Difference between revisions of "Keck-presentation"

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(Courses (Mike 5 min))
(II) Why Earlham (Charlie 15 min))
 
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**re-read grant RFP
 
**re-read grant RFP
 
**re-read grant proposal
 
**re-read grant proposal
**paul's one pager on the history of student/faculty research at earlham
 
**timed run-through
 
**plan tour (35 minutes)
 
 
*How much time spent with small liberal arts colleges?  Answer dictates level of coverage in different parts of what follows.
 
 
*Tension between Quaker modesty and our desire to put the best facia on our college and our people.
 
  
 
*Overview of Earlham  
 
*Overview of Earlham  
 
**1847, Quakers were a large portion of the early settlers to this area
 
**1847, Quakers were a large portion of the early settlers to this area
**Liberal arts with masters in teaching and seminaries
+
**Liberal arts with masters in teaching and two seminaries, Bethany and Earlham School of Religion
 
**Quaker
 
**Quaker
 
***Governance
 
***Governance
 
***Student/faculty interactions
 
***Student/faculty interactions
**Teaching first and formost (but we do other things too, see Science Division)
+
**Teaching first and foremost (but we do other things too, see Science Division)
  
 
*Student Body
 
*Student Body
**International
+
**Diversity (science students in particular)
**Diversity (science in particular)
 
 
***Efforts to improve enrollments in STEM disciplines
 
***Efforts to improve enrollments in STEM disciplines
**Selectivity
+
***Over 24% of our students are eligible for PELL grants
 +
**International - over 60 countries represented
 
**Curriculum
 
**Curriculum
***Liberal arts, distribution requirements (new language)
+
***Liberal arts, general education requirements (analytical reasoning and scientific inquiry) ensure that science is a part of every students academic plan
***Science a part of everyone's course of study
+
***Off-campus study, over 60% of students, many science based programs
****Actual details of the requirements
+
***More than 25% of our students major in a STEM discipline
****More below on our majors
 
  
 
*Science Division  
 
*Science Division  
 
**Faculty cohesiveness and collective strength
 
**Faculty cohesiveness and collective strength
***Multidisciplinary experience
+
***Generational shift in the science faculty over the past 8 years or so
***Intel Science Fair judges
+
***Growth in the science faculty over the past 10 years or so (2 FTE in CS, 1 FTE in Chemistry, 1 FTE in Geosciences)
***Teaching awards, e.g. John's
+
***Multidisciplinary experience, e.g. bio-chemistry, environmental programs, computational science
 +
***Teaching awards, e.g. John's and Mic's (exact titles)
 +
***Intel International Science Fair judges
 
**Science major to PhD strength
 
**Science major to PhD strength
***Numbers for particular departments
+
***Geosciences 13th, Biology 8th (nationally), 90-100% acceptance rate to medical, dental, and veterinary school
***Overlap w/ major/minors
+
***Double major and major/minors with overlap in the sciences
 
**Multidisciplinary applied science groups  
 
**Multidisciplinary applied science groups  
***Hardware interfacing project
+
***Hardware Interfacing Project
***Cluster computing group
+
***Cluster Computing Group
 
***Green Science  
 
***Green Science  
 
**Student/faculty research experience (history, current)
 
**Student/faculty research experience (history, current)
***Publications and presentations
+
***Early 1960's; biology, geology, chemistry; soil science with radioactive tracers, bat species population.
 +
***Foundation on which over 40 years of experience has been built, funded mostly through external grants (e.g. NSF and HHMI)
 +
***$3M Endowed fund to support the core of summer student/faculty research part of the capital campaign, operating fund support for the near-term
 +
***Publications in peer reviewed journals and presentations at national and international meetings
 
**Computational Experience
 
**Computational Experience
 
***Folding@Home
 
***Folding@Home
***Computational Economics
 
 
***Phylogenetic reconstruction of turtle DNA using Bayesian analysis  
 
***Phylogenetic reconstruction of turtle DNA using Bayesian analysis  
 
***LittleFe and SC Education
 
***LittleFe and SC Education
**Instrumentation and experience with it
+
**Instrumentation and experience with it (for a metals project)
***SEM, Nuclear Magnetic Resonance Spectrometer, Inductively Coupled Plasma Atomic Emissions Spectrometer (measures the concentration of up to 35 metals simultaneously), laser, clusters, weather station, ...  Which are most important for this project?
+
***Inductively coupled plasma atomic emissions spectrometer (measures the concentration of up to 35 metals simultaneously)
**Pedagogical creativity experience
+
***Atomic absorption spectrometer
 +
***Clusters
 +
***Scanning electron microscope
 +
***Benchtop Xray difractometer
 +
***Weather station
 +
**$2.5M in science renovations and equipment in 2000, new science facilities design done last year, reuse and new space, explicit support for multidisciplinary work, part of the current capital campaign (currently in the quiet phase)
 +
**Pedagogical creativity
 +
***Short course to support MCM Modeling Contest
 +
***Computational science in context
  
 
*Closing
 
*Closing
 +
**The foundation of our faculty, our facilities (current and planned), and our students position Earlham well to undertake the broad science curriculum changes outlined in our proposal.
  
 
= III) Why Project (Ron 15 min) =
 
= III) Why Project (Ron 15 min) =
Line 100: Line 105:
 
- mention connections to intro classes - give a couple of examples (i.e. student taking environmental chem/tox will already have taken gen chem and eq/al)
 
- mention connections to intro classes - give a couple of examples (i.e. student taking environmental chem/tox will already have taken gen chem and eq/al)
  
== Intro: Gen Chem (Mike 10 min) ==  
+
== Intro: Gen Chem (Mike 10 min) ==
 +
 
 +
there are three slides for this part.
 +
 
 +
Slide one -
 +
 
 +
    Principles of Chemistry (CHEM 111) - typical enrollment of 90 
 +
 
 +
                Environmental module goals:
 +
 
 +
                    introduce basic spectroscopy concepts
 +
 
 +
                    illustrate an application of equilibrium constants
 +
 
 +
                    emphasize multidisciplinary connections
 +
 
 +
                    introduce students to spreadsheet modeling
 +
 
 +
Slide two - this slide includes picture of Corinne and Kalani with ICP
 +
    Week 1 – Spectroscopy
 +
 
 +
                    atomic spectroscopy – ICP-AES and GFAAS
 +
 
 +
                    molecular spectroscopy – diode array
 +
 +
                    energy levels and light
 +
 
 +
                    color vs absorption
 +
 
 +
 
 +
Slide three -
 +
    Week 2 – measurement of Kd and Modeling
 +
 
 +
                kd – measure of soils ability to bind metal (illustration to the
 +
                    right)
 +
 
 +
                Measure for different soils - mention both well characterized as
 +
                                              well as from our local sites
 +
 
 +
                Test parameter variability - includes sample graph from J chem
 +
                                            ed article on kd vs pH
 +
 
 +
                Model using a spreadsheet
 +
 
 
== Upper: Geology (Ron 10 min) ==
 
== Upper: Geology (Ron 10 min) ==
 +
 +
Hydrogeology – Study of ground water flow.
 +
*Physical dynamics.
 +
**Ground water recharge, flow and discharge.
 +
**Transient flow dynamics.
 +
*Chemical dynamics.
 +
**Equilibrium Speciation Modeling.
 +
***PHREEQCi
 +
***MINTEQA2
 +
***Geochemists Workbench 4.01
 +
**Contaminant transport modeling.
 +
***Visual MODFLOW
 +
 +
Geochemistry - Metal speciation controls cycling behavior. 
 +
*Aqueous.
 +
**Equilibrium Speciation Modeling.
 +
***PHREEQCi
 +
***MINTEQA2
 +
***Geochemists Workbench 4.01
 +
*Mineralogy - Reactive mineral phase determination.
 +
**Disaggregation.
 +
***Carbonate.
 +
***Organic matter.
 +
***Cements.
 +
**Dispersal of charged particulates.
 +
**Grain size segregation.
 +
**Cation exchange capacity.
 +
 
* Break
 
* Break
== Research: Biology (David 10 min) ==  
+
 
 +
== Research: Biology (David 10 min) ==
 +
*Slide 1 - Biology Modules - I have to mention what we do in course modules very briefly because developing them is part of summer research and some of the course modules amass the samples for chemistry to analyze during summer research.
 +
*Slide 2 - Cartoon of mercury cycle/biomag. - for david to refer to throughout presentatition, and to begin with to discuss multi-disciplinary nature of env. toxicology and to demo what we inventory in the lake.
 +
*Slide 3 - Eco Bio module
 +
*Slide 4 - John I and students
 +
*Slide 5 - Vert Zoo module
 +
*Slide 6 - Hg cycle cartoon again...I need it.
 +
*Slide 7 - Cell Phys module
 +
*Slide 8 - Metallothionein model
 +
*Slide 9 - Summer research schedule
 +
*Slide 10 - Histopath slide of Hg poisoning
 +
*Slide 11 - Description of advanced summer research.
 +
 
 
== Seminars (Meg 5 min) ==
 
== Seminars (Meg 5 min) ==
  
Line 158: Line 247:
 
 
 
= Wrap-up: Review, questions, tour next (Mike 5 min) =
 
= Wrap-up: Review, questions, tour next (Mike 5 min) =
 +
 +
 +
Summary slide:
 +
 +
        Strong multidisciplinary and computational program
 +
 +
        Courses impact almost all Earlham students
 +
 +
        Research of local benefit
 +
 +
        Model for other institutions
 +
 +
 +
I will then ask if she has any questions (or additional questions if she has already been asking questions).
 +
 +
Lab visit slide -
 +
 +
Shows Stanley, Noyes, Dennis with people/departments indicated for lab tours.  Who is doing the geo tour?
 +
 +
Bon question. I (Ron) have class from 11 to 11:50.

Latest revision as of 19:40, 26 September 2006

I) Who we are (Mike 5 min)

1. Title slide - Computational and Multidisciplinary Curriculum and Research Initiative

2. Key personnel slide - everyone introduces themselves and mentions the classes that they teach - particularly the ones in the project

                  Key Personnel
                 Corinne Deibel (Chemistry)		
                 Michael Deibel (Chemistry)
                 John Iverson (Biology)			
                 Mic Jackson (Mathematics)
                 David Matlack (Biology)			
                 Ron Parker (Geosciences)
                 Charlie Peck (Computer Science)		
                 Meg Streepey (Geosciences)
                 Lori Watson (Chemistry)

3. Presentation Overview slide

               Why Earlham
               Why this Initiative
               Project description
               Why Keck

II) Why Earlham (Charlie 15 min)

  • Notes
    • re-read grant RFP
    • re-read grant proposal
  • Overview of Earlham
    • 1847, Quakers were a large portion of the early settlers to this area
    • Liberal arts with masters in teaching and two seminaries, Bethany and Earlham School of Religion
    • Quaker
      • Governance
      • Student/faculty interactions
    • Teaching first and foremost (but we do other things too, see Science Division)
  • Student Body
    • Diversity (science students in particular)
      • Efforts to improve enrollments in STEM disciplines
      • Over 24% of our students are eligible for PELL grants
    • International - over 60 countries represented
    • Curriculum
      • Liberal arts, general education requirements (analytical reasoning and scientific inquiry) ensure that science is a part of every students academic plan
      • Off-campus study, over 60% of students, many science based programs
      • More than 25% of our students major in a STEM discipline
  • Science Division
    • Faculty cohesiveness and collective strength
      • Generational shift in the science faculty over the past 8 years or so
      • Growth in the science faculty over the past 10 years or so (2 FTE in CS, 1 FTE in Chemistry, 1 FTE in Geosciences)
      • Multidisciplinary experience, e.g. bio-chemistry, environmental programs, computational science
      • Teaching awards, e.g. John's and Mic's (exact titles)
      • Intel International Science Fair judges
    • Science major to PhD strength
      • Geosciences 13th, Biology 8th (nationally), 90-100% acceptance rate to medical, dental, and veterinary school
      • Double major and major/minors with overlap in the sciences
    • Multidisciplinary applied science groups
      • Hardware Interfacing Project
      • Cluster Computing Group
      • Green Science
    • Student/faculty research experience (history, current)
      • Early 1960's; biology, geology, chemistry; soil science with radioactive tracers, bat species population.
      • Foundation on which over 40 years of experience has been built, funded mostly through external grants (e.g. NSF and HHMI)
      • $3M Endowed fund to support the core of summer student/faculty research part of the capital campaign, operating fund support for the near-term
      • Publications in peer reviewed journals and presentations at national and international meetings
    • Computational Experience
      • Folding@Home
      • Phylogenetic reconstruction of turtle DNA using Bayesian analysis
      • LittleFe and SC Education
    • Instrumentation and experience with it (for a metals project)
      • Inductively coupled plasma atomic emissions spectrometer (measures the concentration of up to 35 metals simultaneously)
      • Atomic absorption spectrometer
      • Clusters
      • Scanning electron microscope
      • Benchtop Xray difractometer
      • Weather station
    • $2.5M in science renovations and equipment in 2000, new science facilities design done last year, reuse and new space, explicit support for multidisciplinary work, part of the current capital campaign (currently in the quiet phase)
    • Pedagogical creativity
      • Short course to support MCM Modeling Contest
      • Computational science in context
  • Closing
    • The foundation of our faculty, our facilities (current and planned), and our students position Earlham well to undertake the broad science curriculum changes outlined in our proposal.

III) Why Project (Ron 15 min)

  • Goals and Objectives
  • All that other stuff

IV) What Project (50 min total)

Courses (Mike 5 min)

there are 2 slides for this - which are the tables of introductory and advanced courses

Intro classes - emphasize the number of intro classes, number of departments and particularly the number of students - tie this back to Charlie's mention of the gen ed requirements

Advanced classes - emphasize the number of classes, departments - mention connections to intro classes - give a couple of examples (i.e. student taking environmental chem/tox will already have taken gen chem and eq/al)

Intro: Gen Chem (Mike 10 min)

there are three slides for this part.

Slide one -

    Principles of Chemistry (CHEM 111) - 	typical enrollment of 90  
               Environmental module goals:
                   introduce basic spectroscopy concepts
                   illustrate an application of equilibrium constants
                   emphasize multidisciplinary connections 
                   introduce students to spreadsheet modeling

Slide two - this slide includes picture of Corinne and Kalani with ICP

    Week 1 – Spectroscopy 
                   atomic spectroscopy – ICP-AES and GFAAS
                   molecular spectroscopy – diode array

                   energy levels and light
                   color vs absorption


Slide three -

    Week 2 – measurement of Kd and Modeling
               kd – measure of soils ability to bind metal (illustration to the
                    right)
               Measure for different soils - mention both well characterized as 
                                             well as from our local sites
               Test parameter variability - includes sample graph from J chem 
                                            ed article on kd vs pH
               Model using a spreadsheet

Upper: Geology (Ron 10 min)

Hydrogeology – Study of ground water flow.

  • Physical dynamics.
    • Ground water recharge, flow and discharge.
    • Transient flow dynamics.
  • Chemical dynamics.
    • Equilibrium Speciation Modeling.
      • PHREEQCi
      • MINTEQA2
      • Geochemists Workbench 4.01
    • Contaminant transport modeling.
      • Visual MODFLOW

Geochemistry - Metal speciation controls cycling behavior.

  • Aqueous.
    • Equilibrium Speciation Modeling.
      • PHREEQCi
      • MINTEQA2
      • Geochemists Workbench 4.01
  • Mineralogy - Reactive mineral phase determination.
    • Disaggregation.
      • Carbonate.
      • Organic matter.
      • Cements.
    • Dispersal of charged particulates.
    • Grain size segregation.
    • Cation exchange capacity.
  • Break

Research: Biology (David 10 min)

  • Slide 1 - Biology Modules - I have to mention what we do in course modules very briefly because developing them is part of summer research and some of the course modules amass the samples for chemistry to analyze during summer research.
  • Slide 2 - Cartoon of mercury cycle/biomag. - for david to refer to throughout presentatition, and to begin with to discuss multi-disciplinary nature of env. toxicology and to demo what we inventory in the lake.
  • Slide 3 - Eco Bio module
  • Slide 4 - John I and students
  • Slide 5 - Vert Zoo module
  • Slide 6 - Hg cycle cartoon again...I need it.
  • Slide 7 - Cell Phys module
  • Slide 8 - Metallothionein model
  • Slide 9 - Summer research schedule
  • Slide 10 - Histopath slide of Hg poisoning
  • Slide 11 - Description of advanced summer research.

Seminars (Meg 5 min)

Increasingly necessary to explicitly teach students multidisciplinary aspects of science

Also important to provide a strong disciplinary foundation in the sciences

Seminars related to this project are key to being intentional about students' multidisciplinary experience.

Introductory seminars are voluntary, aimed at students with an interest in environmental science. Led by faculty, students who have taken or are taking one of the intro-level courses will present project results. Gives students a necessary intellectual framework for interpreting discipline-specific course research projects.

Advanced seminars are open to upper-level majors only. Will focus on project research in significantly more depth. Overall same goal as the intro course seminar, but more detailed and independent, given advanced intellectual development and knowledge base of upper-level students.

Seminars can be flexible to allow for future project topics; most important that students view a scientific problem through different disciplines, and are given some help in assimilating projects in different courses.

Dissemination/Evaluation (Lori 5 min)

Dissemination activities will include:

• NITLE workshop on integrating multi-disciplinary computational methods into the undergraduate science curriculum. We have already arranged with the National Institute for Technology and Liberal Education (NITLE) to offer a workshop for our peers where we will describe what we have done and offer suggestions for how similar programs can be implemented at their institutions.

• Earlham Science Poster Session (held each Fall)

• Student presentation of papers at regional and national scientific conferences (Butler Undergraduate Research Conference, Geological Society of America, American Chemical Society, etc).

• CUR publications and programs

• Student/Faculty papers in science pedagogy journals and basic science journals, as appropriate.

Evaluation will include:

• External evaluation both during and at the conclusion of the grant period

• Qualitative evaluation: open-ended surveys, interviews

• Quantitative evaluation: quantitative surveys, pre and post grant levels of undergraduate research, curricular use of computational modeling and interdisciplinary projects

V) Why Keck (Lori 5 min)

Why Keck:

• Long tradition of supporting curricular innovation: Funding for undergraduate research at small liberal arts colleges is limited. The W.M. Keck Foundation is known and respected throughout the scientific community as a foundation that supports innovative science programs at high-quality libral arts institutions.

• Limited sources of support for such a comprehensive multidisciplinary program: Most sources support only limited interdisciplinary work (bio and chem., for example) and most do not support such work at undergraduate institutions


• NSF funding for science education at 4yr institutions has been flat for past 10 years and curricular improvements funding has decreased by 50% over same timeframe


• Strong supporter of computational science education: the Keck Undergraduate Computational Science Education Consortium headed by Capital University.

• Keck support would also raise the visibility of the sciences regionally and nationally.

Wrap-up: Review, questions, tour next (Mike 5 min)

Summary slide:

        Strong multidisciplinary and computational program
        Courses impact almost all Earlham students
        Research of local benefit
        Model for other institutions


I will then ask if she has any questions (or additional questions if she has already been asking questions).

Lab visit slide -

Shows Stanley, Noyes, Dennis with people/departments indicated for lab tours. Who is doing the geo tour?

Bon question. I (Ron) have class from 11 to 11:50.