ASTM User Training

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ASTM User Training

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Vol. Water content in foundation/wall cracks. Particulate emission rate ... Class Exercise # ?? Soil to Ground Water Leaching. MEK. chemical characteristics ... – PowerPoint PPT presentation

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Title: ASTM User Training

1
ASTM User Training

in
Risk-Based Corrective Action for Chemical
Releases
(Provisional ASTM Standard Guide)
Day 2

2
Agenda - Day 2

800 - 930 RBSL/SSTL Development
930 - 945 Break
945 - 1045 RBSL/ SSTL Development
1045 - 1100 Break
1100 -1200 RESC/SSEC Development/Data
Collection
1200 - 100 Lunch
100 - 230 Tier Decisions/Remedial Options
230 - 245 Break
245 - 400 Source Reduction/ Activity and Land
Use Controls
400 - 415 Break
415 - 500 Factors for Consideration in
Remedial Action Selection

3
RBSL Development
4
RBSL Development

Acceptable concentrations of chemical(s) of
concern developed for the Tier 1 evaluation
conservative/non-site-specific models and input
values
data collection biased to area of highest
concentration

5
RBSL Development Components of Risk Assessment
Health Risk
Toxicity
Dose
Exposure
Exposure Concentrations
Fate Transport
Source Concentrations
6
RBSL DevelopmentSite Conceptual Model

Develop a generic or site-specific site
conceptual model to identify the RBSL to be
determined
site conceptual model can be either program or
site-specific based
program based RBSL
generic exposure pathways
non-site specific/conservative parameters
individual site based RBSL
site-specific exposure pathways
non-site specific/conservative parameters

7
RBSL DevelopmentExposure Pathway Considerations

Receptors
residential adult or children, worker
Transport mechanisms
soil to ground water leaching
soil and ground water to indoor or outdoor air
Exposure routes
ingestion
inhalation
dermal contact

8
RBSL DevelopmentUncertainty

Define the uncertainties and the approach for
addressing
algorithm
simple partitioning?
heterogeneity of subsurface environment
conservative soil type?
biodegradation
ignore?

9
RBSL DevelopmentMethods and Parameters

Identify the methods that are to be used to
calculate the RBSL so that they are reproducible
simple algorithms
analytical models
Define the parameters that are required by the
algorithms or models used to calculate the RBSL
fate and transport
chemical and site characteristics
toxicity
exposure

10
Fate and Transport ParametersChemical
Characteristics

Molecular weight
Solubility
Vapor pressure
Henrys law constant
Soil-water partitioning coefficient
Octanol/water coefficient
Degradation rate
Air diffusivity
Water diffusivity

11
Fate and Transport ParametersSite Characteristics

Saturated Zone
Groundwater mixing zone thickness
Width of source area
Depth of source area

Vadose Zone
Lower depth of surficial soil
Thickness of capillary fringe
Thickness of vadose zone
Depth to groundwater
Depth to top of subsurface soil sources
Depth from bottom of subsurface sources to ground
water

12
Fate and Transport ParametersSite
Characteristics - Saturated Zone

Groundwater Darcy and seepage velocity
Fraction organic carbon
Ground water gradient
Saturated hydraulic conductivity
Soil porosity
Soil bulk density
Dispersivity
longitudinal, transverse, vertical

13
Fate and Transport ParametersSite
Characteristics - Vadose Zone

Fraction organic carbon
Infiltration rate
Volumetric air content in capillary fringe soils
Volumetric water content in capillary fringe
Volumetric air content
Volumetric water content
Soil porosity
Soil bulk density

14
Fate and Transport ParametersSite
Characteristics - Volatilization

Enclosed-space air exchange rate
Enclosed-space volume to infiltration area ratio
Enclosed-space foundation or wall thickness
Areal fraction of cracks in foundations/walls
Vol. Air content in foundation/wall cracks

Vol. Water content in foundation/wall cracks
Particulate emission rate
Wind speed above ground surface in ambient mixing
zone
Width of source area parallel to wind flow
Ambient air mixing zone height
Averaging time for vapor flux

15
Toxicity Parameters

Target risk
Hazard quotient
Chemical toxicity
slope factor (mg/kg-day)-1 or unit risk factor
(mg/m3)-1
ingestion
inhalation
reference dose (mg/kg-day) or reference
concentration (mg/m3)
ingestion
inhalation

16
Exposure Parameters

Averaging time
cancer
non-cancer
Body weight
Exposure duration
Exposure frequency
Exposure time for indoor air
Exposure time for outdoor air
Soil ingestion rate

Daily indoor inhalation rate
Daily outdoor inhalation rate
Daily water ingestion rate
Soil to skin adherence factor
Skin surface area for soil exposure

17
RBSL DevelopmentOther Relevant Measurable
Criteria

Concentrations of chemical(s) of concern, other
numeric values, physical condition or performance
criteria, other than the RBSL, RESC, SSTL,SSEC,
used to define corrective action goals
consistent with the technical policy decisions
regulatory standards
consensus criteria
aesthetic criteria
groundwater protection criteria

18
Ground Water Ingestion

Calculate (see Class Exercise ?)
Other relevant measurable criteria (ORMC)
e.g., drinking water maximum contaminant levels
(MCL)

Non-Cancer
Cancer
SF Cancer Slope Factor (mg/kg-day)-1 HQ
Hazard Quotient RfD Reference Dose
(mg/kg-day) IR Ingestion Rate (l/day) EF
Exposure Frequency (days/yr)
ED Exposure Duration (yr) BW Body Weight
(kg) AT Averaging Time (period over which
exposure is averaged) (days)
19
Leaching from Source Area to Ground Water

Tier 1 RBSL are based on conservative default
parameters
steady state
infinite source
no vapor loss
no biodegradation
no dispersion/diffusion
RBSLgw RBSLdw

RBSLs-gw
RBSLgw
20
Leaching from Source Area to Ground Water
Partition Factor
Attenuation Factor
Back Calculate To Soil Concentration
21
Leaching from Source Area to Ground Water -
Attenuation Factors
Attenuation (neglecting biodegradation) is
controlled by physical site parameters and the
infiltration rate.
22
Leaching from Source Area to Ground Water -
Partitioning Factors
Concentrations of chemicals of concern measured
in soil includes chemical mass that is
volatilized into soil gas, dissolved into pore
moisture, and sorbed onto the soil surface.
Controlled by Chemical and Soil Parameters
23
Class Exercise ??Soil to Ground Water Leaching

MEK
chemical characteristics
physical parameters
ground water RBSL
unsaturated zone parameters
algorithms
uncertainty

24
Direct Contact -Carcinogens
Ingestion of soil

Ingestion of soil
Inhalation of vapor and particulates
Dermal contact with soil

Dermal Contact
Inhalation of particulates
Inhalation of vapors
IRsoil ingestion rate of soil FI fraction
ingested IRair inhalation rate of
air RAFd Dermal relative absorption factor SA
Skin surface area (cm2/day) M Soil
to skin adherence factor (mg/cm3) VF
Volatilization factor
25
Direct ContactVolatilization Factors

Volatilization factor VFss for Surficial Soil
Ambient Air Vapors

Volatilization factor VFr for Surficial Soil
Ambient Air Particulates

Pe particulate emission rate (g/cm-s) W
width of source are parralell to the wind
(cm) Uair wund speed in ambient mixing zone
(cm/s) dair ambient air mixing zone (cm) rs
soil bulk density (g-soil/cm3-soil) d lower
depth of surficial zone
26
Direct ContactAlgorithms
Cancer RBSLs (ug/kg)
Non-Cancer RBSLs (ug/kg)
27
Class Exercise ??Direct Contact

Mercury
chemical characteristics
physical parameters
target risk/hazard quotient
exposure factors
unsaturated zone parameters
algorithm
uncertainty

28
Vapor Intrusion into Buildings

Evaluation in Tier 1 is very conservative
Often a significant pathway

Mixing in breathing zone
Diffusive transport to breathing zone
Impacted soil and/or ground water in equilibrium
with soil gas
29
Vapor Intrusion into BuildingsVolatilization
Factor
H Henrys law constant dair ambient air
mixing zone (cm) rs soil bulk density
(g-soil/cm3-soil) qas volumetric air content in
vadose zone (cm/cm) Kd soil-water sorption
coefficient (g/g) Ls depth to subsurface soil
source (cm) LB enclosed space
volume/infiltration area ratio (cm/cm) Lcrack
enclosed space foundation or wall thickness
(cm) ER enclosed space air exchange ratio
(L/s) h areal fraction of cracks in
foundation/walls (cm2/cm2) Deffs effective
diffusion coefficient in soil based on vapor
phase (cm2/s) Deffcrack effective diffusion
coefficient through cracks (cm2/s)
30
Vapor Intrusion Into Buildings Controlling
Parameters

Soil to Soil Vapor Partitioning
Kd f(foc, koc)
chemical Henrys Constant and Solubility
existence of a NAPL
Diffusive Transport
Deff f(qws, qwa)
layering in the vadose zone
Indoor Air Transport
building construction

31
Equilibrium Partitioning Example
100
Linear Partitioning Approximation
Benzene Concentration in Ground
Water Cw (mg-benzene/l-water)
Raoult's Law Limit
10
Expected concentration
1
100
10000
1000
Residual Gasoline Concentration in Soil
CT (mg-gasoline/kg-soil)
Cwmax xiSi xi mole fraction of benzene Si
solubility of benzene
32
Class Exercise ??Ground Water to Indoor Air

Tetrachlorethene
chemical characteristics
physical parameters
indoor air RBSL
saturated zone parameters
unsaturated zone parameters
heterogeneity of soils
biodegradation
algorithms
uncertainty

33
Class Exercise ??Cumulative Risk

Show the comparison of a few chemicals to the
their RBSLs
Show the ratios of the concentrations to the
RSBLs
Discuss apportioning the target risk among the
chemicals to address cumulative effects
Texas is an example (may be too complicated)
more than 10 chemicals that are carcinogens or 10
non-carcinogens with the same target organ, then
adjust the RBSL
10gt sum for all i (RBSLadj-i /RBSL)

34
SSTL Development
35
SSTL DevelopmentSite Specific Parameter Values

When should site-specific data be considered?
Which parameters should be considered for each
exposure pathway?
How should site specific data be collected and
analyzed (recommended methods)?
What is the reasonable range of values for each
site-specific parameter?

36
SSTL DevelopmentSite Specific Parameter Values

Statistical representation of source area
concentrations of chemical(s) of concern,
Default parameter values used to develop the RBSL
are not appropriate for site-specific conditions,
or
The RBSL is applied at a site-specific point of
demonstration to develop SSTL

37
SSTL DevelopmentSite Specific Parameter Values

Site specific parameters can have a large impact
on calculated SSTL as compared to RBSL
Sometimes more than an order of magnitude!

38
SSTL DevelopmentSite Specific Parameter Values

Examine importance of parameters by looking at
exposure pathways
source composition
NAPL composition, molecular weight, density,
total volume, component effective solubility
soil properties
total and effective porosity, moisture content,
organic carbon fraction, and soil permeability or
hydraulic conductivity
physical site conditions
depth from source to groundwater, thickness of
vadose zone, thickness of capillary fringe,
infiltration rate
ground water flow
site specific aquifer data, hydraulic
conductivity, hydraulic gradient
building design
Air exchange rate, building dimensions,
foundation construction

39
SSTL Development - ExampleEffective Solubility
Limit (Seff)

Estimated based on Raoults Law using published
references for the pure component solubility
limit (e.g., see Montgomery and Welkom, 1990)
data on the mole fraction of compounds in
gasoline can be found in published references
(e.g., see Johnson et al, 1990) or measured in a
sample of source zone soil.

40
SSTL DevelopmentHeterogeneous Soils

Will heterogeneous soil properties limit flux?
define the effective diffusion coefficient, Deff

Homogeneous layer
Heterogeneous soil layers
1
Deff
DTeff, L
2
3
41
SSTL DevelopmentHeterogeneous Soils

How does moisture content affect diffusion?

Total Porosity
H0.22 DH2O / Dair 0.0001
42
SSTL DevelopmentHeterogeneity Summary

Zones of low Deff will reduce flux and increase
SSTL
Can result in an order of magnitude change in
SSTL
Estimation methods for Deff
typical properties for soil types
site specific soil property analysis
in-situ measurement of Deff

43
SSTL DevelopmentBiodegradation

Aerobic Biodegradation
Oxygen acts as an electron acceptor.
Indigenous micro-organisms exist that are capable
of degrading many volatile organic compounds.
The most significant rates of degradation occur
aerobically
Field studies conducted to date indicate that the
factor that most significantly controls
biodegradation in subsurface environments is the
rate of oxygen transport.
Anaerobic Biodegradation
Oxygen acts as an electron acceptor. There are
other potential electron acceptors commonly found
in aquifer environments, including NO3-2, SO4-2,
Fe3.

44
SSTL DevelopmentBiodegradation

For mathematical simplicity, most volatile
organic chemical degradation reactions are
treated as being first-order reactions. In
other words

concentration of chemical
is proportional to
decay rate
dC
?
?
?
C
dt
45
SSTL DevelopmentBiodegradation - Decay

The concentration can be determined by
C(t) Co exp (-?t)
ln(C(t)/Co) -?t
? first order decay rate constant (t-1)
C(t) concentration at time t (mg/l)
Co initial concentration (mg/l)

For example, typical values for the rate constant
(?) for benzene fall in the range 0.1 - 1 per
day.
46
SSTL DevelopmentBiodegradation - Decay

The half-life of a chemical is defined as the
time it takes for the first-order reaction to
transform half of the initial mass of the
chemical. If C(t)/Co is replaced with 0.5, then
t0.5 (ln 2)/? or t0.5 0.693/?
t0.5 half-life of the chemical (days)

47
SSTL DevelopmentBiodegradation

Illustration of first-order decay

48
SSTL Development Natural Attenuation

Natural Attenuation refers to the reduction in
mass, mobility, or concentration of chemical(s)
of concern by intrinsic processes (e.g.,
advection, dispersion, diffusion, dilution,
sorption, degradation).
Dilution Attenuation Factor (DAF)

Data collection needs include flow direction
gradient hydraulic conductivity lithology
depth to ground water ground water
fluctuations extent of source historical
monitoring data
49
SSTL Development Using RBSL Algorithms

Default parameter values used to develop the RBSL
are not appropriate for site-specific conditions
RBSL algorithms and Tier 1 point(s) of exposure
are appropriate for the site

50
Class Exercise ?? Using RBSL Algorithms

Example problem
substituting site-specific values to calculate
SSTL
use ground water to indoor air
parameters
depth to ground water
soil moisture content
sensitivity

51
SSTL DevelopmentStatistical Representation

95 UCL of arithmetic mean
sufficient number and quality of samples to
derive normal, log-normal or other applicable
frequency distribution
Based on appropriate statistical methodology for
normal or log-normal distributions

52
Class Exercise ??Statistical Representation

Example problem
soil concentrations
use direct contact RBSL
compare highest value to average values
look at area weighted averages
look at histograms translate to frequency
distributions
calculate the probability of the concentration
being above the RBSL based on the distribution

53
SSTL Development Using Exposure Pathway
Evaluation
Receptor
Transport
Source
Conceptual Model
54
SSTL Development Using Exposure Pathway
Evaluation
3
SSTL Applied at Source Area
RBSL or ORMC Applied at Point of Exposure
Source Area
Csoil
Cgw
Cpoe
1
2
Back-calculating site-specific target levels at
source areas
55
SSTL Development Using Exposure Pathway
Evaluation

Allowable concentration at the point(s) of
exposure (CPOE) is based on
RBSL,
ORMC, or
SSTL calculated using target risk, toxicity
factors and site-specific exposure factors

56
SSTL Development Using Exposure Pathway
Evaluation

Allowable concentration in ground water at the
source area (Cgw) is
An attenuation factor (AF) of less than 1 is a
result of
diffusion
dispersion
adsorption
decay (chemical and biological)

57
SSTL Development Using Exposure Pathway
Evaluation

Allowable concentration in soil at the source
area (Csoil) is
A leaching factor (LF) of less than 1 is a result
of
diffusion
dispersion
adsorption
decay (chemical and biological)

58
Using Ground Water Transport Modeling to Develop
the AFConsiderations and Data Requirements

Source-specific data
size, shape strength
type of source
continuous, constant pulse, exponentially
decaying
Receptor-specific data
distance orientation relative to source
Chemical-specific data
persistence, mobility, solubility
concentration in source area

Media-specific data
aquifer characteristics
porosity, hydraulic conductivity
Model applicability
simplest model to represent transport
does it apply?

59
Conceptual Ground Water ModelSignificant
Transport Processes

Different processes to consider

Infiltration from Rainfall
COC in Soil
Aqueous Advection
Advection and Dispersion In Groundwater
60
Ground Water Transport ModelingDomenico Solution

Transport processes
dispersion in 3 dimensions
one-dimensional uniform advection
Model assumptions and applicability
one-dimensional flow and 3-dimensional dispersion
first-order decay rate based on dissolved and
adsorbed phases decaying at the same rate
medium is isotropic and homogeneous
source concentration is constant
areal source perpendicular to the direction of
flow

61
Ground Water Transport ModelingDomenico

Analytical solution for the steady-state
concentration along the centerline

62
Ground Water Transport ModelingDomenico

Analytical solution, steady-state
Attenuation factor relates the concentration at
the source to the centerline down gradient
concentration at the water table
Function of
advection and partitioning vKi/qR
decay
dispersion longitudinal, transverse and vertical
source area depth and width

63
Ground Water Transport Modeling
Steady-state centerline concentrations predicted
by the Domenico solution
k0.0/d
k0.1/d
k1.0/d
Source width 50 ft source thickness 5 ft GW
velocity 0.3 ft/d ?x 0.1 L ?y ?x/3 ?z
0.035 ?x
no decay
C(x)/C(source)
max decay
Distance from Source ft
64
Transport ModelingCaution

Given the inherent limitations (data, model
assumptions), models are used to estimate rates
of transport, expected trends in data. This
information is very useful in developing SSTL,
monitoring plans and remedial designs, and for
assessing the significance of various exposure
and transport pathways. Models should not be a
substitute for site-specific data. Model
results are only one of the elements used in
making RBCA decisions!!!

65
Transport ModelingSummary

Identify the processes to considered in the
modeling
Determine the assumptions made by the model
Identify the appropriate data requirements
balance the model complexity with the available
data
Verify the model predictions with empirical data

66
Class Exercise ?? Using Exposure Pathway
Evaluation

Move point of demonstration to calculate new
concentration of chemical(s) of concern in ground
water at the source area
Domenico
Calculate concentration in soil at the source
area
use soil to ground water leachate RBSL calculation

67
RESC/SSEC Development
68
Example 1 City Service Center

A service station in the downtown of a city has
experienced a release from an underground storage
tank.
Chemical(s) of concern associated with gasoline
have been identified in the underlying soils and
groundwater.
The city service station is not located near
relevant ecological receptors or habitats.

69
Example 1 City Service CenterInitial Site
Assessment

No ecological relevant receptors or habitats have
been identified
these conditions were documented
Ecological issues need not be considered
Initial site assessment is sufficient

70
Example 2 Rural Manufacturing Facility

A manufacturing site located in a rural area has
observed concentrations of TCE in its soils and
ground water
The site is located near a small river, which
provides habitat for aquatic biota but is not
used for drinking water
The groundwater flow is toward the river
It is likely that the groundwater discharges to
the river.

71
Example 2 Rural Manufacturing Facility -
Initial Site Assessment

Potentially complete pathways and exposure to
relevant ecological receptors and habitats exist.
Proceed to Tier 1 assessment

72
Example 2 Rural Manufacturing Facility - Tier 1

Probability of potentially complete pathways and
exposure to relevant ecological receptors and
habitats has increased, but is not conclusively
known.
Concentrations of TCE in ground water range from
70 1,200 ?g/l
Concentrations of TCE in the surface water are
above the generic screening levels
attributed directly to the presence of a hot
spot.

73
Example 2 Rural Manufacturing Facility - Tier 2

The concentrations of TCE in the surface water
that are above the generic screening levels were
attributed directly to the presence of a hot
spot
Exit Tier 2 and proceed to remedial action

74
Example 3 Printing Site

The Printer is located near a wetland and river
Drainage and runoff from the Printing Site are
believed to have contributed to elevated
concentrations of organic chemicals and metals in
a nearby swamp.

75
Example 3 Printing SiteInitial Site Assessment

Elevated concentrations of organic chemicals and
metals are known to exist in the swamp area
Proceed to Tier 1 based upon
potentially completed exposure pathways and
the presence of relevant ecological receptors and
habitats

76
Example 3 Printing SiteTier 1

Runoff could carry chemical(s) of concern from
the spill locations to the wetlands
Concentrations of several organic chemicals and
metals are above the surface water screening
levels
Proceed to Tier 2 to refine generic criteria to
more site specific values

77
Example 3 Printing SiteTier 2

Concentrations of several organic chemicals and
metals in soil and wetland sediment at the site
are above those in the region for several metals
The site also exceeds ecological toxicological
benchmarks.
Proceed to a site-specific Tier 3 evaluation

78
Data Collection
79
Data Collection

Follows line of evidences
background information
qualitative data
quantitative data
Purpose and use
Analytical methods
Quantity and quality necessary to make decisions
conservatism vs. uncertainty
technical policy decisions

80
Data CollectionTier 1

Objective is to demonstrate highest concentration
of chemical(s) of concern
for each exposure pathway identified
Drivers
site conceptual model
concentrations of chemical(s) of concern
Technical policy decisions
what quantity and quality of data is adequate to
demonstrate no further action
agreement on screening approach

81
Data CollectionTier 2 and Tier 3

Objective is to demonstrate that concentrations
of chemical(s) of concern at the point(s) of
exposure will not be above acceptable levels or
criteria
for each exposure pathway identified
Drivers
site conceptual model
concentrations of chemical(s) of concern
fate and transport
Technical policy decisions
what quantity and quality of data is adequate to
demonstrate no further action

82
Data Collection

Representative of the site conceptual model AND

Chemical(s) of concern in the source area
Distribution of chemical(s) of concern
Variability in environmental conditions
Environmental media
Transport pathways
83
Tier Decisions
84
Risk-Based Corrective Action (RBCA) Process

Encourages user-led initiatives
Encourages stakeholder involvement
Provides a framework for corrective action
Recognizes the diversity of sites
Encourages technical policy issues to be
addressed up front
Provides appendices for direction and examples

85
Tiered Decisions

Decisions about chemicals of concern and pathways
that are complete or potentially complete
Decisions are made based on the tier evaluation

86
Tiered Decisions

Complete or potentially complete pathways
site conditions are above corrective action goals
options interim remedial action, tier upgrade,
remedial action
site conditions are below corrective action goals
option no further action
Decisions are made as part of Tier 1, Tier 2 and
Tier 3 Evaluations

87
RBCA Process Flow Chart
88
Decision Alternatives

No further action
pathway meets corrective action goal for the tier
does not apply to chemicals or pathways for which
there are no corrective action goals
Interim action/risk reduction
address immediate issues
reduce migration or concentrations
eliminate pathways and re-evaluate

89
Decision Alternatives

Tier Upgrade
complete or potentially complete pathways
for pathways where no corrective action goals
were developed or identified
not available at Tier 3

90
Decision Alternatives

Final remedial action
develop remedial action performance criteria
based on
corrective action goals
site conditions
chemicals of concern
pathways
site use or redevelopment
evaluate alternatives to meet goals

91
Decision Alternatives

Choosing among the alternatives involves business
decisions
economic
site use or redevelopment
liability
stakeholder issues
All of the alternatives meet the same level of
protectiveness

92
Why 3 Tiers (Levels) in RBCA?
Tier 1
More Site-Specific
Tier 2
More Conservative
Tier 3
Target Risk
Every tier achieves the same level of public
health protection
2
93
Tier Upgrade

For chemicals and pathways where site conditions
are above corrective action goals
Compare with interim remedial action and final
remedial action
may be qualitative or quantitative
Not available at Tier 3

94
What are the Drivers?

Cost to implement each alternative
Time and schedule concerns
Stakeholder issues
regulatory compliance factors
acceptability to neighbors
political issues
Impacts of implementing each alternative
e.g., short term impact to ecological habitats
from active remedial action
Site use or redevelopment
transaction issues

95
Weighing the Alternatives
96
Weighing the Alternatives

Start with common sense screening
Is remedial action clearly the right choice given
the site circumstances or would further tier
evaluation be best?
e.g., time sensitive redevelopment design system
to meet current tiers corrective action goals
rather than spending more time to develop higher
tier corrective action goals
If no clear choice then go to a more detailed
analysis

97
Weighing the Alternatives

Develop a common scale for evaluating the drivers
common scale for assigning values to drivers for
each alternative
Where do each of the alternatives (i.e., tier
upgrade, interim action, remedial action) fit
based on each of the drivers?
Compare qualitatively or semi-quantitatively
Results of the comparison will be site specific
based on the relative importance of the drivers
at a particular facility

98
Example Qualitative Comparison

Redevelopment site - shopping mall construction
ready to begin now
Option 1 Tier 2 remedial action
extensive soil excavation, groundwater air
sparging system
Implement now
Option 2 Tier Upgrade
tier 3corrective action goals expected to result
in limited soil excavation and engineering
control system for groundwater
6 months for Tier Evaluation, then Implement

99
Example Qualitative Comparison Scale
100
Quantitative Analysis

Formal decision analysis
Develop decision trees including all of the
alternatives
Need to know
the common value of implementing each alternative
the consequences of success and failure
the probability of success and failure

101
Quantitative Analysis

Calculate the common value for each of the
alternatives based on each of the drivers
Compare the weighted average values (expected
values) and choose the alternative with the
highest expected value
Common values can be expressed as monetary
values, utilities, or another common scale

102
Example Comparison

For one site the comparison between tier upgrade
and remedial action looks like this

103
Example Comparison
0.7
104
Example Comparison
Expected Value probability of failurevalue of
failure probability of successvalue of
implementation
E(Tier Upgrade) (0.1)(-35)(0.9)(-25) -26
E(Remedial Action) (0.2)(-45)(0.8)(-20) -25
Choose Remedial Action
105
Remedial Options
106
Remedial Action

Purpose of Remedial Action
Definition
The RBCA Paradigm
Use of the site conceptual model
Developing a holistic perspective
Remedial action alternatives evaluation

107
Remedial Action

Activities conducted reduce or eliminate current
or potential future exposures to receptors or
relevant ecological receptors and habitats
These activities include
monitoring
implementing activity and use limitations
designing and operating clean-up equipment
other activities that are conducted to reduce
sources of exposures to meet corrective action
goals, or sever exposure pathways to meet
corrective action goals

108
The Evolution of the Remedial Action Philosophy

Pre RBCA
What is the most we can clean up?
Emphasis on mass reduction through technology
for risk reduction

Post RBCA
What is clean up is necessary to be protective of
human health and the environment?
emphasis on technology and activity and use
limitations for risk reduction

109
The RBCA Remedial Action Paradigm

Is there a complete or potentially complete
exposure pathway?
How can we break the complete or potentially
complete exposure pathway?
reduce the source area
eliminate the transport mechanism
remove the receptor

110
Drivers for Remedial Action

Concentrations of chemical(s) of concern are
above the appropriate corrective action goals at
the point of demonstration
which COC are above the goals?
RBSL, SSTL, RESC, SSEC
what pathways are of concern?
what media are affected?
A higher tier evaluation is not warranted?

111
Remedial Action Performance Criteria

Concentrations of chemical(s) of concern or ORMC
in environmental media that are protective of
human health and the environment for a given
activity land use
These goals may be based on
generic (e.g., RBSL, RESC) or site-specific
(e.g., SSTL, SSEC) corrective action goals
developed during the Tier Evaluation
regulatory standards (e.g, MCL)
other performance criteria (e.g., aesthetic
criteria)
Criteria for establishing these goals should be
acceptable to the regulatory agencies

112
The Holistic Approach to Selecting Remedial
Action Alternatives

Remedial action has to achieve an adequate level
of risk reduction for all COC phases for each
complete or potentially complete exposure pathway
Considerations necessary to achieve remedial
action goals
All exposure pathways
Chemical(s) of concern
Chemical properties (e.g., chemical, physical,
toxicological)
Subsurface characteristics
Distribution of chemical(s) of concern in the
environment
Chemical phases

113
The Holistic Approach to Selecting Remedial
Action Alternatives

Chemical properties and the characteristics of
the environmental media define the phase and the
distribution of chemical(s) of concern

114
The Holistic Approach to Selecting Remedial
Action Alternatives
115
The Holistic Approach to Selecting Remedial
Action Alternatives
116
Source Reduction
117
Source Reduction Technologies

NAPL recovery
Pump treat (dissolved phase)
Natural attenuation
High vacuum extraction
Excavation

Soil vapor extraction
Bioventing
Sparging
Enhanced bioremediation
Thermal technologies
Chemical
Oxidation

118
Source Reduction Considerations

Source Type
residual phase (soil sorbed)
free phase (NAPL)
vapor
dissolved
Mobility
volatility
solubility
availability
trapped residual phase
Environmental media

Chemical persistence
Location
surface soils
subsurface soils
unsaturated
saturated
NAPL on ground water surface
NAPL below ground water surface
sediments

119
Source Reduction Implications

Does mass reduction result in significant risk
reduction?
Not Always
with current technologies it may not be
practicable to reduce residual NAPL in the
saturated zone to a level that will result in
acceptable dissolved concentrations
recent studies predict that 80 - 90 of the
saturated zone residual NAPL must be removed to
affect the soluble plume

120
Source Reduction Implications

Risk reduction in low permeability soil estimated
to be negligible
Risk reduction in high permeability soil can be
good
Field residual saturation controls the source
reduction
Low volatility chemicals are recalcitrant
longer dissolution and attenuation times
lower mobility plus higher residual saturation
generally lower quantified risk
Chemical alteration better when feasible

121
Source Reduction Implications

Opinion
many chemical(s) of concern plumes do not pose a
risk
leaving long-lived chemical(s) of concern plumes
in place requires management mechanisms
new technologies are needed

122
Source Reduction ImplicationsTechnology
Limitations

Some methods limited in effectiveness
ability of method to access the affected area
Certain methods limited to amenable components
e.g., volatile for SVE
Phase-specific or component specific nature of
some methods
Prior success and experience for some methods
Potential negative or adverse impacts of a method
e.g., noise, dust

123
Source Reduction ImplicationsTechnology
Limitations

Economics
Time to complete
Heterogeneity of soils
Success hinges not on remedial action screening
calculations but on understanding the
hydro-geological characteristics and chemical
distribution and relationship to clean up
operation

124
Activity and Use Limitations in Remedial Action
125
Activity and Use Limitations

Legal or physical restrictions or limitations on
the use or access to a site or facility
to eliminate or minimize potential exposures to
COC
to prevent activities that could interfere with
the effectiveness of a remedial action
to ensure maintenance of a condition of no
significant risk to human health and the
environment
to prevent adverse impacts to individuals or
populations that may be exposed to chemicals of
concern
focus on controlling human activity rather than
containing or managing chemicals of concern

126
Activity and Use Limitations
127
Activity and Use Limitations
128
Activity and Use Limitations Types of Controls

Proprietary controls
State and local government controls
Statutory enforcement tools
Informational devices
Engineering and access controls

129
Activity and Use LimitationsProprietary Controls

Deed and Use Restrictions
limits or conditions on the use and conveyance of
land to
inform prospective owner or tenant of existing
condition
ensure long-tern compliance and integrity of
remedial action
must satisfy several legal requirements
written and recorded
reflect mutual intention that restrictions run
with the land
compliance enforcement by third parties (privity
of estate)
address impacts that touch and concern land
remedies for non-compliance includes seeking an
injunction or civil penalties (e.g., fines)

130
Activity and Use LimitationsProprietary Controls

Restrictive covenant
provisions in a deed limiting the use of the
property and prohibiting certain uses
in context of property law the term describes
contract between grantor and grantee for
grantee's use and occupancy of land
general purpose is to maintain or enhance value
of lands adjacent to one another by controlling
nature and use of surrounding lands
not a permanent part of the property record or
property title for flexibility to re-convey the
property

131
Activity and Use LimitationsProprietary Controls

Easements
a right of use over the property of another
traditionally limited uses
rights of way and rights concerning flowing
waters
normally for the benefit of adjoining lands, no
matter who the owner is rather than for the
benefit of a specific individual
may allow access to the property or prohibit a
use of the property
grant state authorities or others an easement for
operation and maintenance of engineering controls
or for general inspection/audit functions

132
Activity and Use LimitationsState and Local
Government Controls

Restrictive zoning
imposed by municipal or local government
authorities
prohibit residential uses in a formerly
industrial area
can not limit uses or activities at individual
sites
Local jurisdiction review of activity and land
use controls before issuing building permits
Water and well use advisories
alert the public to potential risks from ground
water
recorded in the land record
presented in the form of public notice of
remedial action as part of the federal or state
program

133
Activity and Use LimitationsState and Local
Government Controls

Well restrictions that prohibit or condition the
construction of ground water wells in an area
permitting
prohibit construction of a private well without
permit
limited water quality testing and well
inspections prior to use
overlay zoning
zones drawn on zoning map to provide protection
not explicitly stated under existing zoning
regulations
aquifers and quality designation through
classification system
local and county ordinances
restrict the use of ground water in cases where
the existing water supply on a property is a
potential threat to health

134
Activity and Use LimitationsStatutory
Enforcement Tools

Regulatory agency may have enforcement
authorities that can be used to impose activity
and use limitations
administrative orders or a court order whenever
there is an imminent and substantial endangerment
to public health, welfare or the environment
only binding on responsible party not subsequent
owners
a facility operating permit (e.g., under RCRA) or
corrective action permit may be a vehicle for
imposing activity and use limitations
binds only the permittee for life of permit

135
Activity and Use LimitationsInformation Devices

Notices
tool to ensure that parties to a real estate
transaction are aware of the environmental status
of the property prior to finalizing a
transaction.
may be informational only
may be an integral enforceable part of activity
use controls
usually requires disclosure of the specific
environmental condition of a site and any
restrictions on use, access and development of
part or all of the property
record notice
actual notice to the other party to a real estate
transaction
notice to the appropriate government authority

136
Activity and Use LimitationsInformation Devices

Registry requirements
a list maintained by a regulatory or other
government agency of all properties that have
been the site of hazardous waste disposal and
that have restrictions on use or transfer
Transfer requirements
specific regulatory program that require full
evaluation of the environmental condition of a
site before or after a transfer occurs
typically creates information disclosure
obligations on the seller or lessor of property

137
Activity and Use LimitationsEngineering Controls

Technology based, physical modifications to a
site or facility to reduce or eliminate potential
for exposure to a chemical(s) of concern
Hydraulic containment
physical barrier
slurry walls
fences
capping
point of use water treatment
positive pressure (prevent vapor intrusion)

138
Activity and Use LimitationsEngineering Controls

Considerations
location
residential or mixed use neighborhood
surroundings
near sensitive land use areas, such as day care
centers, playgrounds, schools
usage
frequently used or traversed by area residents or
local workers
maintenance and monitoring
duration of the potential exposure

139
Activity and Use LimitationsBarriers to Use

Real estate preference and misunderstanding
concern for property cost devaluation
stigma
controls that prevent or control use should not
contribute to significant property devaluation
reliability of the controls
Inadequate regulatory authority or programs
enforcement to ensure controls remain in place
Legacy of past problems
liability and financial responsibility

140
Factors for Consideration in Remedial Action
Selection
141
Key Questions for Remedial Action

Is the situation stable?
is there limited or no migration potential of
chemical(s) of concern?
Is there a need to implement remedial action
immediately to address a significant potential
exposure?
Will active source reduction reduce overall risk
(all phases considered) to an acceptable level?
if active remedial action is not likely to reduce
overall risk in a reasonable time, should this
still be considered?

142
Key Questions for Remedial Action

Is containment an appropriate alternative?
will containment protect receptors?
will source reduction reduce the containment
lifetime?
is the source reduction technology likely to be
successful and cost-effective versus containment?
Are activity and use limitations appropriate with
or without remedial action?
Are there potential redevelopment or future land
use issues that need to be considered?

143
Key Questions for Remedial Action

What remedial action alternative or combination
of alternatives can achieve the corrective action
goals for the complete or potentially complete
exposure pathways at the point(s) of
demonstration?
source reduction
engineering controls
activity and use limitations for contributing
chemical phases

144
Factors for Consideration in Remedial Action
Selection

Effectiveness
Reliability
Short-term risk
Integration with property use
acceptability
Implementability
Ecological
Cost effectiveness

145
Remedial Action SelectionEffectiveness

Ability of remedial action alternative to achieve
the corrective action goals
In some cases it may be technically impracticable
to achieve the appropriate remedial action goals
activity and use limitations should be considered
Regional factors may also influence overall
effectiveness
background concentrations of COC
location of other potential sources

146
Remedial Action SelectionReliability

The potential of the remedial action to achieve
and maintain the corrective action goals
New technologies are continually being developed
may not have an established performance history
both their short-term and long-term reliability
are subject to question

147
Remedial Action SelectionShort-Term Risk

Short-term risk posed by the implementation of
the remedial action to
the affected community
those engaged in the remedial action effort
relevant ecological receptors and habitats
example excavation may involve
aesthetic impacts to the local community
heath and safety risks to excavation contractors
increased potential for a transportation accident
damage or destruction of ecological receptors or
habitats
future risk and liabilities at disposal site

148
Remedial Action SelectionIntegration with
Property Use

Consideration of potential redevelopment and
current use of the property in selection, design
and implementation of remedial action alternative
Redevelopment of the site
short term objectives
long term objectives
delayed or accelerated implementation
location of equipment

149
Remedial Action SelectionAcceptability

Consideration of the acceptability of the
remedial action to the affected community and
other potential stakeholders
it is important to keep stakeholders involved in
the process to provide awareness of the issues
and prevent potential conflicts at the end of the
project
buyer or lender requirements in a property sale
regulatory compliance and acceptability of the
selected remedial action alternative
available regulatory oversight or voluntary
action program
insurer or management requirements related to
future liabilities

150
Remedial Action SelectionImplementability

Consideration of the technical and physical
issues that will affect the implementation of the
remedial action considering site constraints
geological factors
soil heterogeneity and discontinuities
surface factors
location constraints due to existing physical
structures
political or regulatory constraints
ability to obtain permits
logistics of scale-up of new technology

151
Remedial Action SelectionEcological

Remedy selection always involves tradeoffs
Need to balance the consequences of actions taken
Can occur when considering human health and the
environment
Example
implementation of remedial action to protect
human health will destroy ecological health in
the areas where remedial action will occur
What options can be selected to protect human
health while leaving the environment intact?

152
Remedial Action SelectionCost Effectiveness