Introduction
At an
early age, all children have the capacity and propensity to observe, explore,
and discover the world around them (NRC 2012). These are basic abilities for
science learning that can and should be encouraged and supported among children
in the earliest years of their lives. The National Science Teachers Association
(NSTA) affirms that learning science and engineering practices in the early
years can foster children’s curiosity and enjoyment in exploring the world
around them and lay the foundation for a progression of science learning in
K–12 settings and throughout their entire lives.
This
statement focuses primarily on children from age 3 through preschool. NSTA
recognizes, however, the importance of exploratory play and other forms of
active engagement for younger children from birth to age 3 as they come to
explore and understand the world around them. This document complements NSTA’s
position statement on elementary school science (NSTA 2002) that focuses on
science learning from kindergarten until students enter middle or junior high.
Current
research indicates that young children have the capacity for constructing
conceptual learning and the ability to use the practices of reasoning and
inquiry (NRC 2007, 2012). Many adults, including educators, tend to
underestimate children’s capacity to learn science core ideas and practices in
the early years and fail to provide the opportunities and experiences for them
to foster science skills and build conceptual understanding (NRC 2007, p. vii).
Also underestimated is the length of time that young children are able to focus
on science explorations. Effective science investigations can deeply engage
young children for extended periods of time, beyond a single activity or
session.
NSTA
supports the learning of science among young children that will create a
seamless transition for learning in elementary school.
Young
Children and Science Learning
NSTA
identifies the following key principles to guide the learning of science among
young children.
· Children have the capacity to
engage in scientific practices and develop understanding at a conceptual level.
Current
research shows that young children have the capacity for conceptual learning
and the ability to use the skills of reasoning and inquiry as they investigate
how the world works (NRC 2007, NRC 2012). For example, their play with blocks,
water, and sand shares some science-relevant characteristics. Young children
also can learn to organize and communicate what they learn, and know the
difference between concrete and abstract ideas (Carey 1985). Adults who engage
children in science inquiry through the process of asking questions,
investigating, and constructing explanations can provide developmentally
appropriate environments that take advantage of what children do as part of
their everyday life prior to entering formal school settings (NAEYC 2013, p.
17; NRC 2007).These skills and abilities can provide helpful starting points
for developing scientific reasoning (NRC 2007, p. 82).
· Adults play a central and important
role in helping young children learn science.
Everyday
life is rich with science experiences, but these experiences can best
contribute to science learning when an adult prepares the environment for
science exploration, focuses children’s observations, and provides time to talk
about what was done and seen (NAEYC 2013, p. 18). It is important that adults
support children’s play and also direct their attention, structure their
experiences, support their learning attempts, and regulate the complexity and
difficulty of levels of information (NRC 2007, p. 3). It’s equally important
for adults to look for signs from children and adjust the learning experiences
to support their curiosity, learning, and understanding.
· Young children need multiple
and varied opportunities to engage in science exploration and discovery (NAEYC 2013).
Young
children develop science understanding best when given multiple opportunities
to engage in science exploration and experiences through inquiry (Bosse,
Jacobs, and Anderson 2009; Gelman, Brenneman, Macdonald, and Roman 2010). The
range of experiences gives them the basis for seeing patterns, forming
theories, considering alternate explanations, and building their knowledge. For
example, engaging with natural environments in an outdoor learning center can
provide opportunities for children to examine and duplicate the habitats of
animals and insects, explore how things move, investigate the flow of water,
recognize different textures that exist, make predictions about things they
see, and test their knowledge.
· Young children develop science
skills and knowledge in both formal and informal settings.
Opportunities
to explore, inquire, discover, and construct within the natural environment and
with materials that are there need to be provided in formal education settings,
such as preschool and early care and education programs through intentional
lessons planned by knowledgeable adults. In addition, children need to have
opportunities to engage in science learning in informal settings, such as at
home with cooking activities and outdoor play or in the community exploring and
observing the environment.
· Young children develop science
skills and knowledge over time.
To
effectively build science understanding, young children need opportunities for
sustained engagement with materials and conversations that focus on the same
set of ideas over weeks, months, and years (NRC 2007, p. 3). For example,
investigating the concept of light and shadows over several weeks indoors and
out with a variety of materials and multiple activities will allow children to
re-visit and re-engage over time, building on observations and predictions from
day to day.
· Young children develop science
skills and learning by engaging in experiential learning.
Young
children engage in science activities when an adult intentionally prepares the
environment and the experiences to allow children to fully engage with
materials. The activities allow children to question, explore, investigate,
make meaning, and construct explanations and organize knowledge by manipulating
materials.
Declarations
NSTA
recommends that teachers and other education providers who support children’s
learning in any early childhood setting should
· recognize the value
and importance of nurturing young children’s curiosity and provide experiences
in the early years that focus on the content and practices of science with an
understanding of how these experiences connect to the science content defined
in the Next Generation Science Standards (NGSS)(NGSS Lead
States 2013);
· understand that
science experiences are already a part of what young children encounter every
day through play and interactions with others, but that teachers and other
education providers need to provide a learning environment that encourages
children to ask questions, plan investigations, and record and discuss findings;
· tap into, guide,
and focus children’s natural interests and abilities through carefully planned
open-ended, inquiry-based explorations;
· provide numerous
opportunities every day for young children to engage in science inquiry and
learning by intentionally designing a rich, positive, and safe
environment for exploration and discovery;
· emphasize the
learning of science and engineering practices, including asking questions and
defining problems; developing and using models; planning and carrying out investigations;
analyzing and interpreting data; using mathematics and computational thinking;
constructing explanations and designing solutions; engaging in argument from
evidence; and obtaining, evaluating, and communicating information (NRC 2012,
NGSS Lead States 2013);
· recognize that
science provides a purposeful context for developing literacy skills and
concepts, including speaking, listening, vocabulary development, and many
others; and
· recognize that
science provides a purposeful context for use of math skills and concepts.
NSTA
recommends that teachers and other providers who support the learning of
science in young children be given professional development experiences that
· engage them in
learning science principles in an interactive, hands-on approach, enabling them
to teach about science principles appropriately and knowledgeably;
· are ongoing and
science-specific;
· help them
understand how children learn science and engineering practices (NRC 2012, NGSS
Lead States 2013);
· inform them about a
range of strategies for teaching science effectively; and
· include the use of
mentors to provide ongoing support for educators for the application of new
learning.
NSTA
recommends that those in a position to provide financial, policy, and other
support for early childhood education should
· provide appropriate
resources for teachers and children;
· ensure a positive
and safe environment for exploration and discovery;
· ensure teachers
receive sustained science-specific professional development that includes how
children learn and how to teach science;
· provide mentoring;
and
· establish a
coherent system of science standards, instruction, appropriate assessment, and
curriculum.
Parents and other caregivers
can nurture children’s natural curiosity about the world around them, creating
a positive and safe environment at home for exploration and discovery. These
recommendations can be found in NSTA’s position statement, Parent Involvement in Science Learning (NSTA
2009), found at www.nsta.org.
—Adopted by the NSTA Board of Directors,
January 2014
References
Bosse, S., G. Jacobs,
and T. L. Anderson. 2009. Science in the air. Young Children, p. 10–15, reprinted and retrieved at www.naeyc.org/files/yc/file/200911/BosseWeb1109.pdf.
Carey, S. 1985. Conceptual change in childhood. Cambridge, MA: The MIT Press.
Gelman, R., K.
Brenneman, G. Macdonald, and M. Roman. 2010. Preschool pathways to science: Ways of doing, thinking,
communicating and knowing about science. Baltimore, MD: Brookes Publishing.
National Association
for the Education of Young Children (NAEYC). 2013. All criteria document,
17–18. Retrieved from www.naeyc.org/files/academy/file/AllCriteriaDocument.pdf
National Research
Council (NRC). 2007. Taking science to school:
Learning and teaching science in grades K–8. Washington, DC: National
Academies Press.
National Research
Council (NRC). 2012. A framework for K–12 science
education: Practices, crosscutting concepts, and core ideas. Washington, DC:
National Academies Press.
National Science
Teachers Association (NSTA). 2002. NSTA
Position Statement: Elementary School Science.
National Science
Teachers Association (NSTA). 2009. NSTA
Position Statement: Parent Involvement in Science Learning.
NGSS Lead States.
2013. Next Generation Science
Standards: For states, by states. Washington, DC: National Academies Press.
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