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Wikipedia

Inquiry-based learning

November 25, 2023

Inquiry-based learning (also spelled as enquiry-based learning in British English)[a] is a form of active learning that starts by posing questions, problems or scenarios. It contrasts with traditional education, which generally relies on the teacher presenting facts and their knowledge about the subject. Inquiry-based learning is often assisted by a facilitator rather than a lecturer. Inquirers will identify and research issues and questions to develop knowledge or solutions. Inquiry-based learning includes problem-based learning, and is generally used in small-scale investigations and projects, as well as research.[2] The inquiry-based instruction is principally very closely related to the development and practice of thinking and problem-solving skills.[3]

History edit

Inquiry-based learning is primarily a pedagogical method, developed during the discovery learning movement of the 1960s as a response to traditional forms of instruction—where people were required to memorize information from instructional materials,[4] such as direct instruction and rote learning. The philosophy of inquiry based learning finds its antecedents in constructivist learning theories, such as the work of Piaget, Dewey, Vygotsky, and Freire among others,[5][6][7] and can be considered a constructivist philosophy. Generating information and making meaning of it based on personal or societal experience is referred to as constructivism.[8] Dewey's experiential learning pedagogy (that is, learning through experiences) comprises the learner actively participating in personal or authentic experiences to make meaning from it.[9][10] Inquiry can be conducted through experiential learning because inquiry values the same concepts, which include engaging with the content/material in questioning, as well as investigating and collaborating to make meaning. Vygotsky approached constructivism as learning from an experience that is influenced by society and the facilitator. The meaning constructed from an experience can be concluded as an individual or within a group.[8][9]

In the 1960s Joseph Schwab called for inquiry to be divided into three distinct levels.[11] This was later formalized by Marshall Herron in 1971, who developed the Herron Scale to evaluate the amount of inquiry within a particular lab exercise.[12] Since then, there have been a number of revisions proposed and inquiry can take various forms. There is a spectrum of inquiry-based teaching methods available.[13]

Inquiry learning has been used as a teaching and learning tool for thousands of years, however, the use of inquiry within public education has a much briefer history.[14] Ancient Greek and Roman educational philosophies focused much more on the art of agricultural and domestic skills for the middle class and oratory for the wealthy upper class. It was not until the Enlightenment, or the Age of Reason, during the late 17th and 18th century that the subject of Science was considered a respectable academic body of knowledge.[15] Up until the 1900s the study of science within education had a primary focus on memorizing and organizing facts.

John Dewey, a well-known philosopher of education at the beginning of the 20th century, was the first to criticize the fact that science education was not taught in a way to develop young scientific thinkers. Dewey proposed that science should be taught as a process and way of thinking – not as a subject with facts to be memorized.[14] While Dewey was the first to draw attention to this issue, much of the reform within science education followed the lifelong work and efforts of Joseph Schwab. Joseph Schwab was an educator who proposed that science did not need to be a process for identifying stable truths about the world that we live in, but rather science could be a flexible and multi-directional inquiry driven process of thinking and learning. Schwab believed that science in the classroom should more closely reflect the work of practicing scientists. Schwab developed three levels of open inquiry that align with the breakdown of inquiry processes that we see today.[16]

  1. Students are provided with questions, methods and materials and are challenged to discover relationships between variables
  2. Students are provided with a question, however, the method for research is up to the students to develop
  3. Phenomena are proposed but students must develop their own questions and method for research to discover relationships among variables

Today, we know that students at all levels of education can successfully experience and develop deeper level thinking skills through scientific inquiry.[17] The graduated levels of scientific inquiry outlined by Schwab demonstrate that students need to develop thinking skills and strategies prior to being exposed to higher levels of inquiry.[16] Effectively, these skills need to be scaffolded by the teacher or instructor until students are able to develop questions, methods, and conclusions on their own.[18]

Characteristics edit

 
Example of problem/project based learning versus reading cover to cover. The problem/project based learner may memorize a smaller amount of total information due to spending time searching for the optimal information across various sources, but will likely learn more useful items for real world scenarios, and will likely be better at knowing where to find information when needed.[19]

Specific learning processes that people engage in during inquiry-learning include:[20][21]

  • Creating questions of their own
  • Obtaining supporting evidence to answer the question(s)
  • Explaining the evidence collected
  • Connecting the explanation to the knowledge obtained from the investigative process
  • Creating an argument and justification for the explanation

Inquiry learning involves developing questions, making observations, doing research to find out what information is already recorded, developing methods for experiments, developing instruments for data collection, collecting, analyzing, and interpreting data, outlining possible explanations and creating predictions for future study.[22]

Levels edit

There are many different explanations for inquiry teaching and learning and the various levels of inquiry that can exist within those contexts. The article titled The Many Levels of Inquiry by Heather Banchi and Randy Bell (2008)[23] clearly outlines four levels of inquiry.

Level 1: Confirmation Inquiry
The teacher has taught a particular science theme or topic. The teacher then develops questions and a procedure that guides students through an activity where the results are already known. This method is great to reinforce concepts taught and to introduce students into learning to follow procedures, collect and record data correctly and to confirm and deepen understandings.

Level 2: Structured Inquiry
The teacher provides the initial question and an outline of the procedure. Students are to formulate explanations of their findings through evaluating and analyzing the data that they collect.

Level 3: Guided Inquiry
The teacher provides only the research question for the students. The students are responsible for designing and following their own procedures to test that question and then communicate their results and findings.

Level 4: Open/True Inquiry
Students formulate their own research question(s), design and follow through with a developed procedure, and communicate their findings and results. This type of inquiry is often seen in science fair contexts where students drive their own investigative questions.

Banchi and Bell (2008) explain that teachers should begin their inquiry instruction at the lower levels and work their way to open inquiry in order to effectively develop students' inquiry skills. Open inquiry activities are only successful if students are motivated by intrinsic interests and if they are equipped with the skills to conduct their own research study.[24]

Open/true inquiry learning edit

An important aspect of inquiry-based learning is the use of open learning, as evidence suggests that only utilizing lower level inquiry is not enough to develop critical and scientific thinking to the full potential.[25][26][27] Open learning has no prescribed target or result that people have to achieve. There is an emphasis on the individual manipulating information and creating meaning from a set of given materials or circumstances.[28] In many conventional and structured learning environments, people are told what the outcome is expected to be, and then they are simply expected to 'confirm' or show evidence that this is the case.

Open learning has many benefits.[27] It means students do not simply perform experiments in a routine like fashion, but actually think about the results they collect and what they mean. With traditional non-open lessons there is a tendency for students to say that the experiment 'went wrong' when they collect results contrary to what they are told to expect. In open learning there are no wrong results, and students have to evaluate the strengths and weaknesses of the results they collect themselves and decide their value.

Open learning has been developed by a number of science educators including the American John Dewey and the German Martin Wagenschein.[b] Wagenschein's ideas particularly complement both open learning and inquiry-based learning in teaching work. He emphasized that students should not be taught bald facts, but should understand and explain what they are learning. His most famous example of this was when he asked physics students to tell him what the speed of a falling object was. Nearly all students would produce an equation, but no students could explain what this equation meant.[citation needed] Wagenschein used this example to show the importance of understanding over knowledge.[30]

Although both guided and open/true inquiry were found to promote science literacy and interest, each has its own advantages. While open/true inquiry may contribute to students' initiative, flexibility and adaptability better than guided inquiry in the long run,[31] some claim that it may lead to high cognitive load and that guided inquiry is more efficient in terms of time and content learning.[32]

Inquisitive learning edit

Sociologist of education Phillip Brown defined inquisitive learning as learning that is intrinsically motivated (e.g. by curiosity and interest in knowledge for its own sake), as opposed to acquisitive learning that is extrinsically motivated (e.g. by acquiring high scores on examinations to earn credentials).[33][34][35] However, occasionally the term inquisitive learning is simply used as a synonym for inquiry-based learning.[36][37]

Inquiry-based learning in academic disciplines edit

Science education edit

History edit

A catalyst for reform within North American science education was the 1957 launch of Sputnik, the Soviet Union satellite. This historical scientific breakthrough caused a great deal of concern around the science and technology education the American students were receiving. In 1958 the U.S. congress developed and passed the National Defense Education Act in order to provide math and science teachers with adequate teaching materials.[22][38]

Science standards edit

America's Next Generation Science Standards (NGSS) embrace student centered inquiry-based pedagogy by implementing a three-part approach to science education: Disciplinary Core Ideas (DCIs), Science and Engineering Practices (SEPs), and Cross Cutting Concepts (CCCs).[39] The standards are designed so that students learn science by performing scientific practices in the classroom. Students use practices such as asking questions, planning and carrying out investigations, collaborating, collecting and analyzing data, and arguing from evidence to learn the core ideas and concepts in scientific content areas. These practices are comparable to the 21st Century Skills that have been shown to be indicators of success in modern societies and workplaces regardless of whether that field is science based.[40]

Pedagogical applications edit

Inquiry-based pedagogy in science education has been shown to increase students' scientific knowledge and literacy when compared to when students are taught using more traditional pedagogical methods.[41][42][43] However, even though students in inquiry-based classrooms are shown to have higher scientific knowledge, they have also been shown to have increased frustration and decreased confidence in scientific ability when compared to their peers taught using traditional methods.[42][44] Research has also shown that while inquiry-based pedagogy has been shown to improve students' science achievement, social contexts must be taken into account. This is because achievement gaps among students may be as likely to widen as they are to decrease due to differences in student readiness for inquiry-based learning based on social and economic status differences. [45]

In cases where students' scientific knowledge in an inquiry based classroom was not significantly different than their peers taught in traditional methods, student problem solving ability was found to be improved for inquiry learning students.[41] Inquiry as a pedagogical framework and learning process fits within many educational models including Problem Based Learning and the 5E Model of Education.

Problem-based learning edit

Inquiry as a pedagogical framework has been shown to be especially effective when used along problem-based learning (PBL) assignments.[41][46][47] As a student-centered strategy, problem-based learning fits well within an inquiry based classroom. Students learn science by performing science: asking questions, designing experiments, collecting data, making claims, and using data to support claims. By creating a culture and community of inquiry in a science classroom, students learn science by working collaboratively with their peers to investigate the world around them and ways to solve problems affecting their communities.[47] Students confronted with real world problems that affect their everyday lives are shown to have increased engagement and feel more encouraged to solve the problems posed to them.[47]

5E Model of Science Education edit

The 5E Model of Science Education is a planning structure that helps science teachers develop student centered inquiry-based lessons and units. In the 5E model, students learn science by exploring their questions using the same approach scientists explore their questions. By using this approach, science teachers help their students connect scientific content learned in the classroom with phenomena from their own lives and apply that learning to new areas, in science and beyond. [48]

The 5E Model is broken into the following sections which may repeat and occur at various stages of the learning process.

  • Engage: This is generally considered to be the opening stage of the 5E Model and is used to inspire student curiosity and should help students connect new phenomena to prior learning. This stage of the 5E model also aims to identify student misconceptions that need to be addressed through the lessons designed by the teacher. [48]
  • Explore: In this stage, students investigate the phenomena observed during the engage stage and answer any questions they have generated based on their observations. The level of inquiry (i.e. fully open vs. guided) may vary based on the level, age, and readiness of students [43][44][49][48]
  • Explain: In this stage, the teacher helps students piece together the information they gathered during the explore stage. Again, the level of direct teacher instruction and explanation may vary based on the level, age, and readiness of students. [43][44][49][48]
  • Elaborate/Expand: This stage determines if students are truly able to apply the information they've learned to new areas and to the solution of real world problems. [48]
  • Evaluate: In this stage students evaluate their own learning and the teacher evaluates student understanding and ability to apply knowledge to multiple areas. [48]

Collaboration and communication edit

Effective collaboration and communication is an integral part of scientists' and engineers' everyday lives and their importance is reflected in the representation of these skills in the science and engineering practices of the Next Generation Science Standards. Inquiry education supports these skills, especially when students take part in a community of inquiry.[43][47] Students who are actively collaborating and communicating in an inquiry based science class exhibit and develop many of these skills.[46][47][43][41] Specifically, these students:

  • make observations and ask questions with their peers
  • work with peers to design solutions to problems
  • analyze claims of their peers
  • argue from evidence
  • support their peers' growth and search for knowledge

Social studies and history edit

The College, Career, and Civic Life (C3) Framework for Social Studies State Standards was a joint collaboration among states and social studies organizations, including the National Council for the Social Studies,[50] designed to focus social studies education on the practice of inquiry, emphasizing "the disciplinary concepts and practices that support students as they develop the capacity to know, analyze, explain, and argue about interdisciplinary challenges in our social world."[50] The C3 Framework recommends an "Inquiry Arc" incorporating four dimensions: 1. developing questions and planning inquiries; 2. applying disciplinary concepts and tools; 3. evaluating primary sources and using evidence; and 4. communicating conclusions and taking informed action.[50] For example, a theme for this approach could be an exploration of etiquette today and in the past. Students might formulate their own questions or begin with an essential question such as "Why are men and women expected to follow different codes of etiquette?" Students explore change and continuity of manners over time and the perspectives of different cultures and groups of people. They analyze primary source documents such as books of etiquette from different time periods and form conclusions that answer the inquiry questions. Students finally communicate their conclusions in formal essays or creative projects. They may also take action by recommending solutions for improving school climate.[51]

Robert Bain in How Students Learn described a similar approach called "problematizing history".[52] First a learning curriculum is organized around central concepts. Next, a question and primary sources are provided, such as eyewitness historical accounts. The task for inquiry is to create an interpretation of history that will answer the central question. Students will form a hypothesis, collect and consider information and revisit their hypothesis as they evaluate their data.

Ontario's kindergarten program edit

After Charles Pascal's report in 2009, the Canadian province of Ontario's Ministry of Education decided to implement a full day kindergarten program that focuses on inquiry and play-based learning, called The Early Learning Kindergarten Program.[53] As of September 2014, all primary schools in Ontario started the program. The curriculum document[54] outlines the philosophy, definitions, process and core learning concepts for the program. Bronfenbrenner's ecological model, Vygotsky's zone of proximal development, Piaget's child development theory and Dewey's experiential learning are the heart of the program's design. As research shows, children learn best through play, whether it is independently or in a group. Three forms of play are noted in the curriculum document, pretend or "pretense" play, socio-dramatic play and constructive play. Through play and authentic experiences, children interact with their environment (people and/or objects) and question things; thus leading to inquiry learning. A chart on page 15 clearly outlines the process of inquiry for young children, including initial engagement, exploration, investigation, and communication.[54] The new program supports holistic approach to learning. For further details, please see the curriculum document.[54]

Since the program is extremely new[as of?], there is limited research on its success and areas of improvement. One government research report was released with the initial groups of children in the new kindergarten program. The Final Report: Evaluation of the Implementation of the Ontario Full-Day Early-Learning Kindergarten Program from Vanderlee, Youmans, Peters, and Eastabrook (2012) conclude with primary research that high-need children improved more compared to children who did not attend Ontario's new kindergarten program.[55] As with inquiry-based learning in all divisions and subject areas, longitudinal research is needed to examine the full extent of this teaching/learning method.

Learning to read in the Netherlands edit

Since 2013, Dutch children have participated in a curriculum of learning to read through an inquiry-based pedagogical program. The program, from the Dutch developmental psychologist Ewald Vervaet, is named Ontdekkend Leren Lezen (OLL; 'Discovery Learning to Read') and has three parts.[56] As of 2019, OLL is only available in Dutch.

OLL's main characteristic is that it is for children who are reading mature. Reading maturity is assessed with the Reading Maturity Test. It is a descriptive test that consists of two subtests.[57]

Misconceptions edit

There are several common misconceptions regarding inquiry-based science, the first being that inquiry science is simply instruction that teaches students to follow the scientific method. Many teachers had the opportunity to work within the constraints of the scientific method as students themselves and assume inquiry learning must be the same. Inquiry science is not just about solving problems in six simple steps but much more broadly focused on the intellectual problem-solving skills developed throughout a scientific process.[17] Additionally, not every hands-on lesson can be considered inquiry.

Some educators believe that there is only one true method of inquiry, which would be described as the level four: Open Inquiry. While open inquiry may be the most authentic form of inquiry, there are many skills and a level of conceptual understanding that the students must have developed before they can be successful at this high level of inquiry.[18] While inquiry-based science is considered to be a teaching strategy that fosters higher order thinking in students, it should be one of several methods used. A multifaceted approach to science keeps students engaged and learning.

Not every student is going to learn the same amount from an inquiry lesson; students must be invested in the topic of study to authentically reach the set learning goals. Teachers must be prepared to ask students questions to probe their thinking processes in order to assess accurately. Inquiry-science requires a lot of time, effort, and expertise, however, the benefits outweigh the cost when true authentic learning can take place[citation needed].

Neuroscience complexity edit

The literature states that inquiry requires multiple cognitive processes and variables, such as causality and co-occurrence that enrich with age and experience.[58][59] Kuhn, et al. (2000) used explicit training workshops to teach children in grades six to eight in the United States how to inquire through a quantitative study. By completing an inquiry-based task at the end of the study, the participants demonstrated enhanced mental models by applying different inquiry strategies.[58] In a similar study, Kuhan and Pease (2008) completed a longitudinal quantitative study following a set of American children from grades four to six to investigate the effectiveness of scaffolding strategies for inquiry. Results demonstrated that children benefitted from the scaffolding because they outperformed the grade seven control group on an inquiry task.[59] Understanding the neuroscience of inquiry learning the scaffolding process related to it should be reinforced for Ontario's primary teachers as part of their training.

Necessity for teacher training edit

There is a necessity for professional collaboration when executing a new inquiry program (Chu, 2009; Twigg, 2010). The teacher training and process of using inquiry learning should be a joint mission to ensure the maximal amount of resources are used and that the teachers are producing the best learning scenarios. The scholarly literature supports this notion. Twigg's (2010) education professionals who participated in her experiment emphasized year round professional development sessions, such as workshops, weekly meetings and observations, to ensure inquiry is being implemented in the class correctly.[10] Another example is Chu's (2009) study, where the participants appreciated the professional collaboration of educators, information technicians and librarians to provide more resources and expertise for preparing the structure and resources for the inquiry project.[60] To establish a professional collaboration and researched training methods, administration support is required for funding.

Criticism edit

Kirschner, Sweller, and Clark (2006)[61] review of literature found that although constructivists often cite each other's work, empirical evidence is not often cited. Nonetheless the constructivist movement gained great momentum in the 1990s, because many educators began to write about this philosophy of learning.

Hmelo-Silver, Duncan, & Chinn cite several studies supporting the success of the constructivist problem-based and inquiry learning methods. For example, they describe a project called GenScope, an inquiry-based science software application. Students using the GenScope software showed significant gains over the control groups, with the largest gains shown in students from basic courses.[62]

In contrast, Hmelo-Silver et al. also cite a large study by Geier on the effectiveness of inquiry-based science for middle school students, as demonstrated by their performance on high-stakes standardized tests. The improvement was 14% for the first cohort of students and 13% for the second cohort. This study also found that inquiry-based teaching methods greatly reduced the achievement gap for African-American students.[62]

In a 2006 article, the Thomas B. Fordham Institute's president, Chester E. Finn Jr., was quoted as saying "But like so many things in education, it gets carried to excess... [the approach is] fine to some degree.".[63] The organization ran a study in 2005 concluding that the emphasis states put on inquiry-based learning is too great.[64]

Richard E. Mayer from the University of California, Santa Barbara, wrote in 2004 that there was sufficient research evidence to make any reasonable person skeptical about the benefits of discovery learning—practiced under the guise of cognitive constructivism or social constructivism—as a preferred instructional method. He reviewed research on discovery of problem-solving rules culminating in the 1960s, discovery of conservation strategies culminating in the 1970s, and discovery of LOGO programming strategies culminating in the 1980s. In each case, guided discovery was more effective than pure discovery in helping students learn and transfer.[65]

It should be cautioned that inquiry-based learning takes a lot of planning before implementation. It is not something that can be put into place in the classroom quickly. Measurements must be put in place for how students knowledge and performance will be measured and how standards will be incorporated. The teacher's responsibility during inquiry exercises is to support and facilitate student learning (Bell et al., 769–770). A common mistake teachers make is lacking the vision to see where students' weaknesses lie. According to Bain, teachers cannot assume that students will hold the same assumptions and thinking processes as a professional within that discipline (p. 201).

While some see inquiry-based teaching as increasingly mainstream, it can be perceived as in conflict with standardized testing common in standards-based assessment systems which emphasise the measurement of student knowledge, and meeting of pre-defined criteria, for example the shift towards "fact" in changes to the National Assessment of Educational Progress as a result of the American No Child Left Behind program.[citation needed]

Additional scholarly research literature edit

Chu (2009) used a mixed method design to examine the outcome of an inquiry project completed by students in Hong Kong with the assistance of multiple educators. Chu's (2009) results show that the children were more motivated and academically successful compared to the control group.[60]

Cindy Hmelo-Silver reviewed a number of reports on a variety studies into problem based learning.[66]

Edelson, Gordin and Pea describe five significant challenges to implementing inquiry-based learning and present strategies for addressing them through the design of technology and curriculum. They present a design history covering four generations of software and curriculum to show how these challenges arise in classrooms and how the design strategies respond to them.[67]

See also edit

Notes edit

  1. ^ The UK dictionaries Collins and Longman list the spelling "inquiry" first, and Oxford simply calls it another spelling, without labeling it as US English.[1]
  2. ^ Wagenschein characterized his approach as Socratic, genetic, and example-based.[29][circular reference]

References and further reading edit

  1. ^ "enquiry (noun)". www.oxfordlearnersdictionaries.com. Oxford University Press. Retrieved 2 April 2021.
  2. ^ "What is Inquiry-Based Learning (EBL)?". Centre for Excellence in Enquiry-Based Learning. University of Manchester.
  3. ^ Dostál, J. (2015), Inquiry-based instruction. Concept, essence, importance and contribution, Olomouc: Palacký University, doi:10.5507/pdf.15.24445076, ISBN 978-80-244-4507-6
  4. ^ Bruner, J. S. (1961). "The act of discovery". Harvard Educational Review 31 (1): 21–32.
  5. ^ Dewey, J (1997) How We Think, New York: Dover Publications.
  6. ^ Freire, P. (1984) Pedagogy of the Oppressed, New York: Continuum Publishing Company.
  7. ^ Vygotsky, L.S. (1962) Thought and Language, Cambridge, MA: MIT Press.
  8. ^ a b Bachtold, Manuel (2013). "What do students "construct" according to constructivism in science education?". Research in Science Education. 43 (6): 2477–96. Bibcode:2013RScEd..43.2477B. doi:10.1007/s11165-013-9369-7. S2CID 145256074.
  9. ^ a b Roth, Wolff-Michael; Jornet, Alfredo (2013). "Toward a theory of experience". Science Education. 98 (1): 106–26. Bibcode:2014SciEd..98..106R. doi:10.1002/sce.21085. hdl:10072/67780.
  10. ^ a b Twigg, Vani Veikoso (2010). "Teachers' practices, values and beliefs for successful inquiry-based teaching in the International Baccalaureate Primary years Programme". Journal of Research in International Education. 9 (1): 40–65. doi:10.1177/1475240909356947. S2CID 145639391.
  11. ^ Schwab, J. (Summer 1960). "Inquiry, the Science Teacher, and the Educator". The School Review. The University of Chicago Press. 68 (2): 176–195. doi:10.1086/442536. JSTOR 1083585. S2CID 144897014.
  12. ^ Herron, M.D. (1971). The nature of scientific enquiry. The school review, 79(2), 171–212.
  13. ^ Wilhelm, J. G., & Wilhelm, P. J. (2010). Inquiring minds learn to read, write, and think: Reaching all learners through inquiry. Middle School Journal, May 2010, 39–46.
  14. ^ a b National Research Council. 2000. Inquiry and the National Science Education Standards: A Guide for Teaching and Learning. Washington, DC: National Academy Press.
  15. ^ Murphy, M. (2006). The History and Philosophy of Education: Voices of Educational Pioneers Upper Saddle River, NJ.: Pearson Education, Inc. ISBN 0130955507
  16. ^ a b Schwab, J. 1966. The Teaching of Science. Cambridge, MA: Harvard University Press
  17. ^ a b National Science Education Standards. (1996). National Academy Press. Washington, DC.
  18. ^ a b Ban chi, H., & Bell, R. (2008). The Many Levels of Inquiry. Science and Children, 46(2), 26–29.
  19. ^ Image by Mikael Häggström, MD, using source images by various authors. Source for useful context in problem-based learning: Mark A Albanese, Laura C Dast (22 October 2013). "Understanding Medical Education - Problem-based learning". Wiley Online Library. doi:10.1002/9781118472361.ch5.
  20. ^ Bell, T.; Urhahne, D.; Schanze, S.; Ploetzner, R. (2010). "Collaborative inquiry learning: Models, tools, and challenges". International Journal of Science Education. 3 (1): 349–377. Bibcode:2010IJSEd..32..349B. doi:10.1080/09500690802582241. S2CID 3866279.
  21. ^ "What is inquiry?".
  22. ^ a b National Institute for Health. (2005). Doing Science: The Process of Science Inquiry. http://science.education.nih.gov/supplements/nih6/inquiry/guide/info_process-a.htm
  23. ^ Bell, R., Banchi, H. (2008). The Many Levels of Inquiry. Science & Children, 46(2), 26-29.
  24. ^ Yoon, H.; Joung, Y. J.; Kim, M. (2012). "The challenges of science inquiry teaching for pre-service teachers in elementary classrooms: Difficulties on and under the scene". Research in Science & Technological Education. 42 (3): 589–608. Bibcode:2012RScEd..42..589Y. doi:10.1007/s11165-011-9212-y. S2CID 143969965.
  25. ^ Berg, C A R; Bergendahl, V C B; Lundberg, B K S; Tibell, L A E (2003). "Benefiting from an open-ended experiment? A comparison of attitudes to, and outcomes of, an expository versus an open-inquiry version to the same experiment". International Journal of Science Education. 25 (3): 351–372. Bibcode:2003IJSEd..25..351B. doi:10.1080/09500690210145738. S2CID 143335162.
  26. ^ Yen C F and Hunang S C (2001) Authentic learning about tree frogs by preservice biology teachers in an open-inquiry research settings. Proc. Natl. Sci. Counc. ROC(D) 11, 1–10.
  27. ^ a b Zion, M.; Sadeh, I. (2007). "Curiosity and open inquiry learning". Journal of Biological Education. 41 (4): 162–168. doi:10.1080/00219266.2007.9656092. S2CID 56105131.
  28. ^ Hannafin, M., Land, S., Oliver, K. (1999). Open learning environments: Foundation, methods, and models. In C. M. Reigeluth (Ed.), Instructional-design theories and models. A new paradigm of instructional theory Volume II (pp. 115–140). Mahwah, NJ: Lawrence Erlbaum Associates, Inc.
  29. ^ de:Martin Wagenschein
  30. ^ Dahl, Susan; Franzen, Pat. . Science Lines: A Newsletter from the Teacher Resource Center at Fermilab (Activity). Vol. 9, no. 1, Fall 1997. Archived from the original on 8 September 2008. Retrieved 3 January 2017.
  31. ^ Dorfman, Bat-Shahar; Issachar, Hagit; Zion, Michal (1 February 2020). "Yesterday's Students in Today's World—Open and Guided Inquiry Through the Eyes of Graduated High School Biology Students". Research in Science Education. 50 (1): 123–149. doi:10.1007/s11165-017-9683-6. ISSN 1573-1898. S2CID 254987400.
  32. ^ Bunterm, Tassanee; Lee, Kerry; Ng Lan Kong, Jeremy; Srikoon, Sanit; Vangpoomyai, Penporn; Rattanavongsa, Jareunkwan; Rachahoon, Ganya (13 August 2014). "Do Different Levels of Inquiry Lead to Different Learning Outcomes? A comparison between guided and structured inquiry". International Journal of Science Education. 36 (12): 1937–1959. Bibcode:2014IJSEd..36.1937B. doi:10.1080/09500693.2014.886347. ISSN 0950-0693. S2CID 144105574.
  33. ^ Brown, Phillip (March 2003). "The opportunity trap: education and employment in a global economy". European Educational Research Journal. 2 (1): 141–179. doi:10.2304/eerj.2003.2.1.4. S2CID 145073344.
  34. ^ Stiwne, Elinor Edvardsson; Alves, Mariana Gaio (March 2010). "Higher education and employability of graduates: will Bologna make a difference?". European Educational Research Journal. 9 (1): 32–44 [33]. CiteSeerX 10.1.1.1013.4278. doi:10.2304/eerj.2010.9.1.32. S2CID 145319261.
  35. ^ Nielsen, Gritt B. (2015). Figuration work: student participation, democracy and university reform in a global knowledge economy. EASA series. Vol. 27. New York: Berghahn Books. p. 136. ISBN 9781782387718. OCLC 896861729.
  36. ^ Graseck, Paul (January 2005). "Where's the ministry in administration?: attending to the souls of our schools". Phi Delta Kappan. 86 (5): 373–378. doi:10.1177/003172170508600508. S2CID 143901370.
  37. ^ Marshall, Jeff C.; Smart, Julie; Alston, Daniel M. (October 2016). "Development and validation of Teacher Intentionality of Practice Scale (TIPS): a measure to evaluate and scaffold teacher effectiveness". Teaching and Teacher Education. 59 (3): 159–168. Bibcode:2003TeTeE..19..309T. doi:10.1016/j.tate.2016.05.007.
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External links edit

 
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November 25, 2023
inquiry, based, learning, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, o. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Inquiry based learning news newspapers books scholar JSTOR October 2023 Learn how and when to remove this template message Inquiry based learning also spelled as enquiry based learning in British English a is a form of active learning that starts by posing questions problems or scenarios It contrasts with traditional education which generally relies on the teacher presenting facts and their knowledge about the subject Inquiry based learning is often assisted by a facilitator rather than a lecturer Inquirers will identify and research issues and questions to develop knowledge or solutions Inquiry based learning includes problem based learning and is generally used in small scale investigations and projects as well as research 2 The inquiry based instruction is principally very closely related to the development and practice of thinking and problem solving skills 3 Contents 1 History 2 Characteristics 2 1 Levels 2 2 Open true inquiry learning 2 3 Inquisitive learning 3 Inquiry based learning in academic disciplines 3 1 Science education 3 1 1 History 3 1 2 Science standards 3 1 3 Pedagogical applications 3 1 3 1 Problem based learning 3 1 3 2 5E Model of Science Education 3 1 4 Collaboration and communication 3 2 Social studies and history 3 3 Ontario s kindergarten program 3 4 Learning to read in the Netherlands 4 Misconceptions 5 Neuroscience complexity 5 1 Necessity for teacher training 6 Criticism 7 Additional scholarly research literature 8 See also 9 Notes 10 References and further reading 11 External linksHistory editInquiry based learning is primarily a pedagogical method developed during the discovery learning movement of the 1960s as a response to traditional forms of instruction where people were required to memorize information from instructional materials 4 such as direct instruction and rote learning The philosophy of inquiry based learning finds its antecedents in constructivist learning theories such as the work of Piaget Dewey Vygotsky and Freire among others 5 6 7 and can be considered a constructivist philosophy Generating information and making meaning of it based on personal or societal experience is referred to as constructivism 8 Dewey s experiential learning pedagogy that is learning through experiences comprises the learner actively participating in personal or authentic experiences to make meaning from it 9 10 Inquiry can be conducted through experiential learning because inquiry values the same concepts which include engaging with the content material in questioning as well as investigating and collaborating to make meaning Vygotsky approached constructivism as learning from an experience that is influenced by society and the facilitator The meaning constructed from an experience can be concluded as an individual or within a group 8 9 In the 1960s Joseph Schwab called for inquiry to be divided into three distinct levels 11 This was later formalized by Marshall Herron in 1971 who developed the Herron Scale to evaluate the amount of inquiry within a particular lab exercise 12 Since then there have been a number of revisions proposed and inquiry can take various forms There is a spectrum of inquiry based teaching methods available 13 Inquiry learning has been used as a teaching and learning tool for thousands of years however the use of inquiry within public education has a much briefer history 14 Ancient Greek and Roman educational philosophies focused much more on the art of agricultural and domestic skills for the middle class and oratory for the wealthy upper class It was not until the Enlightenment or the Age of Reason during the late 17th and 18th century that the subject of Science was considered a respectable academic body of knowledge 15 Up until the 1900s the study of science within education had a primary focus on memorizing and organizing facts John Dewey a well known philosopher of education at the beginning of the 20th century was the first to criticize the fact that science education was not taught in a way to develop young scientific thinkers Dewey proposed that science should be taught as a process and way of thinking not as a subject with facts to be memorized 14 While Dewey was the first to draw attention to this issue much of the reform within science education followed the lifelong work and efforts of Joseph Schwab Joseph Schwab was an educator who proposed that science did not need to be a process for identifying stable truths about the world that we live in but rather science could be a flexible and multi directional inquiry driven process of thinking and learning Schwab believed that science in the classroom should more closely reflect the work of practicing scientists Schwab developed three levels of open inquiry that align with the breakdown of inquiry processes that we see today 16 Students are provided with questions methods and materials and are challenged to discover relationships between variables Students are provided with a question however the method for research is up to the students to develop Phenomena are proposed but students must develop their own questions and method for research to discover relationships among variablesToday we know that students at all levels of education can successfully experience and develop deeper level thinking skills through scientific inquiry 17 The graduated levels of scientific inquiry outlined by Schwab demonstrate that students need to develop thinking skills and strategies prior to being exposed to higher levels of inquiry 16 Effectively these skills need to be scaffolded by the teacher or instructor until students are able to develop questions methods and conclusions on their own 18 Characteristics edit nbsp Example of problem project based learning versus reading cover to cover The problem project based learner may memorize a smaller amount of total information due to spending time searching for the optimal information across various sources but will likely learn more useful items for real world scenarios and will likely be better at knowing where to find information when needed 19 Specific learning processes that people engage in during inquiry learning include 20 21 Creating questions of their own Obtaining supporting evidence to answer the question s Explaining the evidence collected Connecting the explanation to the knowledge obtained from the investigative process Creating an argument and justification for the explanationInquiry learning involves developing questions making observations doing research to find out what information is already recorded developing methods for experiments developing instruments for data collection collecting analyzing and interpreting data outlining possible explanations and creating predictions for future study 22 Levels edit There are many different explanations for inquiry teaching and learning and the various levels of inquiry that can exist within those contexts The article titled The Many Levels of Inquiry by Heather Banchi and Randy Bell 2008 23 clearly outlines four levels of inquiry Level 1 Confirmation Inquiry The teacher has taught a particular science theme or topic The teacher then develops questions and a procedure that guides students through an activity where the results are already known This method is great to reinforce concepts taught and to introduce students into learning to follow procedures collect and record data correctly and to confirm and deepen understandings Level 2 Structured Inquiry The teacher provides the initial question and an outline of the procedure Students are to formulate explanations of their findings through evaluating and analyzing the data that they collect Level 3 Guided Inquiry The teacher provides only the research question for the students The students are responsible for designing and following their own procedures to test that question and then communicate their results and findings Level 4 Open True Inquiry Students formulate their own research question s design and follow through with a developed procedure and communicate their findings and results This type of inquiry is often seen in science fair contexts where students drive their own investigative questions Banchi and Bell 2008 explain that teachers should begin their inquiry instruction at the lower levels and work their way to open inquiry in order to effectively develop students inquiry skills Open inquiry activities are only successful if students are motivated by intrinsic interests and if they are equipped with the skills to conduct their own research study 24 Open true inquiry learning edit An important aspect of inquiry based learning is the use of open learning as evidence suggests that only utilizing lower level inquiry is not enough to develop critical and scientific thinking to the full potential 25 26 27 Open learning has no prescribed target or result that people have to achieve There is an emphasis on the individual manipulating information and creating meaning from a set of given materials or circumstances 28 In many conventional and structured learning environments people are told what the outcome is expected to be and then they are simply expected to confirm or show evidence that this is the case Open learning has many benefits 27 It means students do not simply perform experiments in a routine like fashion but actually think about the results they collect and what they mean With traditional non open lessons there is a tendency for students to say that the experiment went wrong when they collect results contrary to what they are told to expect In open learning there are no wrong results and students have to evaluate the strengths and weaknesses of the results they collect themselves and decide their value Open learning has been developed by a number of science educators including the American John Dewey and the German Martin Wagenschein b Wagenschein s ideas particularly complement both open learning and inquiry based learning in teaching work He emphasized that students should not be taught bald facts but should understand and explain what they are learning His most famous example of this was when he asked physics students to tell him what the speed of a falling object was Nearly all students would produce an equation but no students could explain what this equation meant citation needed Wagenschein used this example to show the importance of understanding over knowledge 30 Although both guided and open true inquiry were found to promote science literacy and interest each has its own advantages While open true inquiry may contribute to students initiative flexibility and adaptability better than guided inquiry in the long run 31 some claim that it may lead to high cognitive load and that guided inquiry is more efficient in terms of time and content learning 32 Inquisitive learning edit Sociologist of education Phillip Brown defined inquisitive learning as learning that is intrinsically motivated e g by curiosity and interest in knowledge for its own sake as opposed to acquisitive learning that is extrinsically motivated e g by acquiring high scores on examinations to earn credentials 33 34 35 However occasionally the term inquisitive learning is simply used as a synonym for inquiry based learning 36 37 Inquiry based learning in academic disciplines editScience education edit History edit A catalyst for reform within North American science education was the 1957 launch of Sputnik the Soviet Union satellite This historical scientific breakthrough caused a great deal of concern around the science and technology education the American students were receiving In 1958 the U S congress developed and passed the National Defense Education Act in order to provide math and science teachers with adequate teaching materials 22 38 Science standards edit America s Next Generation Science Standards NGSS embrace student centered inquiry based pedagogy by implementing a three part approach to science education Disciplinary Core Ideas DCIs Science and Engineering Practices SEPs and Cross Cutting Concepts CCCs 39 The standards are designed so that students learn science by performing scientific practices in the classroom Students use practices such as asking questions planning and carrying out investigations collaborating collecting and analyzing data and arguing from evidence to learn the core ideas and concepts in scientific content areas These practices are comparable to the 21st Century Skills that have been shown to be indicators of success in modern societies and workplaces regardless of whether that field is science based 40 Pedagogical applications edit Inquiry based pedagogy in science education has been shown to increase students scientific knowledge and literacy when compared to when students are taught using more traditional pedagogical methods 41 42 43 However even though students in inquiry based classrooms are shown to have higher scientific knowledge they have also been shown to have increased frustration and decreased confidence in scientific ability when compared to their peers taught using traditional methods 42 44 Research has also shown that while inquiry based pedagogy has been shown to improve students science achievement social contexts must be taken into account This is because achievement gaps among students may be as likely to widen as they are to decrease due to differences in student readiness for inquiry based learning based on social and economic status differences 45 In cases where students scientific knowledge in an inquiry based classroom was not significantly different than their peers taught in traditional methods student problem solving ability was found to be improved for inquiry learning students 41 Inquiry as a pedagogical framework and learning process fits within many educational models including Problem Based Learning and the 5E Model of Education Problem based learning edit Inquiry as a pedagogical framework has been shown to be especially effective when used along problem based learning PBL assignments 41 46 47 As a student centered strategy problem based learning fits well within an inquiry based classroom Students learn science by performing science asking questions designing experiments collecting data making claims and using data to support claims By creating a culture and community of inquiry in a science classroom students learn science by working collaboratively with their peers to investigate the world around them and ways to solve problems affecting their communities 47 Students confronted with real world problems that affect their everyday lives are shown to have increased engagement and feel more encouraged to solve the problems posed to them 47 5E Model of Science Education edit The 5E Model of Science Education is a planning structure that helps science teachers develop student centered inquiry based lessons and units In the 5E model students learn science by exploring their questions using the same approach scientists explore their questions By using this approach science teachers help their students connect scientific content learned in the classroom with phenomena from their own lives and apply that learning to new areas in science and beyond 48 The 5E Model is broken into the following sections which may repeat and occur at various stages of the learning process Engage This is generally considered to be the opening stage of the 5E Model and is used to inspire student curiosity and should help students connect new phenomena to prior learning This stage of the 5E model also aims to identify student misconceptions that need to be addressed through the lessons designed by the teacher 48 Explore In this stage students investigate the phenomena observed during the engage stage and answer any questions they have generated based on their observations The level of inquiry i e fully open vs guided may vary based on the level age and readiness of students 43 44 49 48 Explain In this stage the teacher helps students piece together the information they gathered during the explore stage Again the level of direct teacher instruction and explanation may vary based on the level age and readiness of students 43 44 49 48 Elaborate Expand This stage determines if students are truly able to apply the information they ve learned to new areas and to the solution of real world problems 48 Evaluate In this stage students evaluate their own learning and the teacher evaluates student understanding and ability to apply knowledge to multiple areas 48 Collaboration and communication edit Effective collaboration and communication is an integral part of scientists and engineers everyday lives and their importance is reflected in the representation of these skills in the science and engineering practices of the Next Generation Science Standards Inquiry education supports these skills especially when students take part in a community of inquiry 43 47 Students who are actively collaborating and communicating in an inquiry based science class exhibit and develop many of these skills 46 47 43 41 Specifically these students make observations and ask questions with their peers work with peers to design solutions to problems analyze claims of their peers argue from evidence support their peers growth and search for knowledgeSocial studies and history edit The College Career and Civic Life C3 Framework for Social Studies State Standards was a joint collaboration among states and social studies organizations including the National Council for the Social Studies 50 designed to focus social studies education on the practice of inquiry emphasizing the disciplinary concepts and practices that support students as they develop the capacity to know analyze explain and argue about interdisciplinary challenges in our social world 50 The C3 Framework recommends an Inquiry Arc incorporating four dimensions 1 developing questions and planning inquiries 2 applying disciplinary concepts and tools 3 evaluating primary sources and using evidence and 4 communicating conclusions and taking informed action 50 For example a theme for this approach could be an exploration of etiquette today and in the past Students might formulate their own questions or begin with an essential question such as Why are men and women expected to follow different codes of etiquette Students explore change and continuity of manners over time and the perspectives of different cultures and groups of people They analyze primary source documents such as books of etiquette from different time periods and form conclusions that answer the inquiry questions Students finally communicate their conclusions in formal essays or creative projects They may also take action by recommending solutions for improving school climate 51 Robert Bain in How Students Learn described a similar approach called problematizing history 52 First a learning curriculum is organized around central concepts Next a question and primary sources are provided such as eyewitness historical accounts The task for inquiry is to create an interpretation of history that will answer the central question Students will form a hypothesis collect and consider information and revisit their hypothesis as they evaluate their data Ontario s kindergarten program edit After Charles Pascal s report in 2009 the Canadian province of Ontario s Ministry of Education decided to implement a full day kindergarten program that focuses on inquiry and play based learning called The Early Learning Kindergarten Program 53 As of September 2014 all primary schools in Ontario started the program The curriculum document 54 outlines the philosophy definitions process and core learning concepts for the program Bronfenbrenner s ecological model Vygotsky s zone of proximal development Piaget s child development theory and Dewey s experiential learning are the heart of the program s design As research shows children learn best through play whether it is independently or in a group Three forms of play are noted in the curriculum document pretend or pretense play socio dramatic play and constructive play Through play and authentic experiences children interact with their environment people and or objects and question things thus leading to inquiry learning A chart on page 15 clearly outlines the process of inquiry for young children including initial engagement exploration investigation and communication 54 The new program supports holistic approach to learning For further details please see the curriculum document 54 Since the program is extremely new as of there is limited research on its success and areas of improvement One government research report was released with the initial groups of children in the new kindergarten program The Final Report Evaluation of the Implementation of the Ontario Full Day Early Learning Kindergarten Program from Vanderlee Youmans Peters and Eastabrook 2012 conclude with primary research that high need children improved more compared to children who did not attend Ontario s new kindergarten program 55 As with inquiry based learning in all divisions and subject areas longitudinal research is needed to examine the full extent of this teaching learning method Learning to read in the Netherlands edit Since 2013 Dutch children have participated in a curriculum of learning to read through an inquiry based pedagogical program The program from the Dutch developmental psychologist Ewald Vervaet is named Ontdekkend Leren Lezen OLL Discovery Learning to Read and has three parts 56 As of 2019 OLL is only available in Dutch OLL s main characteristic is that it is for children who are reading mature Reading maturity is assessed with the Reading Maturity Test It is a descriptive test that consists of two subtests 57 Misconceptions editThere are several common misconceptions regarding inquiry based science the first being that inquiry science is simply instruction that teaches students to follow the scientific method Many teachers had the opportunity to work within the constraints of the scientific method as students themselves and assume inquiry learning must be the same Inquiry science is not just about solving problems in six simple steps but much more broadly focused on the intellectual problem solving skills developed throughout a scientific process 17 Additionally not every hands on lesson can be considered inquiry Some educators believe that there is only one true method of inquiry which would be described as the level four Open Inquiry While open inquiry may be the most authentic form of inquiry there are many skills and a level of conceptual understanding that the students must have developed before they can be successful at this high level of inquiry 18 While inquiry based science is considered to be a teaching strategy that fosters higher order thinking in students it should be one of several methods used A multifaceted approach to science keeps students engaged and learning Not every student is going to learn the same amount from an inquiry lesson students must be invested in the topic of study to authentically reach the set learning goals Teachers must be prepared to ask students questions to probe their thinking processes in order to assess accurately Inquiry science requires a lot of time effort and expertise however the benefits outweigh the cost when true authentic learning can take place citation needed Neuroscience complexity editThe literature states that inquiry requires multiple cognitive processes and variables such as causality and co occurrence that enrich with age and experience 58 59 Kuhn et al 2000 used explicit training workshops to teach children in grades six to eight in the United States how to inquire through a quantitative study By completing an inquiry based task at the end of the study the participants demonstrated enhanced mental models by applying different inquiry strategies 58 In a similar study Kuhan and Pease 2008 completed a longitudinal quantitative study following a set of American children from grades four to six to investigate the effectiveness of scaffolding strategies for inquiry Results demonstrated that children benefitted from the scaffolding because they outperformed the grade seven control group on an inquiry task 59 Understanding the neuroscience of inquiry learning the scaffolding process related to it should be reinforced for Ontario s primary teachers as part of their training Necessity for teacher training edit There is a necessity for professional collaboration when executing a new inquiry program Chu 2009 Twigg 2010 The teacher training and process of using inquiry learning should be a joint mission to ensure the maximal amount of resources are used and that the teachers are producing the best learning scenarios The scholarly literature supports this notion Twigg s 2010 education professionals who participated in her experiment emphasized year round professional development sessions such as workshops weekly meetings and observations to ensure inquiry is being implemented in the class correctly 10 Another example is Chu s 2009 study where the participants appreciated the professional collaboration of educators information technicians and librarians to provide more resources and expertise for preparing the structure and resources for the inquiry project 60 To establish a professional collaboration and researched training methods administration support is required for funding Criticism editKirschner Sweller and Clark 2006 61 review of literature found that although constructivists often cite each other s work empirical evidence is not often cited Nonetheless the constructivist movement gained great momentum in the 1990s because many educators began to write about this philosophy of learning Hmelo Silver Duncan amp Chinn cite several studies supporting the success of the constructivist problem based and inquiry learning methods For example they describe a project called GenScope an inquiry based science software application Students using the GenScope software showed significant gains over the control groups with the largest gains shown in students from basic courses 62 In contrast Hmelo Silver et al also cite a large study by Geier on the effectiveness of inquiry based science for middle school students as demonstrated by their performance on high stakes standardized tests The improvement was 14 for the first cohort of students and 13 for the second cohort This study also found that inquiry based teaching methods greatly reduced the achievement gap for African American students 62 In a 2006 article the Thomas B Fordham Institute s president Chester E Finn Jr was quoted as saying But like so many things in education it gets carried to excess the approach is fine to some degree 63 The organization ran a study in 2005 concluding that the emphasis states put on inquiry based learning is too great 64 Richard E Mayer from the University of California Santa Barbara wrote in 2004 that there was sufficient research evidence to make any reasonable person skeptical about the benefits of discovery learning practiced under the guise of cognitive constructivism or social constructivism as a preferred instructional method He reviewed research on discovery of problem solving rules culminating in the 1960s discovery of conservation strategies culminating in the 1970s and discovery of LOGO programming strategies culminating in the 1980s In each case guided discovery was more effective than pure discovery in helping students learn and transfer 65 It should be cautioned that inquiry based learning takes a lot of planning before implementation It is not something that can be put into place in the classroom quickly Measurements must be put in place for how students knowledge and performance will be measured and how standards will be incorporated The teacher s responsibility during inquiry exercises is to support and facilitate student learning Bell et al 769 770 A common mistake teachers make is lacking the vision to see where students weaknesses lie According to Bain teachers cannot assume that students will hold the same assumptions and thinking processes as a professional within that discipline p 201 While some see inquiry based teaching as increasingly mainstream it can be perceived as in conflict with standardized testing common in standards based assessment systems which emphasise the measurement of student knowledge and meeting of pre defined criteria for example the shift towards fact in changes to the National Assessment of Educational Progress as a result of the American No Child Left Behind program citation needed Additional scholarly research literature editChu 2009 used a mixed method design to examine the outcome of an inquiry project completed by students in Hong Kong with the assistance of multiple educators Chu s 2009 results show that the children were more motivated and academically successful compared to the control group 60 Cindy Hmelo Silver reviewed a number of reports on a variety studies into problem based learning 66 Edelson Gordin and Pea describe five significant challenges to implementing inquiry based learning and present strategies for addressing them through the design of technology and curriculum They present a design history covering four generations of software and curriculum to show how these challenges arise in classrooms and how the design strategies respond to them 67 See also editAction learning Design based learning Discovery learning Networked learning Phenomenon based learning POGIL Problem based learning Progressive inquiry Project based learning Scientific literacy Three part lessonNotes edit The UK dictionaries Collins and Longman list the spelling inquiry first and Oxford simply calls it another spelling without labeling it as US English 1 Wagenschein characterized his approach as Socratic genetic and example based 29 circular reference References and further reading edit enquiry noun www oxfordlearnersdictionaries com Oxford University Press Retrieved 2 April 2021 What is Inquiry Based Learning EBL Centre for Excellence in Enquiry Based Learning University of Manchester Dostal J 2015 Inquiry based instruction Concept essence importance and contribution Olomouc Palacky University doi 10 5507 pdf 15 24445076 ISBN 978 80 244 4507 6 Bruner J S 1961 The act of discovery Harvard Educational Review 31 1 21 32 Dewey J 1997 How We Think New York Dover Publications Freire P 1984 Pedagogy of the Oppressed New York Continuum Publishing Company Vygotsky L S 1962 Thought and Language Cambridge MA MIT Press a b Bachtold Manuel 2013 What do students construct according to constructivism in science education Research in Science Education 43 6 2477 96 Bibcode 2013RScEd 43 2477B doi 10 1007 s11165 013 9369 7 S2CID 145256074 a b Roth Wolff Michael Jornet Alfredo 2013 Toward a theory of experience Science Education 98 1 106 26 Bibcode 2014SciEd 98 106R doi 10 1002 sce 21085 hdl 10072 67780 a b Twigg Vani Veikoso 2010 Teachers practices values and beliefs for successful inquiry based teaching in the International Baccalaureate Primary years Programme Journal of Research in International Education 9 1 40 65 doi 10 1177 1475240909356947 S2CID 145639391 Schwab J Summer 1960 Inquiry the Science Teacher and the Educator The School Review The University of Chicago Press 68 2 176 195 doi 10 1086 442536 JSTOR 1083585 S2CID 144897014 Herron M D 1971 The nature of scientific enquiry The school review 79 2 171 212 Wilhelm J G amp Wilhelm P J 2010 Inquiring minds learn to read write and think Reaching all learners through inquiry Middle School Journal May 2010 39 46 a b National Research Council 2000 Inquiry and the National Science Education Standards A Guide for Teaching and Learning Washington DC National Academy Press Murphy M 2006 The History and Philosophy of Education Voices of Educational Pioneers Upper Saddle River NJ Pearson Education Inc ISBN 0130955507 a b Schwab J 1966 The Teaching of Science Cambridge MA Harvard University Press a b National Science Education Standards 1996 National Academy Press Washington DC a b Ban chi H amp Bell R 2008 The Many Levels of Inquiry Science and Children 46 2 26 29 Image by Mikael Haggstrom MD using source images by various authors Source for useful context in problem based learning Mark A Albanese Laura C Dast 22 October 2013 Understanding Medical Education Problem based learning Wiley Online Library doi 10 1002 9781118472361 ch5 Bell T Urhahne D Schanze S Ploetzner R 2010 Collaborative inquiry learning Models tools and challenges International Journal of Science Education 3 1 349 377 Bibcode 2010IJSEd 32 349B doi 10 1080 09500690802582241 S2CID 3866279 What is inquiry a b National Institute for Health 2005 Doing Science The Process of Science Inquiry http science education nih gov supplements nih6 inquiry guide info process a htm Bell R Banchi H 2008 The Many Levels of Inquiry Science amp Children 46 2 26 29 Yoon H Joung Y J Kim M 2012 The challenges of science inquiry teaching for pre service teachers in elementary classrooms Difficulties on and under the scene Research in Science amp Technological Education 42 3 589 608 Bibcode 2012RScEd 42 589Y doi 10 1007 s11165 011 9212 y S2CID 143969965 Berg C A R Bergendahl V C B Lundberg B K S Tibell L A E 2003 Benefiting from an open ended experiment A comparison of attitudes to and outcomes of an expository versus an open inquiry version to the same experiment International Journal of Science Education 25 3 351 372 Bibcode 2003IJSEd 25 351B doi 10 1080 09500690210145738 S2CID 143335162 Yen C F and Hunang S C 2001 Authentic learning about tree frogs by preservice biology teachers in an open inquiry 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Evaluation of the implementation of the Ontario full day early learning kindergarten program PDF Report Archived from the original PDF on 25 March 2014 Ewald Vervaet There is a fourth book It is for children who are not reading mature and generally in kindergarten Klank en vormspel Sound and form play Retrieved 27 April 2019 Ewald Vervaet Schrijfproef en leesproef Writing test and reading test PDF in Dutch Retrieved 27 April 2019 a b Kuhn D Black J Keselman A Kaplan D 2000 The development of cognitive skills to support inquiry learning Cognition and Instruction 18 4 495 523 CiteSeerX 10 1 1 527 1718 doi 10 1207 s1532690xci1804 3 S2CID 8273319 a b Kuhn D Pease M 2008 What needs to develop in the development of inquiry skills Cognition and Instruction 26 4 512 59 doi 10 1080 07370000802391745 S2CID 144373662 a b Chu K W S 2009 Inquiry project based learning with a partnership of three types of teachers and the school librarian Journal of the American Society for Information Science and Technology 60 8 1671 86 doi 10 1002 asi 21084 Kirschner P A Sweller J Clark R E 2006 Why minimal guidance during instruction does not work an analysis of the failure of constructivist discovery problem based experiential and inquiry based teaching PDF Educational Psychologist 41 2 75 86 doi 10 1207 s15326985ep4102 1 hdl 1874 16899 S2CID 17067829 Archived from the original PDF on 19 September 2017 Retrieved 30 December 2007 a b Hmelo Silver Duncan Chinn 2007 Scaffolding and Achievement in Problem Based and Inquiry Learning A Response to Kirschner Sweller and Clark 2006 PDF Educational Psychologist 42 2 99 107 doi 10 1080 00461520701263368 S2CID 1360735 Archived from the original PDF on 23 December 2010 Retrieved 27 December 2007 Thomson Robert 19 January 2006 What s the Right Formula Gross Paul December 2005 The State of State Science Standards PDF Report Thomas B Fordham Institute Mayer R 2004 Should there be a three strikes rule against pure discovery learning The case for guided methods of instruction PDF American Psychologist 59 1 14 19 CiteSeerX 10 1 1 372 2476 doi 10 1037 0003 066x 59 1 14 PMID 14736316 S2CID 1129364 Hmelo Silver C September 2004 Problem Based Learning What and how do students learn PDF Educational Psychology Review 16 3 235 266 doi 10 1023 B EDPR 0000034022 16470 f3 S2CID 15702585 Archived from the original PDF on 16 October 2012 Edelson D Gordin D Pea R 1999 Addressing the Challenges of Inquiry Based Learning Through Technology and Curriculum Design PDF Journal of the Learning Sciences 8 3 391 450 doi 10 1207 s15327809jls0803 amp 4 3 External links edit nbsp Wikiversity has learning resources about Inquiry based learning Inquiry based middle school lesson plan Born to Run Artificial Selection Lab Teaching Inquiry based Science What is Inquiry Retrieved from https en wikipedia org w index php title Inquiry based learning amp oldid 1186112543, wikipedia, wiki, book, books, library,

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