Difference between revisions of "Keck Foundation LOI"

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== 1) Opening ==
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Computational methods are now an important part of basic research in all of the natural sciences, yet few undergraduate programs have such components. Earlham is very well positioned to develop a template for incorporating computational methods into science curricula, e.g. our interdisciplinary approach and the high percentage of our graduates that go on to earn Ph.D.s in a science.  These methods are just one type of scientific inquiry covered by our curriculum modules.  /* Is this paragraph placed correctly? */
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== 2) Description ==
+
\begin{document}
Course curriculum module development
 
*Describe one introductory and one upper-level fully, list the others that will be like this
 
  
Summer workshops
+
\centerline{\large \bf Multidisciplinary Science Curriculum Modules and Student/Faculty Research}
*Describe all of them with some detail
+
 +
\section*{Introduction}
  
Physical aspects
+
Earlham College requests \$342,400 to develop multidisciplinary science curriculum modules and student/faculty research projects focusing on a common core problem: metals in the environment.  This project will emphasize collaboration among our natural science departments, including biology, chemistry, computer science, geosciences, mathematics, and environmental science. Scientific research is becoming increasingly multidisciplinary and collaborative; therefore, it is essential to train our students to develop multi-faceted approaches to problem solving. This project will introduce an important scientific problem, ask students to collect and analyze data, and to make interpretations using different disciplinary perspectives in both coursework and independent research projects with faculty.  We believe this idea of collaborative multidisciplinary learning will transform our undergraduate curriculum in the sciences and provide a model for programs among the sciences at other liberal arts colleges.
*Back campus study plot
 
*Springwood Lake
 
*Laboratory experiments with ground water simulators
 
  
This project will focus on interdisciplinary collaboration and curriculum development among the natural and physical sciences departments at Earlham College, including biology, chemistry, computer science, geosciences, mathematics, and physics. It is clear that cutting-edge scientific research is becoming more interdisciplinary and collaborative at all levels; therefore, it is essential to train our students to develop multi-faceted approaches to problem solving. This project will introduce an important scientific problem and ask students to collect and analyze data, as well as make interpretations, using different disciplinary perspectives in both coursework and independent research projects with faculty. We believe this idea of collaborative learning will transform our undergraduate curriculum in the sciences and provide a model for interdisciplinary curricula for other liberal arts colleges.
+
A grant from the Keck Foundation would support a modest amount of equipment, curriculum module and seminar development, and student/faculty summer research, over three years.  Curriculum modules will be created for both introductory and upper-division science courses.  Field, laboratory, and computational methods will be integrated in the modules for students at all levels to experience first-hand how modern scientific inquiry is carried out using a multidisciplinary approach. Our study of metals in the environment will generate module and research topics reflecting faculty expertise, student interest, and local impact. Following the scientific and pedagogical success of this initial topic, we intend to expand it to reflect the changing interests of students, faculty, and the community. We will study anthropogenic impacts on two local ecosystems: nearby Springwood Lake with documented pollution impacts from industrial activity and a site on campus.
  
In choosing the scientific problem around which to construct this project, we have tried to generate topics centered around faculty expertise, student interest, and local impact. We anticipate that if this approach is successful, both scientifically and educationally, we would be able to expand topics to reflect the changing interests of students, faculty, and the community. Therefore, our selection of the research problem is purposefully flexible, although any topic must meet the following explicit criteria:
+
Earlham College is a four-year, private, coeducational institution providing a liberal arts education for 1200 undergraduates.  In 2000, Earlham ranked eighth among 1302 institutions of higher learning in the Biological Sciences category of the Baccalaureate Origins Report.  One quarter of Earlham students major in science.  Earlham's teaching philosophy strongly emphasizes collaborative student/faculty research, both within courses and extracurricularly.  Earlham students regularly present papers at the annual Butler University Undergraduate Research Conference and at the annual Merck/Earlham College Undergraduate Research  Conference, and at national conferences in a wide range of science disciplines. Students are frequently co-authors on papers submitted to refereed scientific journals.
*It must be broadly relevant to the scientific community (research results should be publishable in more than one venue).
 
*It must be easily adapted to both student/faculty research and the undergraduate science curriculum.
 
*It must involve field work, laboratory work, and computational analysis.
 
*It must be interdisciplinary in nature.
 
*It must have local impact or be important to the local community.
 
 
We will focus on the following metals:
 
*Mercury
 
*Lead
 
*Uranium
 
*Arsenic
 
*Selenium
 
*Vanadium
 
*Molybdenum
 
 
Water flow through soil both experimentally and computationally.
 
  
The courses will we incorporate these modules into include:
+
Four aspects of our project work together to make it powerful: 1) our focus on local problems; 2) the combined use of field, laboratory, and computational methods;  3) the longitudinal involvement of students as they take introductory through upper-level science classes; and 4) showing students how modern science is multidisciplinary with teams of scientists who inform and illuminate the different disciplinary perspectives of a problem. 
*Introductory Classes
 
**EcoBio - 100 per year
 
**Environmental Science and Sustainability - 40 per year
 
**Programming and Problem Solving - 30
 
**Introduction to Computational Science - 10
 
**Statistics - 40
 
**Principles of Chemistry - 90
 
  
*Upper-level Classes
+
\section*{Description}
**Equilibrium and Analysis
 
**Hydrogeology
 
**Geochemistry
 
**Modeling
 
**Environmental Chemistry
 
**Instrumental Analysis
 
  
(Include a total number of students per year, over the life of the grant, and as a percentage of the total number of students at Earlham.)
+
Curriculum modules relevant to this proposal will be incorporated into 6 introductory courses in 5 departments in the Sciences.  Almost every one of Earlham's 1200 students will take at least one of these classes before they graduate.  Additionally, curriculum modules will be incorporated into at least 7 upper-level courses in 4 departments in the Sciences.
  
The environmental impact of local industry and geology on ground water sources would be studied using such methods computational modeling, analytical techniques, and effects/evidence of metal uptake by plants or aquatic life. Again we could employ Clear Creek as our study site. Snapping turtles are potential heavy metal reservoirs, as such they would provide us with one particularly good angle with which to approach this which builds on significant faculty expertise.
+
{\bf Introductory Course Modules} - To illustrate how traditional topics can be introduced in an innovative way using this environmental project as a unifying theme, we propose to incorporate a new environmental chemistry component into our general chemistry class (typical annual enrollment of 90). This unit will introduce students to fate and transport modeling of metals by measuring the distribution coefficient, Kd, which is a common parameter used to estimate the concentration of metal pollutants in aqueous systems. Students will learn the significance of Kd, a measure of the soil sorption capacity, by determining this parameter in standardized material and applying the procedure to soils collected from our study sites.
  
Course Modules
+
The module will be conducted over two laboratory periods. The first week will consist of a spectroscopy lab, where the students will be introduced to absorption spectroscopy for the determination of the metal concentration in water, and to infrared spectroscopy for the characterization of soil components.  In the second week, students will use atomic spectroscopy to determine Kd of one or more metals.  The effect of pH on Kd will also be investigated for the soils.  The results will be used to discuss such environmental issues as acid rain and metal mobilization.  The soil Kd results will be compiled in a database for use in fate and transport modeling.
*Test plot to examine ground flow and uptake
 
*Year round
 
*Longitudinal
 
*Off-site plot maintenence
 
  
Summer multidisciplinary research community
+
{\bf Upper Division Course Modules} - Hydrogeology serves to illustrate an application of our project to an upper-level course.  The lab modules for hydrogeology will target complete hydrogeologic characterization of both the on-campus research site and Springwood Lake. For the on-campus site, we will install ground water monitoring wells and multi-level piezometers. Subsurface hydraulic properties will be determined via constant-head slug tests and constant-discharge pump tests.  Quantitative analyses (using Earlham's Inductively Coupled Plasma spectrometer) will establish baseline metals concentrations.  Students will track the environmental fate of target metals added to the control site under regulated conditions. 
*Continue maintence/development of local plot
 
*Off-site plot research
 
  
== 3) Purposes, Aims, and Impact ==
+
The proposed modules for hydrogeology will give students an experience that embodies much of the professional practice of the science.  Students will conduct all facets of the subsurface investigation, aquifer property determination, and sample collection. Students in other courses will cooperatively engage with hydrogeology students to develop the protocols for performing the environmental fate experiments, chemical analyses and equilibrium speciation modeling.
See how modern, collaborative, science is done
 
  
Outreach to local community, science in the context of real life
+
{\bf Summer Research} - Overall, we propose that the summer research component of this project will involve at least 6 faculty each year, about 18 projects total, and at least 36 students over three summers.
  
Research projects and curriculum modules for a variety of introductory and upper-level classes.
+
Chemistry: collection, sample preparation and analysis of metals in a variety of environmental matrices, and the development and implementation of metal speciation protocols; investigation of the redox chemistry of soil; characterization and model synthesis of the metal-ligand complexes present in these soils/leachates.
  
For science and non-science majors, a better understanding of both computational and experimental research methods, model development and verification, and interdisciplinary science research. For example, students in both majors and non-majors versions of general chemistry should come away with some understanding of how computational methods, chemistry, biology, and geology, work together to deepen our understanding of the problem.
+
Biology: sampling of aquatic biota (macrophytes and animals) in Springwood Lake to describe and quantify the food chains; evaluate the extent of bioaccumulation of metals by those organisms; assess the rates of biomagnification occurring in higher trophic levels.
  
Introduce students to scientific problems which incorporate local and regional issues and resources.
+
Geosciences: characterization of the physical properties of subsurface soils by conducting whole-soil hydraulic conductivity tests and laboratory grain-size analyses; determine reactivities of soil minerals by quantifying mineral constituents, cation-exchange capacities, organic matter content and surface functional groups.  
  
== 4) Timetable ==
+
Computer Science: design, development, deployment, and management of the field monitoring equipment using photovoltaic panels, batteries, imbedded controllers, wireless data transfer interfaces, environmental sensors, and open source tools; modeling of the biochemical and groundwater processes.
4 years, full summer of activity in 2007
 
  
Include a statement that shows that Earlham will carry this on supported by funds that are described in the current capital campaign menu.
+
\section*{Purposes, Aims, And Impact}
  
== 5) Justification for why Keck and not some other funding source ==
+
This project will bridge the gap between modern scientific research and science education by incorporating research modules into courses and further developing multidisciplinary summer research activity.  In addition to using multidisciplinary approaches in courses and research, we will institute a series of seminars for small groups of students who are enrolled in one of the courses with a research project module. In these small groups, students will discuss and present the work their class is pursuing on the topic, and engage in weekly readings and assignments meant to broaden their understanding of the nature of modern, multidisciplinary science.
It is difficult to obtain funding from government agencies, e.g. the NSF, for cross disciplinary work such as we describe here. This puts Keck in a somewhat unique position as a sponsor for this project.
 
  
Multidisciplinary curriculum development is hard to find public funding for.
+
An important artifact of this project will be further development of Earlham's Environmental Studies program, which is largely staffed by the same faculty that would be a part of this work.
 
Modest size.  NSF and similar agencies look to fund much larger, more narrowly focused projects than the one we envision.
 
  
== Appendix A - Budget ==
+
Because this project will impact the local community, we will hold an annual poster session on-campus for the public in which faculty and students will present their resultsWe believe this innovative approach of combining classroom scientific inquiry, summer research projects, multidisciplinary discussion, and community participation will give our students a unique opportunity to engage in truly modern collaborative science.
Equipment:
 
*Ultrasonic Nebulizer (Boorman?  Leave it here for now)$15K
 
*Large freeze drier $20K
 
*Acid digestion system $20K
 
*Field monitoring equipment (one per location) ~$1.5K per, about 6
 
**Temperature
 
**PH (digital)
 
**Conductivity
 
**Redox (reduction oxidation potential)
 
**Computer, packaging, uploading
 
**Nitrate selective probe through the summer?
 
*Sampling equipment (what depth do we need?) $1K + lots
 
**Lake sediment cores to 2m
 
**Shelby soil cores to some unknow depth
 
**One time install for monitoring wells and equipment for drawing
 
**Sounds like different approaches for different locations. Springwood has wells that we could sample (possibly)
 
  
Software and hardware $5K
+
\section*{Timeline}
*Groundwater flow analysis, Do we need cycles? Talk to Mic about this
 
  
Workshops
+
\begin{tabular*}{6.5in}{l@{\extracolsep{\fill}}l}
*Faculty stipends - 10 per workshop (year) over 4 years
+
Spring 2007 & Purchase and installation of equipment \\
*Meals and supplies
+
Summer 2007 & Course module and seminar development, student/faculty research \\
*Intructor stipends
+
Academic 2007-08 & Initial implementation of course modules and seminars \\
*Topics (possible, refine before submission)
+
Summer 2008 & Course module and seminar development, student/faculty research \\
**Computational Science Methods - general and domain specific
+
Academic 2008-09 & Continued implementation of course modules and seminars \\
**Environmental Geology
+
Summer 2009 & Course module and seminar development, student/faculty research \\
**Hydrology
+
Academic 2009-10 & Continued implementation of course modules and seminars \\
**Soil Chemistry
+
\end{tabular*}
**Analytical Techniques
 
**Biochemistry and metabolism of metals
 
**Computational Chemistry
 
*PDF would pay for faculty stipends, Keck would pay for instructor costs and general stuff.
 
  
Supplies
+
\section*{Justification For Keck Request}
*Per faculty, per course, per student researcher
 
  
Faculty and student stipends for summer prep of curriculum modules
+
The costs involved in the proposed multidisciplinary project exceed the capacity of Earlham's operating budget.  In order to plan and implement this project, we must secure outside funding.  Private and government funding for multidisciplinary projects at 4-year colleges is limited.  Furthermore, many focus on one core discipline with collaborative disciplines radiating from the  core.
  
Faculty Release Time during the academic year for first offering
+
\newpage
  
Faculty and student Stipends for summer research projects based on this
+
\section*{Budget}
  
== Appendix B - Reviewers ==
+
\begin{verbatim}
We'll need complete addresses, telephone, and fax
+
                                  2007      2008      2009      Total
<pre>
+
PERSONNEL             
Lew Reilly
+
  Faculty Stipends           
Ursinus College
+
    Summer research (@$600/wk) $28,800    $28,800    $28,800    $86,400
Department of Physics
+
    Project Coordinator        $3,000    $3,000    $3,000    $9,000
Collegeville, PA
+
  Student Stipends               
+
    Summer research (@$400/wk) $38,400    $38,400    $38,400  $115,200
Scott Brooks - BioGeoChemist
 
Environmental Sciences Division, POB 2008
 
Oak Ridge National Laboratory
 
Oak Ridge, TN  37831
 
  
Mic's friend
+
TOTAL PERSONNEL                                                $210,600
Oak Ridge National Laboratory
+
               
Oak Ridge, TN
+
EQUIPMENT             
 +
  Ultrasonic Nebulizer        $15,000           
 +
  Large freeze drier          $25,000           
 +
  Acid digestion system        $25,000           
 +
 
 +
  Field Monitoring (4@$3000 each):             
 +
    Temperature, pH (digital), conductivity, redox (reduction oxidation
 +
    potential), pressure transducer, nitrate selective probe, computer,
 +
    packaging, and communications 
 +
  Total Field Monitoring      $12,000           
  
Bob Panoff
+
  Field Sampling:                     
Shodor Institute
+
    Lake sediment cores to 2 m             
Raleigh, NC
+
    Shelby soil cores             
 +
    Monitoring wells (one time install)
 +
    Drawing equipment             
 +
  Total Field Sampling        $15,000
 +
 
 +
  Biology sampling gear        $3,800
  
Brock Spencer
+
TOTAL EQUIPMENT                                                  $95,800
Beloit College
+
               
Department of Chemistry
+
SUPPLIES               
Beloit, WI 53511
+
  Per student (12) per year    $1,000    $1,000    $1,000  
 +
TOTAL SUPPLIES                $12,000  $12,000    $12,000      $36,000
 +
               
 +
GRAND TOTAL                                                    $342,400
 +
\end{verbatim}
  
Biologist?
+
In 2010, Earlham will be in the final stages of a capital campaign which includes support for an on-going summer student/faculty science research program.  This endowment would continue support for the projects described in this proposal.
  
Bruce Herbert, Professor
+
\end{document}
Department of Geology and Geophysics
 
Texas A & M University
 
MS 3115
 
College Station, Texas 77845
 
herbert@geo.tamu.edu
 
979-845-2405
 
</pre>
 
 
 
== Appendix C - College Collateral ==
 
Fact sheet
 
 
 
Background on each department, orange flyers?
 
 
 
Division Brag Sheets - EllieV's revisions?  SaraP?
 

Latest revision as of 06:31, 31 January 2006

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\usepackage{pslatex} %\usepackage{times} %\usepackage{palatino} %\usepackage{palatcm} %\usepackage{helvet} %\usepackage{bookman}

\begin{document}

\centerline{\large \bf Multidisciplinary Science Curriculum Modules and Student/Faculty Research}

\section*{Introduction}

Earlham College requests \$342,400 to develop multidisciplinary science curriculum modules and student/faculty research projects focusing on a common core problem: metals in the environment. This project will emphasize collaboration among our natural science departments, including biology, chemistry, computer science, geosciences, mathematics, and environmental science. Scientific research is becoming increasingly multidisciplinary and collaborative; therefore, it is essential to train our students to develop multi-faceted approaches to problem solving. This project will introduce an important scientific problem, ask students to collect and analyze data, and to make interpretations using different disciplinary perspectives in both coursework and independent research projects with faculty. We believe this idea of collaborative multidisciplinary learning will transform our undergraduate curriculum in the sciences and provide a model for programs among the sciences at other liberal arts colleges.

A grant from the Keck Foundation would support a modest amount of equipment, curriculum module and seminar development, and student/faculty summer research, over three years. Curriculum modules will be created for both introductory and upper-division science courses. Field, laboratory, and computational methods will be integrated in the modules for students at all levels to experience first-hand how modern scientific inquiry is carried out using a multidisciplinary approach. Our study of metals in the environment will generate module and research topics reflecting faculty expertise, student interest, and local impact. Following the scientific and pedagogical success of this initial topic, we intend to expand it to reflect the changing interests of students, faculty, and the community. We will study anthropogenic impacts on two local ecosystems: nearby Springwood Lake with documented pollution impacts from industrial activity and a site on campus.

Earlham College is a four-year, private, coeducational institution providing a liberal arts education for 1200 undergraduates.  In 2000, Earlham ranked eighth among 1302 institutions of higher learning in the Biological Sciences category of the Baccalaureate Origins Report.  One quarter of Earlham students major in science.  Earlham's teaching philosophy strongly emphasizes collaborative student/faculty research, both within courses and extracurricularly.  Earlham students regularly present papers at the annual Butler University Undergraduate Research Conference and at the annual Merck/Earlham College Undergraduate Research  Conference, and at national conferences in a wide range of science disciplines. Students are frequently co-authors on papers submitted to refereed scientific journals.

Four aspects of our project work together to make it powerful: 1) our focus on local problems; 2) the combined use of field, laboratory, and computational methods; 3) the longitudinal involvement of students as they take introductory through upper-level science classes; and 4) showing students how modern science is multidisciplinary with teams of scientists who inform and illuminate the different disciplinary perspectives of a problem.

\section*{Description}

Curriculum modules relevant to this proposal will be incorporated into 6 introductory courses in 5 departments in the Sciences. Almost every one of Earlham's 1200 students will take at least one of these classes before they graduate. Additionally, curriculum modules will be incorporated into at least 7 upper-level courses in 4 departments in the Sciences.

{\bf Introductory Course Modules} - To illustrate how traditional topics can be introduced in an innovative way using this environmental project as a unifying theme, we propose to incorporate a new environmental chemistry component into our general chemistry class (typical annual enrollment of 90). This unit will introduce students to fate and transport modeling of metals by measuring the distribution coefficient, Kd, which is a common parameter used to estimate the concentration of metal pollutants in aqueous systems. Students will learn the significance of Kd, a measure of the soil sorption capacity, by determining this parameter in standardized material and applying the procedure to soils collected from our study sites.

The module will be conducted over two laboratory periods. The first week will consist of a spectroscopy lab, where the students will be introduced to absorption spectroscopy for the determination of the metal concentration in water, and to infrared spectroscopy for the characterization of soil components. In the second week, students will use atomic spectroscopy to determine Kd of one or more metals. The effect of pH on Kd will also be investigated for the soils. The results will be used to discuss such environmental issues as acid rain and metal mobilization. The soil Kd results will be compiled in a database for use in fate and transport modeling.

{\bf Upper Division Course Modules} - Hydrogeology serves to illustrate an application of our project to an upper-level course. The lab modules for hydrogeology will target complete hydrogeologic characterization of both the on-campus research site and Springwood Lake. For the on-campus site, we will install ground water monitoring wells and multi-level piezometers. Subsurface hydraulic properties will be determined via constant-head slug tests and constant-discharge pump tests. Quantitative analyses (using Earlham's Inductively Coupled Plasma spectrometer) will establish baseline metals concentrations. Students will track the environmental fate of target metals added to the control site under regulated conditions.

The proposed modules for hydrogeology will give students an experience that embodies much of the professional practice of the science. Students will conduct all facets of the subsurface investigation, aquifer property determination, and sample collection. Students in other courses will cooperatively engage with hydrogeology students to develop the protocols for performing the environmental fate experiments, chemical analyses and equilibrium speciation modeling.

{\bf Summer Research} - Overall, we propose that the summer research component of this project will involve at least 6 faculty each year, about 18 projects total, and at least 36 students over three summers.

Chemistry: collection, sample preparation and analysis of metals in a variety of environmental matrices, and the development and implementation of metal speciation protocols; investigation of the redox chemistry of soil; characterization and model synthesis of the metal-ligand complexes present in these soils/leachates.

Biology: sampling of aquatic biota (macrophytes and animals) in Springwood Lake to describe and quantify the food chains; evaluate the extent of bioaccumulation of metals by those organisms; assess the rates of biomagnification occurring in higher trophic levels.

Geosciences: characterization of the physical properties of subsurface soils by conducting whole-soil hydraulic conductivity tests and laboratory grain-size analyses; determine reactivities of soil minerals by quantifying mineral constituents, cation-exchange capacities, organic matter content and surface functional groups.

Computer Science: design, development, deployment, and management of the field monitoring equipment using photovoltaic panels, batteries, imbedded controllers, wireless data transfer interfaces, environmental sensors, and open source tools; modeling of the biochemical and groundwater processes.

\section*{Purposes, Aims, And Impact}

This project will bridge the gap between modern scientific research and science education by incorporating research modules into courses and further developing multidisciplinary summer research activity. In addition to using multidisciplinary approaches in courses and research, we will institute a series of seminars for small groups of students who are enrolled in one of the courses with a research project module. In these small groups, students will discuss and present the work their class is pursuing on the topic, and engage in weekly readings and assignments meant to broaden their understanding of the nature of modern, multidisciplinary science.

An important artifact of this project will be further development of Earlham's Environmental Studies program, which is largely staffed by the same faculty that would be a part of this work.

Because this project will impact the local community, we will hold an annual poster session on-campus for the public in which faculty and students will present their results. We believe this innovative approach of combining classroom scientific inquiry, summer research projects, multidisciplinary discussion, and community participation will give our students a unique opportunity to engage in truly modern collaborative science.

\section*{Timeline}

\begin{tabular*}{6.5in}{l@{\extracolsep{\fill}}l} Spring 2007 & Purchase and installation of equipment \\ Summer 2007 & Course module and seminar development, student/faculty research \\ Academic 2007-08 & Initial implementation of course modules and seminars \\ Summer 2008 & Course module and seminar development, student/faculty research \\ Academic 2008-09 & Continued implementation of course modules and seminars \\ Summer 2009 & Course module and seminar development, student/faculty research \\ Academic 2009-10 & Continued implementation of course modules and seminars \\ \end{tabular*}

\section*{Justification For Keck Request}

The costs involved in the proposed multidisciplinary project exceed the capacity of Earlham's operating budget. In order to plan and implement this project, we must secure outside funding. Private and government funding for multidisciplinary projects at 4-year colleges is limited. Furthermore, many focus on one core discipline with collaborative disciplines radiating from the core.

\newpage

\section*{Budget}

\begin{verbatim}

                                 2007       2008       2009      Total

PERSONNEL

 Faculty Stipends             
   Summer research (@$600/wk) $28,800    $28,800    $28,800    $86,400 
   Project Coordinator         $3,000     $3,000     $3,000     $9,000 
 Student Stipends                
   Summer research (@$400/wk) $38,400    $38,400    $38,400   $115,200 

TOTAL PERSONNEL $210,600

EQUIPMENT

 Ultrasonic Nebulizer         $15,000            
 Large freeze drier           $25,000            
 Acid digestion system        $25,000            
 
 Field Monitoring (4@$3000 each):              
   Temperature, pH (digital), conductivity, redox (reduction oxidation 
   potential), pressure transducer, nitrate selective probe, computer, 
   packaging, and communications  
 Total Field Monitoring       $12,000            
 Field Sampling:                      
   Lake sediment cores to 2 m              
   Shelby soil cores               
   Monitoring wells (one time install)
   Drawing equipment              
 Total Field Sampling         $15,000
 
 Biology sampling gear         $3,800

TOTAL EQUIPMENT $95,800

SUPPLIES

 Per student (12) per year     $1,000    $1,000     $1,000  

TOTAL SUPPLIES $12,000 $12,000 $12,000 $36,000

GRAND TOTAL $342,400 \end{verbatim}

In 2010, Earlham will be in the final stages of a capital campaign which includes support for an on-going summer student/faculty science research program. This endowment would continue support for the projects described in this proposal.

\end{document}