Making Sense of Sound

Autor/inn/en	Menon, Deepika; Lankford, Deanna
Titel	Making Sense of Sound
Quelle	In: Science and Children, 54 (2016) 4, S.41-47 (7 Seiten) PDF als Volltext Verfügbarkeit
Sprache	englisch
Dokumenttyp	gedruckt; online; Zeitschriftenaufsatz
ISSN	0036-8148
Schlagwörter	Science Instruction; Elementary School Science; Grade 4; Acoustics; Scientific Principles; Inquiry; Science Activities; Models; Energy + Suchen Sie Ihr Suchwort? Teaching of science; Science education; Natural sciences Lessons; Naturwissenschaftlicher Unterricht; School year 04; 4. Schuljahr; Schuljahr 04; Akustik; Analogiemodell; Energie
Abstract	From the earliest days of their lives, children are exposed to all kinds of sound, from soft, comforting voices to the frightening rumble of thunder. Consequently, children develop their own naïve explanations largely based upon their experiences with phenomena encountered every day. When new information does not support existing conceptions, explanations are refashioned to agree with prior experiences, often resulting in misconceptions. Science education literature identifies multiple misconceptions related to sound commonly held by elementary students, including: Sound can only travel through air and not through solids and liquids; sound can travel through a vacuum, such as space; sound can be produced without using any materials; and hitting an object harder changes the pitch of the sound produced. Inquiry-based activities challenge students to question their own conceptions and build new conceptual understanding in light of new evidence. The authors designed a 5E (Bybee 1997) inquiry-based lesson to engage fourth graders in an exploration of sound, focusing specifically on sound as a mechanical wave. Performance expectations from the "Next Generation Science Standards" ("NGSS") specifically indicate that students should be engaged in scientific practices such as modeling to support learning. Drawing upon "NGSS" performance expectation 4-PS4-1, the authors used physical and technological models to: (1) demonstrate that sound is a form of energy associated with vibration of matter and can cause other objects to move; and (2) describe sound wave patterns in terms of amplitude and wavelength. The physical and technological models described could be further extended to illustrate energy transfer through sound (4-PS3-2). (ERIC).
Anmerkungen	National Science Teachers Association. 1840 Wilson Boulevard, Arlington, VA 22201-3000. Tel: 800-722-6782; Fax: 703-243-3924; e-mail: membership@nsta.org; Web site: http://www.nsta.org
Erfasst von	ERIC (Education Resources Information Center), Washington, DC
Update	2020/1/01