Top

Journal of Science Education and Technology

Published in:

01-04-2013

Investigating Students’ Understanding of the Dissolving Process

Authors: Basil M. Naah, Michael J. Sanger

Published in: Journal of Science Education and Technology | Issue 2/2013

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

In a previous study, the authors identified several student misconceptions regarding the process of dissolving ionic compounds in water. The present study used multiple-choice questions whose distractors were derived from these misconceptions to assess students’ understanding of the dissolving process at the symbolic and particulate levels. The symbolic-level questions were based on balanced equations, and the particulate-level questions used multiple-choice questions involving dynamic animations or static pictures. This paper analyzes students’ responses to these questions to look for associations among four variables—Answer (the correct answer and three misconceptions), Representation (symbolic or particulate question), Visualization (static or animated pictures), and Representation Order (symbolic questions before or after the particulate questions). The results indicate that the correct answer and the acid–base misconception were more popular than the ion-pair or subscript error misconceptions, the ion-pair misconception was more popular for the particulate questions than the symbolic questions, and that participants were more likely to select the correct answer when viewing static particulate questions compared to animated particulate questions, especially if the particulate questions are seen first. These results suggest that the animated motion of dissolving these compounds in water may be distracting for students.

next article Improving Pre-service Elementary Teachers’ Education via a Laboratory Course on Air Pollution: One University’s Experience

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Ardac D, Akaygun S (2005) Using static and dynamic visuals to represent chemical change at the molecular level. Int J Sci Educ 27:1269–1298CrossRef

Baddeley A (1986) Working memory. Oxford University Press, Oxford

Baddeley A (1999) Human memory. Allyn and Bacon, Boston

Barke HD, Hazari A, Yibarek S (2009) Misconceptions in chemistry: addressing perceptions in chemical education. Springer, Berlin

Blakely AW (2011) Using topic order to reinforce student algebra skills in a community college chemistry course. J Chem Educ 88:858–859CrossRef

Bodner GM, Domin DS (2000) Mental models: the role of representation in problem solving in chemistry. Univ Chem Educ 4:23–30

Boo HK (1998) Students’ understandings of chemical bonds and the energetics of chemical reactions. J Res Sci Teach 35:569–581CrossRef

Burke KA, Greenbowe TJ, Windschitl MA (1998) Developing and using conceptual computer animations for chemistry instruction. J Chem Educ 75:1658–1661CrossRef

Butts B, Smith R (1987) HSC chemistry students’ understanding of the structure and properties of molecular and ionic compounds. Res Sci Educ 17:192–201CrossRef

Carlson R, Chandler P, Sweller J (2003) Learning and understanding science instructional material. J Educ Psych 95:629–640CrossRef

Chandrasegaran AL, Treagust DF, Mocerino M (2007) The development of a two-tier multiple-choice diagnostic instrument for evaluating secondary school students’ ability to describe and explain chemical reactions using multiple levels of representation. Chem Educ Res Pract 8:293–307CrossRef

Chittleborough G, Treagust DF (2007) The modeling ability of non-major chemistry students and their understanding of the sub-microscopic level. Chem Educ Res Pract 8:274–292CrossRef

Cramer D (2003) Advanced quantitative data analysis. Open University Press, Maidenhead

Ebenezer JV (2001) A hypermedia environment to explore and negotiate students’ conceptions: animation of the solution process of table salt. J Sci Educ Technol 10:73–92CrossRef

Ebenezer JV, Erickson GL (1996) Chemistry students’ conceptions of solubility: a phenomenography. Sci Educ 80:181–201CrossRef

Foster JK, Barkus E, Yavorsky C (2006) Understanding and using advanced statistics. Sage, London

Gilbert JK, Treagust DF (2009) Towards a coherent model for macro, submicro, and symbolic representations in chemical education. In: Gilbert JK, Treagust DF (eds) Models and modeling in science education, volume 4: multiple representations in chemical education. Springer, DordrechtCrossRef

Gregorius RMa, Santos R, Dano JB, Gutierrez JJ (2010a) Can animations effectively substitute for traditional teaching methods? Part I: preparation and testing of materials. Chem Educ Res Pract 11:253–261CrossRef

Gregorius RMa, Santos R, Dano JB, Gutierrez JJ (2010b) Can animations effectively substitute for traditional teaching methods? Part II: potential for differentiated learning. Chem Educ Res Pract 11:262–266CrossRef

Harp SF, Mayer RE (1998) How seductive details do their damage: a theory of cognitive interest in science learning. J Educ Psych 90:414–434CrossRef

Hilton A, Nichols K (2011) Representational classroom practices that contribute to students’ conceptual and representational understanding of chemical bonding. Int J Sci Educ 33:2215–2246CrossRef

Johnstone AH (1993) The development of chemistry teaching. J Chem Educ 70:701–704CrossRef

Johnstone AH (2010) You can’t get there from here. J Chem Educ 87:22–29CrossRef

Kabapinar F, Leach J, Scott P (2004) The design and evaluation of a teaching-learning sequence addressing the solubility concept with Turkish secondary school students. Int J Sci Educ 26:635–652CrossRef

Kelly RM, Jones LL (2007) Exploring how different features of animations of sodium chloride dissolution affect students’ explanations. J Sci Educ Technol 16:413–429CrossRef

Kelly RM, Jones LL (2008) Investigating students’ ability to transfer ideas learned from molecular animations to the dissolution process. J Chem Educ 85:303–309CrossRef

Kelly RM, Phelps AJ, Sanger MJ (2004) The effects of a computer animation on students’ conceptual understanding of a can-crushing demonstration at the macroscopic, microscopic, and symbolic levels. Chem Educ 9:184–189

Kozma RB, Russell J (1997) Multimedia and understanding: expert and novice responses to different representations of chemical phenomena. J Res Sci Teach 34:949–968CrossRef

Kozma RB, Russell JW, Jones T, Wykoff J, Marx N, Davis J (1997) Use of simultaneous-synchronized macroscopic, microscopic, and symbolic representations to enhance the teaching and learning of chemical concepts. J Chem Educ 74:330–334CrossRef

Kraft A, Strickland AM, Bhattacharyya G (2010) Reasonable reasoning: multi-variate problem-solving in organic chemistry. Chem Educ Res Pract 11:281–292CrossRef

Liu X, Lesniak K (2006) Progression in children’s understanding of the matter concept from elementary to high school. J Res Sci Teach 43:320–347CrossRef

Madden SP, Jones LL, Rahm J (2011) The role of multiple representations in the understanding of ideal gas problems. Chem Educ Res Pract 12:283–293CrossRef

Mayer RE (2001) Multimedia learning. Cambridge University Press, CambridgeCrossRef

Mayer RE, Bove W, Bryman A, Mars R, Topangco L (1996) When less is more: meaningful learning from visual and verbal summaries of science textbook lessons. J Educ Psych 88:64–73CrossRef

Mayer RE, Heiser J, Lonn S (2001) Cognitive constraints on multimedia learning: when presenting more material results in less understanding. J Educ Psych 93:187–198CrossRef

Moreno R, Mayer RE (2000) A coherence effect in multimedia learning: the case for minimizing irrelevant sounds in the design of multimedia instructional messages. J Educ Psych 92:117–125CrossRef

Naah BM, Sanger MJ (2012) Student misconceptions in writing balanced equations for dissolving ionic compounds in water. Chem Educ Res Pract. doi: 10.1039/c2rp00015f

Nyachwaya JM, Mohamed A-R, Roehrig GH, Wood NB, Kern AL, Schneider JL (2011) The development of an open-ended drawing tool: an alternative diagnostic tool for assessing students’ understanding of the particulate nature of matter. Chem Educ Res Pract 12:121–132CrossRef

Paas F, van Gog T, Sweller J (2010) Cognitive load theory: new conceptualizations, specifications, and integrated research perspectives. Educ Psych Rev 22:115–121CrossRef

Paivio A (1986) Mental representation: a dual coding approach. New York, Oxford

Rieber LP (1989) A review of animation research in computer-based instruction. Paper presented at the annual convention of the association for educational communications and technology, Dallas TX

Rosenthal DP, Sanger MJ (2012) Student misconceptions/misinterpretations of two computer animations of varying complexity depicting the same oxidation-reduction reaction. Chem Educ Res Pract manuscript under review

Sande ME (2010) Pedagogical content knowledge and the gas laws: a multiple case study. PhD Dissertation, University of Minnesota

Sanger MJ (2009) Computer animations of chemical processes at the molecular level. In: Pienta NJ, Cooper MM, Greenbowe TJ (eds) Chemists’ guide to effective teaching, vol II. Prentice Hall, Upper Saddle River, pp 198–211

Sanger MJ, Greenbowe TJ (2000) Addressing student misconceptions concerning electron flow in aqueous solutions with instruction including computer animations and conceptual change strategies. Int J Sci Educ 22:521–537CrossRef

Sanger MJ, Phelps AJ, Fienhold J (2000) Using a computer animation to improve students’ conceptual understanding of a can-crushing demonstration. J Chem Educ 77:1517–1520CrossRef

Sanger MJ, Brecheisen DM, Hynek BM (2001) Can computer animations affect college biology students’ conceptions about diffusion and osmosis? Am Biol Teach 63:104–109CrossRef

Sanger MJ, Campbell E, Felker J, Spencer C (2007) Concept learning versus problem solving: does particle motion have an effect? J Chem Educ 84:875–879CrossRef

Smith KJ, Metz PA (1996) Evaluating student understanding of solution chemistry through microscopic representations. J Chem Educ 73:233–235CrossRef

Smith KC, Nakhleh MB (2011) University students’ conceptions of bonding in melting and dissolving phenomena. Chem Educ Res Pract 12:398–408CrossRef

Stieff M, Hegarty M, Deslongchamps G (2011) Identifying representational competence with multi-representational displays. Cogn Instr 29:123–145CrossRef

Strickland AM, Kraft A, Bhattacharyya G (2010) What happens when representations fail to represent? Graduate students’ mental models of organic chemistry diagrams. Chem Educ Res Pract 11:293–301CrossRef

Sweller J (2008) Cognitive load theory and the use of educational technology. Educ Technol 48:32–35

Tabachnick BG, Fidell LS (1996) Using multivariate analysis, 3rd edn. Harper Collins, New York, pp 239–319

Taber KS (1994) Misunderstanding the ionic bond. Educ Chem 31:100–103

Taber KS (1997) Student understanding of ionic bonding: molecular versus electrostatic framework? Sch Sci Rev 78:85–95

Talanquer V (2011) Macro, submicro, and symbolic: the many faces of the chemistry “triplet”. Sci Educ 33:179–195CrossRef

Tellinghuisen J, Sulikowski MM (2008) Does the answer order matter on multiple-choice exams? J Chem Educ 85:572–575CrossRef

Tien LT, Teichert MA, Rickey D (2007) Effectiveness of a MORE laboratory module in prompting students to revise their molecular-level ideas about solutions. J Chem Educ 84:239–319CrossRef

Velázquez-Marcano A, Williamson VM, Ashkenazi G, Tasker R, Williamson KC (2004) The use of video demonstrations and particulate animation in general chemistry. J Sci Educ Technol 13:315–323CrossRef

Wilder A, Brinkerhoff J (2007) Supporting representational competence in high school biology with computer-based biomolecular visualizations. J Comp Math Sci Teach 26:5–26

Williamson VM, Abraham MR (1995) The effects of computer animation on the particulate mental models of college chemistry students. J Res Sci Teach 32:521–534CrossRef

Title: Investigating Students’ Understanding of the Dissolving Process
Authors: Basil M. Naah
Michael J. Sanger
Publication date: 01-04-2013
Publisher: Springer Netherlands
Published in: Journal of Science Education and Technology / Issue 2/2013
Print ISSN: 1059-0145
Electronic ISSN: 1573-1839
DOI: https://doi.org/10.1007/s10956-012-9379-7

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 2/2013

Teachers’ Concerns About Biotechnology Education

Effectiveness of Podcasts Delivered on Mobile Devices as a Support for Student Learning During General Chemistry Laboratories

The Effectiveness of Concept Maps in Teaching Physics Concepts Applied to Engineering Education: Experimental Comparison of the Amount of Learning Achieved With and Without Concept Maps

Technology-supported Learning in Secondary and Undergraduate Biological Education: Observations from Literature Review

Practicality in Virtuality: Finding Student Meaning in Video Game Education

Effects of Jigsaw Cooperative Learning and Animation Techniques on Students’ Understanding of Chemical Bonding and Their Conceptions of the Particulate Nature of Matter

Premium Partners