Scientific misconceptions are commonly held

beliefs A belief is an attitude that something is the case, or that some proposition is true. In epistemology, philosophers use the term "belief" to refer to attitudes about the world which can be either true or false. To believe something is to take i ...

about science that have no basis in actual

scientific fact A fact is a datum about one or more aspects of a circumstance, which, if accepted as true and proven true, allows a logical conclusion to be reached on a true–false evaluation. Standard reference works are often used to check facts. Scient ...

. Scientific misconceptions can also refer to preconceived notions based on religious and/or cultural influences. Many scientific misconceptions occur because of faulty teaching styles and the sometimes distancing nature of true scientific texts. Because students' prior knowledge and misconceptions are important factors for learning science, science teachers should be able to identify and address these conceptions.

Types

Misconceptions (a.k.a. alternative conceptions, alternative frameworks, etc.) are a key issue from

constructivism in science education Constructivism (philosophy of education), Constructivism has been considered as a Paradigm, dominant paradigm, or research programme, in the field of science education since the 1980s. The term constructivism is widely used in many fields, and not ...

, a major theoretical perspective informing science teaching. In general, scientific misconceptions have their foundations in a few "

intuitive Intuition is the ability to acquire knowledge without recourse to conscious reasoning. Different fields use the word "intuition" in very different ways, including but not limited to: direct access to unconscious knowledge; unconscious cognition; ...

knowledge domains, including folkmechanics (object boundaries and movements), folkbiology (biological species' configurations and relationships), and folkpsychology (interactive agents and goal-directed behavior)", that enable humans to interact effectively with the world in which they evolved. That these folksciences do not map accurately onto modern scientific theory is not unexpected. A second major source of scientific misconceptions are didaskalogenic misconceptions, which are induced and reinforced during the course of instruction (in

formal education Education is a purposeful activity directed at achieving certain aims, such as transmitting knowledge or fostering skills and character traits. These aims may include the development of understanding, rationality, kindness, and honesty. Vari ...

). There has been extensive research into students' informal ideas about science topics, and studies have suggested reported misconceptions vary considerably in terms of properties such as coherence, stability, context-dependence, range of application etc. Misconceptions can be broken down into five basic categories: # preconceived notions # nonscientific beliefs # conceptual misunderstandings # vernacular misconceptions # factual misconceptions Preconceived notions are thinking about a concept in only one way. Specially heat, gravity, and energy. Once a person knows how something works it is difficult to imagine it working a different way. Nonscientific beliefs are beliefs learned outside of scientific evidence. For example, one's beliefs about the history of world based on the bible. Conceptual misunderstandings are ideas about what one thinks they understand based on their personal experiences or what they may have heard. One does not fully grasp the concept and understand it. Vernacular misconceptions happen when one word has two completely different meanings, specially in regard to science and everyday life. Factual misconceptions are ideas or beliefs that are learned at a young age but are actually incorrect. While most student misconceptions go unrecognized, there has been an informal effort to identify errors and misconceptions present in textbooks.

Identifying student misconceptions

In the context of Socratic instruction, student misconceptions are identified and addressed through a process of questioning and listening. A number of strategies have been employed to understand what students are thinking prior, or in response, to instruction. These strategies include various forms of "real type" feedback, which can involve the use of colored cards or electronic survey systems (clickers). Another approach is typified by the strategy known as

just-in-time teaching Just-in-time teaching (often abbreviated as JiTT) is a pedagogical strategy that uses feedback between classroom activities and work that students do at home, in preparation for the classroom meeting. The goals are to increase learning during clas ...

. Here students are asked various questions prior to class, the instructor uses these responses to adapt his or her teaching to the students' prior knowledge and misconceptions. Finally, there is a more research-intensive approach that involves interviewing students for the purpose of generating the items that will make up a

concept inventory A concept inventory is a criterion-referenced test designed to help determine whether a student has an accurate working knowledge of a specific set of concepts. Historically, concept inventories have been in the form of multiple-choice tests in ord ...

or other forms of diagnostic instruments. Concept inventories require intensive validation efforts. Perhaps the most influential of these concept inventories to date has been the Force Concept Inventory (FCI). Concept inventories can be particularly helpful in identifying difficult ideas that serve as a barrier to effective instruction. Concept inventories in natural selection and basic biology have been developed. While not all the published diagnostic instruments have been developed as carefully as some concept inventories, some two-tier diagnostic instruments (which offer multiple choice distractors informed by misconceptions research, and then ask learners to give reasons for their choices) have been through rigorous development. In identifying students' misconceptions, first teachers can identify their preconceptions. "Teachers need to know students' initial and developing conceptions. Students need to have their initial ideas brought to a conscious level." However, teachers' ability to diagnose misconceptions needs to be improved. When confronted with misconceptions about evolution, they only diagnose approximately half of these misconceptions.

Addressing student misconceptions

A number of lines of evidence suggest that the recognition and revision of student misconceptions involves active, rather than passive, involvement with the material. A common approach to instruction involves meta-cognition, that is to encourage students to think about their thinking about a particular problem. In part this approach requires students to verbalize, defend and reformulate their understanding. Recognizing the realities of the modern classroom, a number of variations have been introduced. These include

Eric Mazur Eric Mazur (born November 14, 1954) is a physicist and educator at Harvard University, and an entrepreneur in technology start-ups for the educational and technology markets. Mazur's research is in experimental ultrafast optics, condensed matter p ...

's peer instruction, as well as various tutorials in physics. Scientific inquiry is another technique that provides an active engagement opportunity for students and incorporates metacognition and critical thinking. Success with inquiry-based learning activities relies on a deep foundation of factual knowledge. Students then use observation, imagination, and

reasoning Reason is the capacity of consciously applying logic by drawing conclusions from new or existing information, with the aim of seeking the truth. It is closely associated with such characteristically human activities as philosophy, science, lang ...

about scientific phenomena they are studying to organize knowledge within a conceptual framework.Bransford , J. D., Brown, A. L., & Cocking, R. R. (2000). '' How people learn: Brain, mind, experience, and school''. (Expanded ed.
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. Washington D.C.: National Academy Press, .Bransford, J.D.& Donovan, M.S. (Eds).(2005). "Scientific Inquiry and How People Learn". How Students Learn: History, Mathematics and Science in the Classroom. Washington, D.C.: The National Academies Press. The teacher monitors the changing concepts of the students through formative assessment as the instruction proceeds. Beginning inquiry activities should develop from simple concrete examples to more abstract. As students progress through inquiry, opportunities should be included for students to generate, ask, and discuss challenging questions. According to Magnusson and Palincsan, teachers should allow multiple cycles of investigation where students can ask the same questions as their understanding of the concept matures. Through strategies that apply formative assessment of student learning and adjust accordingly, teachers can help redirect scientific misconceptions. Research has shown that science teachers have a wide repertoire to deal with misconceptions and report a variety of ways to respond to students' alternative conceptions, e.g., attempting to induce a cognitive conflict using analogies, requesting an elaboration of the conception, referencing specific flaws in reasoning, or offering a parallel between the student's conception and a historical theory. However, approximately half of the teachers do not address students' misconceptions, but instead agree with them, respond scientifically incorrect, or formulate the correct scientific explanation themselves without addressing the specific student conception.

Footnotes

References

*Barker, V. 2004
Beyond appearances : students' misconceptions about basic chemical ideas
2nd edition (accessed on-line 9 Sept. 2008) *Charles, E.S. & S.T. d'Apollonia. 2003. A systems approach to education. PEREA report. * * * *{{cite journal , author1=Visscher PM , author2=Hill WG , author3=Wray NR , title=Heritability in the genomics era--concepts and misconceptions , journal=Nature Reviews Genetics , volume=9 , issue=4 , pages=255–66 , date=Apr 2008 , pmid=18319743 , doi=10.1038/nrg2322 , s2cid=690431
How Students Learn
2005. A National Academy of Sciences Report. *Fuchs, T.T., & Arsenault, M. (2017). Using test data to find misconceptions in secondary science. School Science Review 364(98) 31-36. Science education Misconceptions

Types

Identifying student misconceptions

Addressing student misconceptions

See also

Footnotes

References