. Conduct Idealized Predictability Experiments Document relative importance of uncertainties in basin initial conditions.

Soil water storage and mobility: Theoretical and Experimental Aspects Dr. Greg Butters Soil Physics Department of Soil and Crop Sciences A lecture for.

CE 424 HYDROLOGY 1 Instructor: Dr. Saleh A. AlHassoun.

Surface Water Hydrology: Infiltration – Green and Ampt Method

SM-CRSP Workshop 2007 ACN Water Conservation Assessment Water Balance Estimation Using Soil Moisture Data

Engineering Hydrology (ECIV 4323)

Evapotranspiration Partitioning in Land Surface Models By: Ben Livneh.

Introduction Conservation of water is essential to successful dryland farming in the Palouse region. The Palouse is under the combined stresses of scarcity.

Source waters and flow paths in an alpine catchment, Colorado, Front Range, United States Fengjing Liu, Mark W. Williams, and Nel Caine 2004.

Tyler, Michael, Diana, Shea. The General Water Cycle.

The Drainage Basin System

Estimating Recharge on Groundwater Resources Projects The Influence of Soils & Crops Tim Hess Institute of Water & Environment Cranfield University Environment.

Soil Water Processes:Chapter 3 Learn how soil properties influence runoff, infiltration and plant growth. Learn how soil properties influence runoff, infiltration.

Drainage Basin. Mississippi River Basin Drainage Basin.

Fire Effects on Water. The Watershed Concept What is a watershed? Area of land that drains into a common outlet Watershed condition- health or status.

Estimating Groundwater Recharge in Porous Media Aquifers in Texas Bridget Scanlon Kelley Keese Robert Reedy Bureau of Economic Geology Jackson School of.

DES 606 : Watershed Modeling with HEC-HMS

Parameterisation by combination of different levels of process-based model physical complexity John Pomeroy 1, Olga Semenova 2,3, Lyudmila Lebedeva 2,4.

Hydro-Thermo Dynamic Model: HTDM-1.0

CE 3354 Engineering Hydrology Lecture 11: Watershed Loss Processes.

Water Every Drop Counts!. Earth’s Water Supply 2 Groups of Fresh Water 1.) Surface (above ground) 2.) Ground (below the ground surface)

Kristina Schneider Kristi Shaw

From RegentsEarth.com win.

The Water Cycle

Module 4: Loss Models Theodore G. Cleveland, Ph.D., P.E, M. ASCE, F. EWRI AUG 2015 Module 4 1.

DES 606 : Watershed Modeling with HEC-HMS

Lecture 11 Evapotranspiration (4)

Kristina Schneider Kristi Shaw

Basic Hydrology & Hydraulics: DES 601

Engineering Hydrology

Learning objectives To understand the water balance

Water Balance Alternative Final Covers

Aim: How is Earth’s supply of water being continuously recycled?

Quiz 7 Answers 1. Soil A has a Ksat value of 8 cm/h, Soil B has a Ksat value of cm/h, and Soil C is shallow and rocky and has a Ksat value of.

Watershed Hydrology NREM 691 Week 3 Ali Fares, Ph.D.

Fire Effects on Water September 27, 2006.

Slides excerpted from the Ecosystem Services module

Hydrology CIVL341.

Engineering Hydrology (ECIV 4323)

Hydrology CIVL341 Introduction

Engineering Hydrology (ECIV 4323)

Presentation transcript:

Preliminary Design of Water Balance Covers: A Method from the ACAP Data Set William H. Albright, PhD Desert Research Institute Reno, Nevada USA Craig H. Benson, PhD, PE, DGE University of Wisconsin-Madison Madison, Wisconsin USA

Precipitation “Sponge” Infiltration Percolation if S > S c Evapotranspiration Water Balance Covers: Sponge Concept S = soil water storage S c =soil water storage capacity

ACAP Site Locations

ACAP: The Field Program Nationwide: 12 sites, 8 states Large (10 × 20 m) drainage lysimeters Conventional technology –Composite –Clay barrier Alternative technology –Water balance –Capillary barrier

Water Balance Covers Evaluated by ACAP

Full-scale equipment and methods

Undisturbed sample to capture as-built soil properties

Water content probe to monitor soil water status

Data Summary Site MaximumAverage Precip. (mm) Perc. (mm) Year Precip. (mm) Perc. (mm) Albany, GA Altamont, CA Apple Valley, CA Boardman, OR ( Thin) Boardman, OR ( Thick)0.0 Cedar Rapids, IA Helena, MT Marina, CA Monticello, UT Omaha, NE (Thin) Omaha, NE (Thick) Polson, MT Sacramento, CA (Thin) Sacramento, CA (Thick) Underwood, ND

ACAP: The Products Nation-wide field-scale data set for composite, compacted clay and water balance covers Measured changes to soil hydraulic properties due to pedogenesis Published results – 25 workshops A new method for feasibility assessment and preliminary design

Natural water storage capacity of finer textured soils Soil water storage typically seasonal Water removal by evaporation and transpiration Percolation occurs when soil water storage exceed total storage capacity Key: Need to know required storage, S r. We always knew how to store water, we did not know how to determine ‘how much’ The ACAP data set from a nation-wide network of field-scale test sections provides a method to determine S r The method is based on data, not estimates from models How Do Water Balance Covers Work?

Water Balance Covers: How They Function

We Answered 2 Questions: When & How Much 1. Determine when water accumulates. 2. Define how much water accumulates. Example: for fall- winter months at sites without snow, water accumulates in the cover when the monthly precipitation (P m ) exceeds 21 mm, on average.

Climate Type SeasonThreshold No Snow & Frozen Ground Fall-WinterP/PET > 0.34 Spring- Summer P/PET > 0.97 Snow & Frozen Ground Fall-WinterP/PET > 0.51 Spring- Summer P/PET > 0.32 Thresholds for Water Accumulation Examined P, P/PET, and P-PET as indicators of water accumulation and found P/PET threshold works best. Data segregated into two climate types (with & without snow and frozen ground) and two periods in each year (fall-winter and spring- summer). Fall-winter = September - February Spring-summer = March - August Water accumulates when P/PET threshold exceeded.

How Much Water Accumulates? 1. Use water balance approach: Δ S = P – R – ET – L – P r Δ S = change in soil water storage R = runoff P = precipitation ET = evapotranspiration L = lateral internal drainage (assume = 0) P r = percolation 2. ET is unknown, but is a fraction ( β ) of PET: ET = β PET 3. R, L, and P r can be lumped into losses ( Λ ) Simplify to obtain: Δ S = P – β PET – Λ 4. Equation used to compute monthly accumulation of soil water storage if P, PET, β, and Λ are known.

Parameters for Water Accumulation Equation Climate Type Season β (-) Λ (mm) No Snow & Frozen Ground Fall-Winter Spring- Summer Snow & Frozen Ground Fall-Winter Spring- Summer Δ S = P – β PET – Λ Two sets of β and Λ parameters (fall-winter & spring- summer) for a given climate type. 0

Monthly Computation of Required Storage (S r ) P m =monthly precipitation PET m =monthly PET β FW =ET/PET in fall- winter β SS =ET/PET in spring- summer Λ FW =runoff & other losses in fall-winter Λ SS =runoff & other losses in spring- summer Include only months that exceed P/PET threshold If Δ S m < 0, set Δ S m = 0 Fall-Winter Months Spring-Summer Months

Example: Idaho Site (snow & frozen ground) For months below threshold, set Δ S = 0 Δ S = P – 0.37*PET (Fall-Winter) β = 0.37, Λ = 0 Store 97 mm for typical year, 230 mm for wettest year

Example: Texas Site (no snow & frozen ground) For months below threshold, set Δ S = 0 Δ S = (P – 0.37*PET)-27 (Fall-Winter) β = 0.3, Λ = 27 Store 188 mm for 95 th percentile year, 548 mm for wettest year

Predicted and Measured S r Good agreement between computed and measured required storage.

Conclusion: A Two-Step Method for Design of Water Balance Covers 1.Preliminary design: estimate required thickness using ACAP approach based on a robust, nation-wide field data set 2.Refine the design with numerical simulations to evaluate: Important design parameters “what if?” assessments 3.Read the book