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Title: Marv Lang, Don Showalter


1
Green Chemistry
Teacher Enhancement Workshop
Kamehameha High School, Oahu, Hawaii
  • Presented by
  • Marv Lang, Don Showalter Gary Shulfer
  • University of Wisconsin-Stevens Point, USA
  • Presentation constructed by Angela Burmeister
  • University of Wisconsin Stevens Point, USA

2
What is Green Chemistry?
  • Green chemistry is the use of chemistry for
    pollution prevention.
  • Pollution prevention is the use of materials,
    processes, or practices that reduce or eliminate
    the creation of pollutants or wastes at the
    source. It includes practices that reduce the
    use of hazardous and nonhazardous materials,
    energy, water, or other resources as well as
    those that protect natural resources through
    efficient use. -U.S. EPA
  • The design of chemical products and processes
    that are more environmentally benign.
  • Encompasses all aspects and types of processes
    that reduce negative impacts to human health and
    the environment.
  • Focuses on processes and products that reduce or
    eliminate the use and generation of hazardous
    substances.
  • Became a formal focus of the U.S. EPA in 1991
    with the formation of their Green Chemistry
    Program.
  • Promotes research, development and implementation
    of inventive chemical technologies that
    accomplish pollution prevention in both a
    scientifically-sound and cost-effective manner.

3
The Twelve Principles
  • Prevention - It is better to prevent waste than
    to treat or clean it up after its been created.
  • Atom Economy - Synthetic methods should be
    designed to maximize the incorporation of all the
    materials that are used in the process.
  • Less Hazardous Chemical Synthesis - Synthetic
    methods should be designed to use and generate
    substances that possess little or no toxicity to
    human health and the environment wherever
    possible.
  • Designing Safer Chemicals - Chemical products
    should be designed to effect their desired
    function while minimizing their toxicity.
  • Safer Solvents and Auxiliaries - The use of
    solvents, separation agents and other auxiliary
    substances should be made unnecessary wherever
    possible and innocuous when used.
  • Design for Energy Efficiency - Energy
    requirements should be minimized, synthetic
    methods should be conducted at ambient
    temperature and pressure.
  • 7. Use of Renewable Feedstocks - A raw material
    or feedstock should be renewable rather than
    depleting whenever technically and economically
    practicable.
  • 8. Reduce Derivatives - Unnecessary
    derivatization should be minimized or avoided
    because such steps require additional reagents
    and can generate waste.
  • 9. Catalysis - Catalytic reagents are superior to
    stoichiometric reagents.
  • 10. Design for Degradation - Chemical products
    should be designed so that at the end of their
    function they break down into innocuous
    degradation products that do not persist in the
    environment.
  • 11. Real-time Analysis for Pollution Prevention -
    Analytical methodologies need to be further
    developed to allow for real-time, in-process
    monitoring and control prior to the formation of
    hazardous substances.
  • 12. Inherently Safer Chemistry for Accident
    Prevention - Substances and their form used in a
    chemical process should be chosen to minimize the
    potential for chemical accidents, including
    releases, explosions and fires.

4
Environmental Chemistry versus Green Chemistry
  • Environmental chemistry is the study of sources,
    reactions, transport and fate of chemical
    entities in the air, water, and soil environments
    as well as their effects on human health and the
    environment.
  • Focuses on the environmental management of
    chemicals.
  • Concerned not only with the chemical pollutants
    in the environment but also with the behavior of
    natural chemicals in natural systems.
  • When chemical use results in environmental
    contamination, it is necessary to set standards
    for acceptable concentrations in water, air, soil
    and biota.
  • Has focused on the effects of what man has put
    into the environment and how to deal with and
    remediate contamination sites.
  • Dilution is the solution to pollution
  • In contrast, green chemistry focuses on how to
    change what human activity puts into the
    environment in order to eliminate or reduce
    effects and prevent contamination sites.
  • An milligram of prevention is worth a kilogram
    of cure.

5
Green Synthesis of Ibuprofen
  • The Boots Company PLC developed and patented the
    six step brown synthesis of ibuprofen in the
    1960s.
  • The synthesis process results in millions of
    pounds of unwanted, unutilized, and unrecycled
    waste chemical byproducts that have to be treated
    or disposed of each year.
  • The percentage atom economy of the brown
    synthesis of ibuprofen is 40 ?60 (by weight) of
    all reagent atoms are incorporated into unwanted
    byproduct or waste.
  • The BHC Company developed and patented a greener,
    three step synthesis of ibuprofen in 1991.
  • Their goal was to develop and put into practice a
    more efficient and environmentally sensitive
    method of synthesizing ibuprofen to market.
  • The green synthesis provides for a far greater
    atom economy at 77 (99 if the acetic acid
    recovered from the first step is considered).
  • This method prevents the formation of millions of
    pounds of waste and chemical byproduct as well as
    saves millions of pounds of reactant materials.
  • The BHC Company won a Presidential Green
    Chemistry Challenge Award in 1997 for their
    development of this synthesis.

6
Green Synthesis of Ibuprofen continued
  • There are also other environmental advantages to
    the green synthesis.
  • The brown synthesis requires auxiliary reagents
    in stoichiometric amounts. In contrast, the
    green synthesis is catalytic.
  • The green synthesis uses reagents which are
    recovered and reused repeatedly (e.g. HF, Raney
    nickel, and Pd).
  • The green synthesis offers greater throughput
    which allows larger quantities to be produced in
    less time resulting in less capital expenditure
    and significant economic benefits.

7
Benefits to Industry
  • Economic Benefits of Pollution Prevention
  • 1) Save money in materials
  • a) Waste is reduced
  • b) More product is produced
  • 2) Improve product quality
  • 3) Conserve energy and water
  • 4) Save money in regulatory and compliance
    costs
  • a) No liability for waste produced
  • -3M saved 750 million in waste disposal costs
    by 1995 after implementing their Pollution
    Prevention Pays (3P) program in 1975.
  • Pollution Prevention can also help a business
  • 1) Improve its bottom line
  • 2) Make compliance with environmental
    regulations easier
  • 3) Demonstrate a proactive commitment to the
    environment

8
Green Chemistry atThe Dow Chemical Company
  • Believe in the triple bottom line-meeting social,
    economic, and environmental objectives.
  • Committed to reducing emissions by improving
    energy efficiency, developing less
    energy-intensive manufacturing processes, and
    producing climate-friendly products.
  • Recent efforts and achievements in green
    chemistry at Dow
  • Spinosad- Recipient of the 1999 Presidential
    Green Chemistry Challenge Award
  • Active ingredient in Tracer Naturalyte insect
    control targeting chewing worm pests
  • Derived through the fermentation of a naturally
    occurring organism
  • Helps preserve the local environment while
    helping to make farms more productive, generate
    higher yields while still cost-effective to the
    farmer
  • Not harmful to beneficial insects, mammals or
    fish and breaks down quickly into organic matter
    after three or four hours of sunlight exposure

9
Dow Chemical Co. continued
  • Sentricon Termite Colony Elimination System-
    Recipient of the 2000 PGCC Award
  • Uses a very small amount of active ingredient and
    less intrusive than traditional methods
  • Uses a targeted approach leading to high
    technical performance, environmental
    compatibility, and reduced human risk
  • Protects about 500,000 structures across the
    country, including the Statue of Liberty, the
    White House, and Independence Hall, as well as
    structures in Australia, France, Spain and Japan

10
Green Chemistry atKodak
  • Recently set a series of 5-year environmental
    goals for worldwide operations to be achieved by
    January 1, 2004.
  • Address 3 strategic initiatives
  • Greater reductions in emissions of 30 priority
    chemicals, methylene chloride, and carbon dioxide
  • Preservation of natural resources including
    reduction in the production of manufacturing
    waste, energy, water usage, and virtual
    elimination of heavy metals from Kodak products
    (e.g. Cd, Hg, Pb, Cr (IV))
  • Strengthening of the companys environmental
    management

11
Kodak continued
  • Pollution Prevention and Waste Minimization
  • Leader in recycling and reuse of its materials
  • Captures and reuses manufacturing solvents and
    silver
  • Recycles scrap, PET plastic and paper
  • Silver recovery
  • Ion exchange technology to recover wastewater
    silver
  • T-Grain emulsions use less film and fewer
    chemicals
  • EPA 33/50 Program
  • EPA set goals of 33 reduction by 1992 and 50
    reduction by 1995
  • Kodak participated and reduced emissions of the
    17 targeted chemicals by 71 by the end of 1994

12
Green Chemistry andEducation
  • The ACS Division of Education and International
    Activities, in partnership with the EPA Office of
    Pollution Prevention and Toxics (OPPT), is
    currently developing educational materials to
    start incorporating green chemistry into the
    general chemistry classroom.
  • Teachers and professors should begin
    incorporating green goals into their courses to
    provide students with knowledge and skills to
    practice green chemistry without compromising the
    integrity of the chemical knowledge.
  • Available resources
  • Annotated Bibliography on Green Chemistry-
    Reference tool for use in chemistry curriculum
    available as a searchable data base to the ACS
    Education Web page at http//center.acs.org/appli
    cations/greenchem
  • Real-World Cases in Green Chemistry- Contains ten
    projects that have won or been nominated for the
    PGCC Award designed for a variety of
    undergraduate courses resource of specific
    examples of redesigning chemical products and
    processes.
  • Chemistry in Context and ChemCom- ACS courses for
    undergraduate and high school students,
    respectively, include new green chemistry
    materials and concepts.
  • Journal of Chemical Education- Several articles
    on green chemistry and incorporating it into
    teaching have been published.

13
Education continued
  • Resources in development
  • Green chemistry labs, demonstrations, teaching
    modules for high school teachers, publication of
    readings, green chemistry video resource for high
    school teachers, short courses, workshops,
    meetings and symposia.
  • Also, undergraduate courses in green chemistry
    are being developed by various universities such
    as Carnegie Mellon University, the University of
    Delaware and the University of Scranton.
  • The biggest challenge of green chemistry is to
    get people to adopt it. We would like to see it
    incorporated into every course from high school
    onwards. A. Matlack, Green Chemistry, February
    1999

14
Resources
  • Amato, Ivan. The Slow Birth of Green Chemistry.
    Science,Vol. 259, 12 March 1993, 1538-1541.
  • Anastas, P.T. Warner, J.C. Green Chemistry
    Theory and Practice Oxford University Press
    New York, 1998.
  • Cann, Michael C. Bringing State of the Art,
    Applied, Novel, Green Chemistry to the Classroom
    by Employing the Presidential Green Chemistry
    Challenge Awards. J. Chem. Ed. 1999, 76 (12),
    1639-1641.
  • Cann, M.C. Connelly, M.E. Real World Cases in
    Green Chemistry, American Chemical Society
    Washington, DC, 2000.
  • Collins, T.J. Introducing Green Chemistry in
    Teaching and Research. J. Chem. Ed. 1995, 72
    (11), 965-966.
  • Connell, Des W. Basic Concepts of Environmental
    Chemistry CRC Press LLC-Lewis Publishers New
    York, 1997.
  • Dow Chemical Company Web sites. (accessed Mar
    2001) www.dow.com/dow_news/corporate/co9_6_28.h
    tml www.dow.com/dow_news/prodbus/20000627a_pb.ht
    ml www.dow.com/dow_news/prodbus/20000627b_pb.
    html www.dow.com/dow_news/speeches/spe_lauzon
    _may.html

15
Resources continued
  • Freeman, Harry F. Industrial Pollution
    Prevention Handbook McGraw-Hill, Inc., 1995.
  • Frost, John. Green Chemistry at Work Products
    Can be Made From Glucose Instead of Benzene.
    U.S. Environmental Protection Agency Web site.
    (accessed April 2001) www.epa.gov/docs/epajrnal/f
    all94/09.txt.html
  • Kodak Web sites. (accessed Mar 2001)
    www.kodak/com/US/en/corp/environment/commitme
    nt/goals.shtml www.kodak/com/US/en/corp/environ
    ment/operations/prevention/index.shtml
    www.kodak/com/US/en/corp/environment/operations/v
    oluntary/design.shtml www.kodak/com/US/en/corp/e
    nvironment/operations/voluntary/epa.shtml
  • Matlack, A. Teaching Green Chemistry. Green
    Chemistry 1999, 1 (1), G19-G20.
  • Schulz, William. ACS green Chemistry Initiatives
    Get Boost from EPA Grant. Chemical and
    Engineering News, August 17, 1998, 47, 59.
  • U.S. Environmental Protection Agency Web site.
    (accessed Jan 2001) www.epa.gov/greenchemistry.
    htm
  • Again, a special thanks to Angie Burmeister for
    constructing this presentation!
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