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<p><b><font size="2" face="Arial"><a name="1">Dan Butin</a><br>
</font></b><font size="2" face="Arial">Thomas Jefferson Center for Educational
Design <br>
University of Virginia<br>
July 2000<br>
</font></p>
<p><font size="2" face="Arial"><img src="headings/science_drop_cap_T.gif" width="27" height="35" align="left" alt="T">he
late astronomer Carl Sagan once said, "everybody starts out as a scientist.
Every child has the scientist's sense of wonder and awe" (CSMEE 1998:
1). The science classroom is no longer simply a place where students become
literate in key scientific concepts and terms, but rather a place to learn
how to ask questions, test hypothesis, and convey ideas and information.
To accommodate these activities, science facilities are being designed
that promote in-depth learning, foster curiosity, and enhance the interrelationship
between science and the greater environment.<br>
<br>
</font><a name="2"></a><img src="headings/science_edtrends.gif" width="128" height="18"><font size="2" face="Arial"><b>
</b> <br>
<br>
The National Research Council's National Science Education Standards state
that science education "should be developmentally appropriate, interesting,
and relevant to students' lives; emphasize student understanding through
inquiry; and be connected with other school subjects" (National Research
Council 1995). This description captures much of the change affecting
science education and its impact on facilities design. Three educational
trends specifically affect science education.</font>
<p> <font size="2" face="Arial"><b>Integrating science curriculums. </b>
Integration of science curriculums is occurring at two levels. First,
the traditional boundaries between the life and physical sciences are
being dismantled. Second, in general, the sciences are becoming more integrated
with other disciplines such as math and history. The ethical, historical,
and political issues within modern-day science--issues such as global
warming, bio- engineered food, and cloning--make science education an
integral component within an interdisciplinary curriculum (National Research
Council 1995). The implications for science facilities include considering</font>
<blockquote>
<p><font size="2" face="Arial"> • designing "universal labs" that
can accommodate multiple science curriculums and</font><br>
<font size="2" face="Arial">• placing science facilities in a central
location instead of an isolated wing.</font></p>
</blockquote>
<p>
<p><font size="2" face="Arial"><b>Project-based learning.</b> According
to the American Association for the Advancement of Science (AAAS), science
instruction should be hands-on and inquiry-based to promote and sustain
student interest and enthusiasm in science. The AAAS argues that 40 to
80 percent of science education should be devoted to laboratory time (AAAS
1990). To accommodate this development, facilities should be designed
to provide:</font>
<blockquote>
<p><font size="2" face="Arial"> • adequate lab workspace for all
students in the classroom and</font><br>
<font size="2" face="Arial">• multiple spaces, such as project
centers and conference rooms, for individual and small group work.</font></p>
</blockquote>
<p>
<p> <font size="2" face="Arial"><b>Integrating technology.</b> "The global
village may be a cliché," argues the National Science Teachers
Association (NSTA), "but the global classroom is a reality" (NSTA 1999).
In enhancing the science curriculum, teachers are looking beyond their
classroom walls to develop more relevant and broad-based activities. Students
are logging onto the Internet to watch frog dissections, download photographs
from orbiting satellites, and converse with experts. They are obtaining
an in-depth analysis of the functioning of the human body and chemical
reactions through interactive computer programs. And telecommunication
connects classrooms with other classrooms, universities, and scientific
facilities worldwide.<br>
<br>
</font><a name="3"></a><img src="headings/science_keyspaces.gif" width="173" height="35"><font size="2" face="Arial"><b>
</b> <br>
<br>
Elementary school science programs should be centered around activities
and hands-on learning. While science has traditionally been taught within
the general classroom, some schools are developing "discovery" rooms that
integrate math, art, and science activities. In either case, the space
should be between 1,000 and 1,500 square feet--depending on class size,
local and state building codes, and the amount of technology integration--and
allow for individual study, small and large group work, and lecture-format
instruction. The classroom should be directly accessible to outdoors to
allow for the integration of the environment into the science curriculum.</font>
<p><font size="2" face="Arial"> In general, an elementary school science
facility should have the following spaces (Maryland State Department of
Education 1994: 23 26):</font>
<p> <font size="2" face="Arial"><b>Wet area.</b> The wet area requires a
sink with hot and cold water, GFI-protected electrical outlets, and a
large enough space for small groups to observe demonstrations.</font>
<p> <font size="2" face="Arial"><b>Holding area.</b> Science activities,
including projects that can last from several days to several weeks, often
require ongoing observation and experimentation. A space is therefore
needed that allows students to observe, gather data, and store science
projects.</font>
<p> <font size="2" face="Arial"><b>Learning centers.</b> To encourage active
learning, multiple learning centers should be spaced around the perimeter
of the room. The learning center may involve the use of computers, microscopes,
or other materials. Students may work alone or in small groups to build
models, work with laboratory kits, or plan projects. Movable tables and
a flat counter top along the perimeter are best for this area; allow a
minimum of two linear feet of space per student. Electrical and data outlets
should be provided every four feet.</font>
<p> <font size="2" face="Arial"><b>Storage room/preparation area.</b> Science
activities require a large number of supplies and materials. The storage
room should be a minimum of 100 to 200 square feet and be equipped with
a sink, electrical outlets, and storage. A space where teachers can prepare
experiments or lab kits is useful. Storage should encompass multiple storage
cabinets and bins, including bookshelves, open shelf storage, flat storage,
and tote tray storage. The storage room should serve, and thus be accessible
to, more than one science classroom. A walk-in storage closet may be a
feasible option for a single science classroom.</font>
<p><font size="2" face="Arial"> The elementary school science facility will
vary widely depending on the grade level. For example, grades 3 to 5 will
require differently sized furnishings, additional equipment, and more
elaborate activity centers than those found in grades K through 2 (Lowry
1997: 11). Nevertheless, all elementary school science facilities should
have a large-screen television or video projection system. These can be
mounted either from the ceiling or brought in on a rolling cart.<br>
<br>
</font><a name="4"></a><img src="headings/science_keyspaces2.gif" width="168" height="36"><font size="2" face="Arial"><b>
</b> <br>
<br>
Although middle school science curriculums differ from high school science
programs, their facilities needs are comparable. Middle school programs
traditionally conduct less sophisticated laboratory experiments, have
a wider variety of activities--such as math, computers, health, and art--and
do not focus as heavily on individual in-depth lab work (NSTA 1990; Texley
and Wild 1996; Rakow 1998). High school science programs, on the other
hand, are more project centered and question based. A good middle school
science facility should, nevertheless, be comparable to high school programs
in providing adequate resources and spaces.</font>
<p><font size="2" face="Arial"> The secondary science facility should be
directly accessible to the outdoors and provide multiple spaces for lectures,
demonstrations, small group or individual projects and experimentation,
and project exhibits. Electrical and data outlets should be placed throughout
the room and spaced for either computer workstations or laptops. Consideration
should be given to advances in technology that may soon allow wireless
networks (NSF 1999). </font>
<p><font size="2" face="Arial"> The science facility should accommodate
a maximum of 24 to 28 students. Due to issues of supervision, safety concerns,
and instructional goals, NSTA recommends a maximum class size of 24. All
science facilities should provide handicapped students full access to
science equipment and experiments (Office for Civil Rights 1999; Biehle
1995: 54).</font>
<p><font size="2" face="Arial"> Secondary science facilities should include:</font>
<p> <font size="2" face="Arial"><b>Combination classroom/laboratory.</b>
This is a dedicated laboratory space that is shared by several science
classrooms or serves as a combination classroom/laboratory. While the
former option may be an efficient hub for several "houses," the latter
option is usually more flexible in meeting the changing curricular needs
of science instruction and the school in general. A combination classroom/laboratory
should be a minimum of 1,400 to 1,500 square feet (1,200 1,300 sq. ft.
in middle school) to provide adequate space for laboratory work. The two
most common arrangements of combination spaces are </font>
<blockquote>
<p><font size="2" face="Arial"> • fixed student workstations and
a separate area for classroom instruction and </font><br>
<font size="2" face="Arial">• movable tables that can serve for
classroom instruction and as laboratory space when located near the
utilities and sinks at the perimeter of the room (NSTA 1999).</font></p>
</blockquote>
<p>
<p><font size="2" face="Arial">The room should have a variety of cabinets
and drawers above and below lab stations. Sinks and electrical outlets
should be placed along the perimeter of the room. If the classroom is
to have fixed workstations, three- or four-sided "utility islands" with
sinks and electrical and data outlets can be spaced throughout the room.
The tables and workspaces around the perimeter of the room should have
flat, durable "lab" top surfaces. The room should have adequate natural
and task lighting to grow plants, observe experiments, and draw. All science
room, prep room, and storage room doors should lock.</font>
<p><font size="2" face="Arial"> It may also be beneficial to design the
main science room as a more flexible and adaptable space--a type of "science
studio" where individual students and groups engage in long-term, in-depth
projects. Such a space might have high ceilings, minimal cabinetry, and
outlets throughout that provide water, gas, electricity, and data capability
(Maryland State Depart-ment of Education 1994; Biehle 1998: 1).</font>
<p> <font size="2" face="Arial"><b>Preparation room.</b> The preparation
room should be directly accessible from the classroom and may be used
for storage and teacher preparation. The room should be between 200 and
500 square feet, have a large window through which to supervise the classroom/laboratory,
and have the necessary utilities--i.e., electricity and water--to prepare
for and conduct classroom projects. The preparation room should have a
phone, an acid-resistant sink with hot and cold water, an ice-making refrigerator,
a full-size dishwasher, and the capacity to handle specialized fixtures
such as an autoclave or distiller. The room should also have multiple
base cabinets.</font>
<p> <font size="2" face="Arial"><b>Storage room.</b> Primarily used for
the storage of chemicals, specimens, and materials, the room should be
approximately 100 to 200 square feet (depending on the number of classrooms
served) and accessible only from the preparation room or situated in between
two science classrooms. The storage room should have the maximum possible
linear feet of wall-mounted, adjustable shelving and base cabinets. To
prevent sparks and potential explosions, there should be no electrical
outlets in this room. A fire resistant storage cabinet and non-corroding
acid cabinet (situated below eye level) should be considered for hazardous
materials.</font>
<p> <font size="2" face="Arial"><b>Greenhouse.</b> A greenhouse can greatly
enhance the curricular offerings of the science program. The greenhouse
should range from 200 to 400 square feet; have separate thermostatic controls,
access to ample water, a floor drain, and humidity control; and be able
to function when school is not in session.</font>
<p> <font size="2" face="Arial"><b>Teacher workspace and faculty offices.</b>
Science teachers should have their own workspace apart from any classroom
preparation space. Separate science offices may be considered or science
teachers may be placed with teachers from other departments to foster
cross-disciplinary interaction and collaboration.</font>
<p> <font size="2" face="Arial"><b>Resource room/small group workroom.</b>
A science resource and workroom can provide valuable space for student
experimentation and inquiry and serve as conference and study spaces.
The room should have a water supply and be furnished with movable tables
and chairs, a whiteboard, multiple cabinets and shelving, multiple electrical
and data outlets, and work counters with space for an aquarium or terrarium.
Teachers should be able to supervise the workroom from the classroom.<br>
<br>
</font><a name="5"></a><img src="headings/science_princ.gif" width="247" height="18"><font size="2" face="Arial">
</font><br>
<br>
<font size="2" face="Arial">Science can be taught in a wide range of settings,
from a regular classroom to a state-of-the-art facility dedicated to science
instruction. All of these learning environments, though, should have several
common features to facilitate quality science instruction.</font>
<p> <font size="2" face="Arial"><b>Promote safety.</b> Safety is of paramount
importance in the science classroom. Chemicals, bunsen burners, and dissection
tools are but a few of the multiple hazards lurking in the science classroom.
All science facilities should have a hands-free eye wash, fire blanket,
fire extinguisher, and first-aid kit. Secondary school science facilities
also should consider installing a fume hood and safety shower if the space
is to be used for chemistry or advanced biology classes. A clearly marked
master cut-off switch for utilities should be located at the front of
the room or be easily accessible in the preparation room (avoid placing
the cut-off switch near a bank of light switches). An HVAC system dedicated
to just the science facilities will provide necessary air changes and
adequate amounts of fresh air. Both the classroom and preparation area
should have telephones to summon emergency technicians. Remember, a larger
room or a smaller number of students can also increase safety.</font>
<p> <font size="2" face="Arial"><b>Integrate the natural environment into
the classroom.</b> Investigating and understanding science can be greatly
enhanced when students have access to the outdoors. Some examples include
providing a nature trail, a garden, a weather station, a wetland area
with a stream, or an outdoor classroom or greenhouse. Outdoor activities
allow students another opportunity to experience science as a relevant,
hands-on aspect of their daily lives.</font>
<p> <font size="2" face="Arial"><b>Foster curiosity and creativity.</b>
"The science classroom," AAAS notes, "ought to be a place where creativity
and invention are recognized and encouraged" (AAAS 1990). Science is as
much about creativity and wonder as it is about logical thinking and factual
knowledge. The design of the science facility can promote such goals through
numerous means, such as turning the classroom and school into a "textbook."
Exposed HVAC, plumbing, and electrical systems allow students to observe
the electrical and mechanical workings of a complex system. Skylights
or multiple windows allow students to observe weather patterns and the
movement of the sun. Read-only displays of key school data, such as temperature
and energy use, can transform the physical classroom into a teaching tool.
In general, the science classroom should be an intellectually stimulating
environment.</font>
<p><font size="2" face="Arial"> Science facility design can offer learning
environments where inquiry, experimentation, and discussions are valued
and encouraged. If every child is truly a scientist, then every science
facility should have the potential to capture a student's interests and
curiosity.<br>
<br>
</font><a name="6"></a><img src="headings/references.gif" width="68" height="18"><font size="2" face="Arial"><b>
</b> <br>
<br>
American Association for the Advancement of Science (AAAS). 1990. <cite>Project
2061: Science for All Americans. </cite> N.Y.: Oxford University Press.
<a href="http://project2061.aaas.org/tools/sfaaol/sfaatoc.html" target="_parent">
<i>http://project2061.aaas.org/tools/sfaaol/sfaatoc.html</i></a></font>
<p><font size="2" face="Arial"> Biehle, James T. 1995. "Complying with Science."
<cite>American School & University </cite> (May), pp. 54—56.</font>
<p><font size="2" face="Arial"> Biehle, James T. 1998. "The Science Resource
Area in the State-of-the-Art High School." <cite>Inside/Out Science.</cite>
Clayton, Mo.: Inside/Out Architects.</font>
<p><font size="2" face="Arial"> Center for Science, Mathematics, and Engineering
Education (CSMEE). 1998. <cite>Every Child a Scientist: Achieving Scientific
Literacy for All.</cite> Washington, D.C. National Academy Press.</font>
<p><font size="2" face="Arial"> Lowry, Lawrence F.,ed. 1997. <cite>NSTA
Pathways to the Science Standards: Guidelines for Moving the Vision into
Practice, Elementary School Edition.</cite> Arlington, Va.: National Science
Teachers Association.</font>
<p><font size="2" face="Arial"> Maryland State Department of Education.
1994. <cite>Science Facilities Design Guidelines. </cite> Baltimore, Md.:
Maryland State Department of Education.</font>
<p><font size="2" face="Arial"> National Research Council, National Committee
on Science Education Standards and Assessment. 1995. <cite>National Science
Education Standards.</cite> Washington, D.C.: National Academy Press.
</font> <font size="2" face="Arial"><cite><a href="http://books.nap.edu/catalog/4962.html" target="_parent">http://books.nap.edu/catalog/4962.html</a></cite>
</font>
<p><font size="2" face="Arial"> National Science Foundation. 1999. "National
Science Foundation Wireless Field Test for Education Project, Old Colorado
City Communications." </font> <font size="2" face="Arial"><cite><a href="http://wireless.oldcolo.com" target="_parent">http://wireless.oldcolo.com</a></cite>
</font>
<p><font size="2" face="Arial"> National Science Teachers Association (NSTA).
1990. Science Education for Middle Level Students. <i><a href="http://www.nsta.org/159&psid=20">http://www.nsta.org/159&psid=20</a></i></font>
<p><font size="2" face="Arial"> National Science Teachers Association (NSTA).
1999. NSTA Guide to School Science Facilities. Arlington, Va: National
Science Teachers Association.</font>
<p><font size="2" face="Arial"> Office for Civil Rights. 1999. <cite>Compliance
with the Americans with Disabilities Act: A Self-Evaluation Guide for
Public Elementary and Secondary Schools.</cite> U.S. Department of Education.
</font>
<p><font size="2" face="Arial"> Rakow, Steven L., ed. 1998. <cite>NSTA Pathways
to the Science Standards: Guidelines for Moving the Vision into Practice,
Middle School Edition. </cite> Arlington, Va.: National Science Teachers
Association.</font>
<p><font size="2" face="Arial"> Texley, Juliana and Ann Wild, eds. 1996.
<cite>NSTA Pathways to the Science Standards: Guidelines for Moving the
Vision into Practice, High School Edition.</cite> Arlington, Va.: National
Science Teachers Association.<br>
<br>
</font><img src="headings/additional_info.gif" width="130" height="18"><font size="2" face="Arial"><b>
</b> <br>
<br>
See the NCEF annotated bibliography <i>Science Facilities</i>, online
at </font> <font size="2" face="Arial"><i><a href="http://www.edfacilities.org/rl/science_HE.cfm" target="_parent">http://www.edfacilities.org/rl/science_HE.cfm</a> and <a href="http://www.edfacilities.org/rl/science.cfm" target="_parent">http://www.edfacilities.org/rl/science.cfm</a><br><br></i></font><img src="headings/reviewers.gif" width="61" height="18">
<br>
<br>
<font size="2" face="Arial">Al Abend, James Biehle, Edward Brzezowski,
Lee Burch, Judy Marks, Joe Nathan, and Sarah Woodhead.<br>
<br>
</font><img src="headings/sponsorship.gif" width="73" height="19"> <br>
<br>
<font size="2" face="Arial">This publication was funded in part by the
National Clearinghouse for Educational Facilities (NCEF), an affiliate
clearinghouse of the Educational Resources Information Center (ERIC) of
the U.S. Department of Education.</font>
<p> </p>
<p> </p>
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