Jump to main content
Ecosystems Research, Athens GA
Migration of volatile chemicals from the subsurface into overlying buildings is called vapor intrusion (VI). Volatile organic chemicals in contaminated soils or groundwater can emit vapors, which may migrate through subsurface soils and may enter the indoor air of overlying buildings. Building depressurization may cause these vapors to enter the home through cracks in the foundation. Depressurization can be caused by a combination of wind effects and stack effects, which are the result of heating within the building and/or mechanical ventilation. In extreme cases, the vapors may accumulate in dwellings to levels that may pose near-term safety hazards, such as explosion. Typically, however, vapor concentrations are present at low levels, to which long-term exposure may pose increased risk for chronic health effects.
This on-line calculator implements the Johnson and Ettinger (J&E) (Johnson and Ettinger, 1991) simplified model to evaluate the vapor intrusion pathway into buildings. This J&E model replicates the implementation that the US EPA Office of Solid Waste and Emergency Response (OSWER) used in developing its draft vapor intrusion guidance, but includes a number of enhancements that are facilitated by web implementation: temperature dependence of Henry's Law Constants, automatic sensitivity analysis of certain parameters, and others described below.
The J&E model has become increasingly popular with regulators and consultants over the last 10 years and several manuscripts have been published on its use (see citation list on the following page). Briefly, the model is a one-dimensional analytical solution, which incorporates both advection and diffusion transport mechanisms to produce a unit-less "attenuation factor". This attenuation factor is a measure of how soil and building properties limit the intrusion of organic vapors into overlying buildings and is defined as the concentration of the compound in indoor air divided by the concentration of the compound in soil gas or groundwater. Chemical concentrations in groundwater will attenuate more than chemicals in soil gas due to the added limitations imposed by mass-transfer across the capillary fringe.The larger the attenuation factor produced by the model, the greater the intrusion of vapors into indoor air.
The J&E model was based on a number of simplifying assumptions (e.g., homogeneity, diffusion-only through subsurface, uncontaminated capillary fringe, etc.). The reader is directed to Environmental Quality Management (2003) or U.S. Environmental Protection Agency (2002) for a discussion of these limitations. Conditions under which the J&E model should not be used include:
Use of the on-line vapor intrusion model is intended to be intuitive and simple. The user begins by entering an optional site name or description. Next, sample information is entered including concentration, units and whether the sample is from soil gas or ground water. Depth to the soil gas sample (or water table for ground water samples) including estimated bounds on this depth are then entered. Contaminant of concern, building type, and soil type beneath the building are selected. Finally, the average soil or groundwater temperature is entered. Default soil, building and exposure parameters that populate the input sheet based on user selections were obtained from U.S. Environmental Protection Agency (2002) and the user is directed to this document for a discussion of their justification. Contaminants of concern are selected from a list of 108 chemicals that may be found at contaminated sites. Their default values are obtained from Environmental Quality Management (2003). Users may accept the default parameter values or overwrite them with site-specific information, if available.
Upon clicking the "Calculate Results" button the on-line calculator performs two calculations and presents their results. First, the Johnson and Ettinger model is run to produce an attenuation factor for the contaminant-soil-building system. If a user has soil gas samples, then a soil-gas to indoor air attenuation factor is computed. If ground water sample data is chosen, then a ground water to indoor air attenuation factor is computed.
Second, the on-line model calculates an indoor-air concentration based on the user-input sample concentration and the model-computed attenuation factor. Cancer Risk levels and Hazard Quotients are presented for the computed indoor air concentrations.
Secondary screening target concentrations require at least a rudimentary knowledge of subsurface conditions such as depth of contamination and soil type. A simple sensitivity analysis is produced with the output results, providing upper and lower bounds on the computed indoor air concentrations based on these two parameters. Depth to the sample may contain uncertainty due to estimation error or to seasonal variability in water table depth. A user-defined bound on sample depth is included to accommodate this potential uncertainty. Additionally, a range of default water-filled-porosities in the unsaturated zone based on soil type is included in the input section. This moisture content range is taken from values presented in U.S. Environmental Protection Agency (2002).
This on-line implementation of the Johnson and Ettinger model utilizes the power of web-based modeling to incorporate the following features:
Environmental Quality Management, 2003.
for U.S. Environmental Protection Agency - Office of Emergency and Remedial Response, Washington, D.C.
User's Guide for Evaluating Subsurface Vapor Intrusion into Buildings.
Hers, I., Zapf-Gilje, R., Johnson, P.C. and Li, L., 2003.
Evaluation of the Johnson and Ettinger Model for Prediction of Indoor Air Quality.
Ground Water Monitoring and Remediation, 23(2): 119-133.
Johnson, P.C., 2002.
Identification of Critical Parameters for the Johnson and Ettinger (1991) Vapor Intrusion Model.
American Petroleum Institute Technical Bulletin Number 17: 38.
Johnson, P.C. and Ettinger, R.A., 1991.
Heuristic Model for Predicting the Intrusion Rate of Contaminant Vapors into Buildings.
Environmental Science and Technology, 25(8): 1445-1452.
Johnson, P.C., Kemblowski, M.W. and Johnson, R.L., 1999.
Assessing the Significance of Subsurface Contaminant Vapor Migration to Enclosed Spaces:
Site-Specific Alternatives to Generic Estimates. Journal of Soil Contamination, 8(3): 389-421.
U.S. Environmental Protection Agency, 2002.
USEPA Office of Solid Waste and Emergency Response, Washington, D.C.
Draft Guidance for Evaluating the Vapor Intrusion to Indoor Air Pathway from Groundwater and Soils.
Contact Jim Weaver to ask a technical question on this material.
The Seal of the United States Environmental Protection Agency
Jump to main content.