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  • 51.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Astronomi på distans: 2011Ingår i: Populär Astronomi, ISSN 1650-7177, Vol. 12, nr 3, s. 38-40Artikel i tidskrift (Övrig (populärvetenskap, debatt, mm))
    Abstract [sv]

    Dagens studenter är mycket mer flexibla i sina studier än tidigare. Idag läser många studenter kurser på olika universitet och högskolor samtidigt. Detta är möjligt genom att många kurser ges på distans via internet. I denna artikel kommer jag att berätta lite om de erfarenheter som jag har efter att ha undervisat ca 10 år på distans.

  • 52.
    Eriksson, Urban
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Nationellt resurscentrum för fysik, Lunds universitet.
    Disciplinary discernment: Reading the sky in astronomy education2019Ingår i: Physical Review Special Topics : Physics Education Research, ISSN 1554-9178, E-ISSN 1554-9178, Vol. 15, nr 1, s. Disciplinary discernment: Reading the sky in astronomy education-Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    This theoretical paper introduces a new way to view and characterize learning astronomy. It describes a framework, based on results from empirical data, analyzed through standard qualitative research method- ology, in which a theoretical model for a vital competency of learning astronomy is proposed: reading the sky, a broad description under with various skills and competencies are included. This model takes into account not only disciplinary knowledge but also disciplinary discernment and extrapolating three dimensionality. Together, these constitute the foundation for the competency referred to as reading the sky. In this paper, these competencies are described and discussed and merged to form a new framework vital for learning astronomy to better match the challenges students face when entering the discipline of astronomy.

  • 53.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Nationellt resurscentrum för fysik, Lunds universitet.
    Disciplinärt urskiljande av representationer i matematik: vad ser studenterna och vad ser de inte?2018Konferensbidrag (Övrigt vetenskapligt)
    Abstract [sv]

    Att lära sig matematik innebär att lära sig "läsa" och "skriva" alla de semiotiska resurser som används för att kommunicera ämnet. Med erfarenheter från andra discipliner, så som astronomi och fysik, vet man att det är svårt för studenter att urskilja disciplinära affordanser av semiotiska resurser och därmed lära sig ämnet och bli en del av disciplinen. Preliminära resultat visar på att detta också gäller för urskiljandet av matematiska semiotiska resurser av olika typ. Den teoretiska utgångspunkten för analys av dessa resurser är en generell hierarki som beskriver olika grader av disciplinärt urskiljande: "The anatomy of disciplinary discernment" (Eriksson et al., 2014). Vi kommer att visa och diskutera ett antal exempel hämtade från funktioner och integraler, där disciplinära affordanser identifieras, både synliga och implicita ("appresented"), av olika komplexitetsgrad och dimensionalitet. Med dessa exempel som utgångspunkt diskuteras möjliga strategier för undervisning och lärande.

  • 54.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    En astronomisk reflektion över bin och honungsproduktion.2006Ingår i: Bitidningen, ISSN 0006-3886Artikel i tidskrift (Övrig (populärvetenskap, debatt, mm))
  • 55.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Nationellt resurscentrum för fysik, Lunds universitet.
    Från Stjärnfläckar till Stjärnobservationer: bland galaxer, stjärnor, planeter och tankar kring dessa2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [sv]

    Att lära sig astronomi, eller naturvetenskap över lag, involverar så mycket och kan liknas vid att lära sig ett nytt språk. Eleven måste lära sig detta språk och det innefattar, förutom skrivet och talat fackspråk, en mängd mer eller mindre begripliga sk representationerna, aktiviteter och verktyg. Det är därför en grannlaga uppgift att lära sig naturvetenskap och eleverna behöver hjälp med att lära sig naturvetenskapens språk. Det sker i allmänhet samtidigt som de lär sig ämnet, men jag kommer att prata om att det krävs träning av vissa speciella färdigheter för att underlätta denna process. Detta involverar disciplinärt urskiljande samt multidimensionellt tänkande. Jag kommer att beskriva ett teoretiskt ramverk, med praktiska exempel från astronomins värld, på hur detta kan ske.

  • 56.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Nationellt resurscentrum för fysik, Lunds universitet.
    “Reading” representations: what does this have to do with teaching and learning physics?2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    Learning physics can be compared to learning a new language in several respects. This includes learning to “read and write” the representations that carry the meaning of the language. In the case of physics these representations include text, gestures, mathematics, graphs, images, simulations and animations. For those who are fluent in the language, these representations are full of meaning but for the novice learning to discern the relevant disciplinary aspects of these representations (disciplinary discernment) can be a struggle. Research has shown that often teachers assume that students “see” the same things in a representation that they do. However, this is usually not true. Learning to discern disciplinary aspects of representations is something that students need help with (scaffolding). One important aspect of learning representational fluency in physics is that of spatial thinking, in particular learning to extrapolate three-dimensionality from one- and two-dimensional representations.

    In this talk I will present a theoretical framework describing the process of teaching and learning representational disciplinary fluency. I will also provide some examples to illustrate the framework, from the perspectives of the instructor and the student.

  • 57.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Nationellt resurscentrum för fysik, Lunds universitet.
    Reading the Sky And The Spiral of Teaching and Learning in AstronomyManuskript (preprint) (Övrigt vetenskapligt)
    Abstract [en]

    This theoretical paper introduces a new way to view and characterize teaching and learning astronomy. It describes a framework, based on results from empirical data, analyzed through standard qualitative research methodology, in which a theoretical model for vital competencies of learning astronomy is proposed: Reading the Sky . This model takes into account not only disciplinary knowledge  but also disciplinary discernment  and extrapolating three-dimensionality . Together, these constitute the foundation for the competency referred to as Reading the Sky . In this paper, I describe these concepts and how I see them being connected and intertwined to form a new competency model for learning astronomy and how this can be used to inform astronomy education to better match the challenges students face when entering the discipline of astronomy: The Spiral of Teaching and Learning . Two examples are presented to highlight how this model can be used in teaching situations.

  • 58.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Nationellt resurscentrum för fysik, Lunds universitet.
    Reading the Sky and The Spiral of Teaching and Learning in Astronomy2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    Teaching and learning astronomy is known to be both exciting and challenging. To learn astronomy demands not only disciplinary knowledge, but also the ability to discern meaning from disciplinary specific representations (disciplinary discernment). This includes the ability to think spatially, in particular, extrapolating three-dimensionality from a one- or two-dimensional input i.e. to be able to visualize in one’s mind how a three-dimensional astronomical object may look from a one- or two-dimensional input such as from a visual image or a mathematical representation. In this talk I demonstrate that these abilities are deeply intertwined, and that to learn astronomy at any level demands becoming fluent in all three aspects (disciplinary knowledge, disciplinary discernment and spatial thinking). A framework is presented for how these competencies can be described, and combined, as a new and innovative way to frame teaching and learning in astronomy. It is argued that using this framework “Reading the Sky” optimizes the learning outcomes for students. The talk also suggests strategies for how to implement this approach for improving astronomy teaching and learning overall.

  • 59.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Reading the sky and the spiral of teaching and learning in astronomy2015Konferensbidrag (Refereegranskat)
    Abstract [en]

    Teaching and learning astronomy is known to be both exciting and challenging. To learn astronomy demands not only disciplinary knowledge, but also ability to discern affordances from disciplinary specific representations used within the discourse, which we call disciplinary discernment, and ability to think spatially, which we refer to as extrapolating three-dimensionality from a two dimensional input. Disciplinary knowledge involves all the knowledge that constitutes the discipline, disciplinary discernment involves discernment of the affordances of disciplinaryspecific representations, and extrapolating three-dimensionality involves the ability to visualize in ones mind how a three-dimensional astronomical object may look from a two-dimensional input (image or simulation). In this paper we argue that these abilities are intertwined and to learn astronomy at any level demands becoming fluent in all three. A framework is presented for how these abilities can be described and combined as a new and innovative way to frame teaching and learning in astronomy for optimizing the learning outcome of students - what we refer to as developing the ability to Read the Sky. We conclude that this is a vital competency needed for learning astronomy and suggest strategies for how to implement this to improve astronomy education.

  • 60.
    Eriksson, Urban
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Reading the sky: from starspots to spotting stars2014Doktorsavhandling, sammanläggning (Övrigt vetenskapligt)
    Abstract [en]

    This thesis encompasses two research fields in astronomy: astrometry and astronomy education and they are discussed in two parts. These parts represent two sides of a coin; astrometry, which is about constructing 3D representations of the Universe, and AER, where for this thesis, the goal is to investigate university students’ and lecturers’ disciplinary discernment vis-à-vis the structure of the Universe and extrapolating three-dimensionality.

    Part I presents an investigation of stellar surface structures influence on ultra-high-precision astrometry. The expected effects in different regions of the HR-diagram were quantified. I also investigated the astrometric effect of exoplanets, since astrometric detection will become possible with projects such as Gaia. Stellar surface structures produce small brightness variations, influencing integrated properties such as the total flux, radial velocity and photocenter position. These properties were modelled and statistical relations between the variations of the different properties were derived. From the models it is clear that for most stellar types the astrometric jitter due to stellar surface structures is expected to be of order 10 μAU or greater. This is more than the astrometric displacement typically caused by an Earth-sized exoplanet in the habitable zone, which is about 1–4 μAU, making astrometric detection difficult.

    Part II presents an investigation of disciplinary discernment at the university level. Astronomy education is a particularly challenging experience for students because discernment of the ‘real’ Universe is problematic, making interpretation of the many disciplinary-specific representations used an important educational issue. The ability to ‘fluently’ discern the disciplinary affordances of these representations becomes crucial for the effective learning of astronomy. To understand the Universe I conclude that specific experiences are called. Simulations could offer these experiences, where parallax motion is a crucial component. In a qualitative study, I have analysed students’ and lecturers’ discernment while watching a simulation video, and found hierarchies that characterize the discernment in terms of three-dimensionality extrapolation and an Anatomy of Disciplinary Discernment. I combined these to define a new construct: Reading the Sky. I conclude that this is a vital competency needed for learning astronomy and suggest strategies for how to implement this in astronomy education.

  • 61.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Teaching and learning in astronomy education – a spiral approach to reading the sky2015Konferensbidrag (Refereegranskat)
    Abstract [en]

    Teaching and learning astronomy is known to be both exciting and challenging. However, learning astronomy at university level is a demanding task for many students. The learning pro-cess involves not only disciplinary knowledge, but also the ability to discern affordances from disciplinary specific representations used within the astronomy discourse, which we call discipli-nary discernment (Eriksson, Linder, Airey, & Redfors, 2014a) and ability to think spatially, which we refer to as extrapolating three-dimensionality from a two dimensional input (Eriksson, Linder, Airey, & Redfors, 2014b). Disciplinary knowledge involves all the knowledge that con-stitutes the discipline, disciplinary discernment involves discernment of the affordances of disci-plinary-specific representations, and extrapolating three-dimensionality involves the ability to visualize in ones mind how a three-dimensional astronomical object may look from a two-dimensional input (image or simulation). In this paper we argue that these abilities are inter-twined and to learn astronomy at any level demands becoming fluent in all three abilities. A framework is presented for how these abilities can be described and combined as a new and in-novative way to frame teaching and learning in astronomy at university level for optimizing the learning outcome of students - what we refer to as developing the ability of Reading the Sky (Eriksson, 2014). We conclude that this is a vital competency needed for learning astronomy and suggest strategies for how to implement this to improve astronomy education.

    References

    Eriksson, Urban. (2014). Reading the Sky - From Starspots to Spotting Stars. (Doctor of Philosophy), Uppsala University, Uppsala. Retrieved from http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-234636  

    Eriksson, Urban, Linder, Cedric, Airey, John, & Redfors, Andreas. (2014a). Introducing the Anatomy of Disciplinary Discernment - An example for Astronomy. European Journal of Science and Mathematics Education, 2(3), 167-182. 

    Eriksson, Urban, Linder, Cedric, Airey, John, & Redfors, Andreas. (2014b). Who needs 3D when the Universe is flat? Science Education, 98(3), 31. 

  • 62.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Nationellt resurscentrum för fysik, Lunds universitet.
    The outer universe and the inner: what is the connection?2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    This talk concerns astronomy eduction resercher and focus on what visualizations offer for learning astronomy at all levels. I will be presenting reserach results concerning disciplinary discernment and spatial thinking in relation to experiences offered by planetarium presentations.

  • 63.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    The spiral of teaching and learning in astronomy education2015Konferensbidrag (Refereegranskat)
    Abstract [en]

    Teaching and learning astronomy is known to be both exciting and challenging. To learn astronomy demands not only disciplinary knowledge, but also ability to discern affordances from disciplinary specific representations used within the discourse, which we call disciplinary dis- cernment (Eriksson, Linder, Airey, & Redfors, 2014a) and ability to think spatially, which we refer to as extrapolating three-dimensionality from a two dimensional input (Eriksson, Linder, Airey, & Redfors, 2014b). Disciplinary knowledge involves all the knowledge that constitutes the discipline, disciplinary discernment involves discernment of the affordances of disciplinary- specific representations, and extrapolating three-dimensionality involves the ability to visualize in ones mind how a three-dimensional astronomical object may look from a two-dimensional input (image or simulation). In this paper we argue that these abilities are intertwined and to learn as- tronomy at any level demands becoming fluent in all three abilities. A framework is presented for how these abilities can be described and combined as a new and innovative way to frame teach- ing and learning in astronomy at university level for optimizing the learning outcome of students - what we refer to as developing the ability of Reading the Sky (Eriksson, 2014). We conclude that this is a vital competency needed for learning astronomy and suggest strategies for how to implement this to improve astronomy education.

  • 64.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    The Spiral of Teaching and Learning in Physics and Astronomy2016Konferensbidrag (Refereegranskat)
    Abstract [en]

    When students start to learn physics and astronomy, they immediately are confronted with a multitude of representations packed with disciplinary information. This information is embedded in these representations and the students need to learn to discern the relevant information. This is not straightforward, and requires a lot of teaching and practice before being mastered. It carries many similarities to learning a new language – the language of physics, astronomy, or other sciences. 

    However, it all starts with disciplinary discernment from those representations, something that has been shown to be challenging for students. Often the teacher who knows the representations and their appresented meaning—their disciplinary affordances—assumes that the students discern the same things in those representations as the teacher does. Research has shown that this is not the case and such assumptions leads to educational problems for the students and make learning physics or astronomy unnecessary difficult, or even inaccessible to the students. The students need be given the opportunity to develop their competency in discerning disciplinary-specific relevant aspects from representations; a competency referred to as Reading the Sky in an astronomy context, and described by the Anatomy of Disciplinary Discernment (Eriksson, 2014a; Eriksson et al., 2014b).

    Furthermore, physics and astronomy are subjects aiming to describe the real multidimensional world, hence involve a substantial amount of spatial thinking. The students need to learn to extrapolate three-dimensionality in their minds from two-dimensional representations, which have been shown to be challenging to students. Unfortunately, this competency is often taken for granted and rarely addressed in teaching (Eriksson et al., 2014c).

    In this talk we present a model in which we identify and describe the critical competencies needed to “read” disciplinary-specific representations; it concerns not only disciplinary discernment but also spatial thinking and disciplinary knowledge. These are combined into the Spiral of Teaching and Learning (STL), a new and powerful model for optimizing teaching and learning science (Eriksson, 2014a; Eriksson, 2015). We discuss consequences and possibilities when applying the STL model and give an example of how this model can be used in teaching and learning astronomy.

  • 65.
    Eriksson, Urban
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Undervisning på distans – framtiden för universitet och högskolor?: ett exempel från astronomiundervisning på Högskolan Kristianstad2016Ingår i: Högskolepedagogisk debatt, ISSN 2000-9216, nr 1, s. 46-73Artikel i tidskrift (Refereegranskat)
    Abstract [sv]

    Dagens studenter är mycket mer flexibla i sina studier än tidigare. Idag läser många studenter kurser på olika universitet och högskolor samtidigt. Detta är möjligt genom att många kurser och program ges på distans via internet. I denna artikel diskuteras de möjligheter och begränsningar som jag anser finns med den undervisningsform som allt mer präglar undervisning vid universitet och högskolor, nationellt och internationellt; distansundervisning.

  • 66.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Lindegren, L.
    Lund Observatory, Lund University.
    Limits of ultra-high-precision optical astrometry: stellar surface structures2007Ingår i: Astronomy and Astrophysics, ISSN 0004-6361, E-ISSN 1432-0746, Vol. 476, nr 3, s. 1389-1400Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    Aims. To investigate the astrometric effects of stellar surface structures as a practical limitation to ultra-high-precision astrometry (e.g. in the context of exoplanet searches) and to quantify the expected effects in different regions of the HR-diagram. Methods. Stellar surface structures (spots, plages, granulation, non-radial oscillations) are likely to produce fluctuations in the integrated flux and radial velocity of the star, as well as a variation of the observed photocentre, i.e. astrometric jitter. We use theoretical considerations supported by Monte Carlo simulations (using a starspot model) to derive statistical relations between the corresponding astrometric, photometric, and radial velocity effects. Based on these relations, the more easily observed photometric and radial velocity variations can be used to predict the expected size of the astrometric jitter. Also the third moment of the brightness distribution, interferometrically observable as closure phase, contains information about the astrometric jitter. Results. For most stellar types the astrometric jitter due to stellar surface structures is expected to be of the order of 10 micro-AU or greater. This is more than the astrometric displacement typically caused by an Earth-size exoplanet in the habitable zone, which is about 1-4 micro-AU for long-lived main-sequence stars. Only for stars with extremely low photometric variability (< 0.5 mmag) and low magnetic activity, comparable to that of the Sun, will the astrometric jitter be of the order of 1 micro-AU, sufficient to allow the astrometric detection of an Earth-sized planet in the habitable zone. While stellar surface structure may thus seriously impair the astrometric detection of small exoplanets, it has in general a negligible impact on the detection of large (Jupiter-size) planets and on the determination of stellar parallax and proper motion. From the starspot model we also conclude that the commonly used spot filling factor is not the most relevant parameter for quantifying the spottiness in terms of the resulting astrometric, photometric and radial velocity variations.

  • 67.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Linder, Cedric
    Uppsala University.
    Airey, John
    Uppsala University.
    Watching the sky: new realizations, new meanings, and surprizing aspects in university level astronomy2011Ingår i: E-Book Proceedings of the ESERA 2011 Conference: Science learning and Citizenship. Part 3: Teaching and learning science / [ed] Catherine Bruguière, Andrée Tiberghien, Pierre Clément, Lyon, France: European Science Education Research Association , 2011, s. 57-63Konferensbidrag (Refereegranskat)
    Abstract [en]

    Learning astronomy is challenging at all levels due to the highly specialized form of communication used to share knowledge. When taking astronomy courses at different levels at university, learners are exposed to a variety of representations that are intended to help them learn about the structure and complexity of the Universe. However, not much is known about the reflective awareness that these representations evoke. Using a simulation video that provides a vivid virtual journey through our Milky Way galaxy, the nature of this awareness is captured and categorised for an array of learners (benchmark by results obtained for experts). The results illustrate how the number and nature of new things grounded in dimensionality, scale, time and perspective reflective awareness can too easily be taken for granted by both teachers and learners.

  • 68.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Linder, Cedric
    Uppsala University.
    Airey, John
    Uppsala University.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Introducing the anatomy of disciplinary discernment: an example from astronomy2014Ingår i: European Journal of Science and Mathematics Education, ISSN 2301-251X, E-ISSN 2301-251X, Vol. 2, nr 3, s. 167-182Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    Education is increasingly being framed by a competence mindset; the value of knowledge lies much more in competence performativity and innovation than in simply knowing. Reaching such competency in areas such as astronomy and physics has long been known to be challenging. The movement from everyday conceptions of the world around us to a disciplinary interpretation is fraught with pitfalls and problems. Thus, what underpins the characteristics of the disciplinary trajectory to competence becomes an important educational consideration. In this article we report on a study involving what students and lecturers discern from the same disciplinary semiotic resource. We use this to propose an Anatomy of Disciplinary Discernment (ADD), a hierarchy of what is focused on and how it is interpreted in an appropriate, disciplinary manner, as an overarching fundamental aspect of disciplinary learning. Students and lecturers in astronomy and physics were asked to describe what they could discern from a video simulation of travel through our Galaxy and beyond. In all, 137 people from nine countries participated. The descriptions were analysed using a hermeneutic interpretive study approach. The analysis resulted in the formulation of five qualitatively different categories of discernment; the ADD, reflecting a view of participants’ competence levels. The ADD reveals four increasing levels of disciplinary discernment: Identification, Explanation, Appreciation, and Evaluation. This facilitates the identification of a clear relationship between educational level and the level of disciplinary discernment. The analytical outcomes of the study suggest how teachers of science, after using the ADD to assess the students disciplinary knowledge, may attain new insights into how to create more effective learning environments by explicitly crafting their teaching to support the crossing of boundaries in the ADD model.  

  • 69.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Linder, Cedric
    Uppsala University.
    Airey, John
    Uppsala University & Linnéuniversitetet.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Tell me what you see: differences in what is discerned when professors and students view the same disciplinary semiotic resource2014Konferensbidrag (Refereegranskat)
    Abstract [en]

    Traditionally, astronomy and physics have been viewed as difficult subjects to master. The movement from everyday conceptions of the world around us to a disciplinary interpretation is fraught with pitfalls and problems. What characterises a disciplinary insider’s discernment of phenomena in astronomy and how does it compare to the views of newcomers to the field? In this paper we report on a study into what students and professors discern (cf. Eriksson et al, in press) from the same disciplinary semiotic resource and use this to propose an Anatomy of Disciplinary Discernment (ADD) as an overarching characterization of disciplinary learning.

    Students and professors in astronomy and physics were asked to describe what they could discern from a simulation video of travel through our Galaxy and beyond (Tully, 2012). In all, 137 people from nine countries participated. The descriptions were analysed using a hermeneutic, constant comparison approach (Seebohm, 2004; Strauss, 1987). Analysis culminated in the formulation of five hierarchically arranged, qualitatively different categories of discernment. This ADD modelling of the data consists of one non-disciplinary category and four levels of disciplinary discernment: Identification, Explanation, Appreciation, and Evaluation. Our analysis demonstrates a clear relationship between educational level and the level of disciplinary discernment.

     

    The analytic outcomes of the study suggest that teachers may create more effective learning environments by explicitly crafting their teaching to support the discernment of various aspects of disciplinary semiotic resources in order to facilitate the crossing of boundaries in the ADD model.

  • 70.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Linder, Cedric
    Uppsala universitet.
    Airey, John
    Uppsala universitet.
    Redfors, Andreas
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    The overlooked challenge of learning to extrapolate three-dimensionality2013Konferensbidrag (Refereegranskat)
    Abstract [en]

    Learning astronomy has many learning challenges due to the highly diverse, conceptual, and theoretical thinking used in the discipline. One taken for granted challenge is the learning to 

    extrapolate three-dimensionality. Although we have the ability to see our surroundings in three- dimensional terms, beyond a distance of about 200m this ability quickly becomes very limited. So, when looking up at the night sky, learning to discern critical features that are embedded in dimensionality does not come easily. There have been several articles addressing how fruitful 3D simulations are for astronomy education, but they do not address what students discern, nor the nature of that discernment. Taking the concept of discernment to be about noticing something and assigning meaning to it, our research question is: In terms of dimensionality, what do astronomy/physics students and professors discern when engaging with a simulated video fly- through of our Galaxy and beyond?

    A web-based questionnaire was designed using links to video clips drawn from a well-regarded simulation-video of travel through our galaxy and beyond. 137 physics and astronomy university students and teaching professors, who were drawn from nine countries, completed the questionnaire. The descriptions provided by them were used to formulate six categories of discernment in relation to multidimensionality. These results are used to make the case that astronomy learning that aims at developing the ability to extrapolate three-dimensionality needs to be grounded in the creation of meaningful motion parallax experiences. Teaching and learning implications are discussed. 

  • 71.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Linder, Cedric
    Uppsala universitet.
    Airey, John
    Uppsala universitet.
    Redfors, Andreas
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    What do teachers of astronomy need to think about?2013Konferensbidrag (Refereegranskat)
    Abstract [en]

    Learning astronomy has exciting prospects for many students; learning about the stars in the

    sky, the planets, galaxies, etc., is often very inspiring and sets the mind on the really big

    aspects of astronomy as a science; the Universe. At the same time, learning astronomy can be

    a challenging endeavor for many students. One of the most difficult things to come to

    understand is how big the Universe is. Despite seeming trivial, size and distances, together

    with the three-dimensional (3D) structure of the Universe, probably present some of the

    biggest challenges in the teaching and learning of astronomy

    (Eriksson, Linder, Airey, &

    Redfors, in preparation; Lelliott & Rollnick, 2010). This is the starting point for every

    astronomy educator. From here, an educationally critical question to ask is: how can we best

    approach the teaching of astronomy to optimize the potential for our students attaining a

    holistic understanding about the nature of the Universe?

    Resent research indicates that to develop students’ understanding about the structure of the

    Universe, computer generated 3D simulations can be used to provide the students with an

    experience that other representations cannot easily provide (Eriksson et al., in preparation;

    Joseph, 2011). These simulations offer disciplinary affordance* through the generation of

    motion parallax for the viewer. Using this background we will present the results of a recent

    investigation that we completed looking at what students’ discern (notice with meaning)

    about the multidimensionality of the Universe. Implications for astronomy education will be

    discussed and exemplified.

    *[T]he inherent potential of [a] representation to provide access to disciplinary knowledge

    (Fredlund, Airey, & Linder, 2012, p. 658)

    Eriksson, U., Linder, C., Airey, J., & Redfors, A. (in preparation). Who needs 3D when the

    Universe is flat?

    Fredlund, T., Airey, J., & Linder, C. (2012). Exploring the role of physics representations: an

    illustrative example from students sharing knowledge about refraction. European

    Journal of Physics, 33(3), 657.

    Joseph, N. M. (2011). Stereoscopic Visualization as a Tool For Learning Astronomy

    Concepts. (Master of Science), Purdue University, Purdue University Press Journals.

    Lelliott, A., & Rollnick, M. (2010). Big Ideas: A review of astronomy education research

    1974--2008. International Journal of Science Education, 32(13), 1771–1799

  • 72.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Linder, Cedric
    Uppsala University.
    Airey, John
    Uppsala University.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Who needs 3D when the universe is flat?2014Ingår i: Science Education, ISSN 0036-8326, E-ISSN 1098-237X, Vol. 98, nr 3, s. 412-442Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    An overlooked feature in astronomy education is the need for students to learn to extrapolate three-dimensionality and the challenges that this may involve. Discerning critical features in the night sky that are embedded in dimensionality is a long-term learning process. Several articles have addressed the usefulness of three-dimensional (3D) simulations in astronomy education, but they have neither addressed what students discern nor the nature of that discernment. A Web-based questionnaire was designed using links to video clips drawn from a simulation video of travel through our galaxy and beyond. The questionnaire was completed by 137 participants from nine countries across a broad span of astronomy education. The descriptions provided by the participants were analyzed using hermeneutics in combination with a constant comparative approach to formulate six categories of discernment in relation to multidimensionality. These results are used to make the case that the ability to extrapolate three-dimensionality calls for the creation of meaningful motion parallax experiences.

  • 73.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Nationellt resurscentrum för fysik, Lunds universitet.
    Pendrill, Anne-Marie
    Lund University.
    Up and down, light and heavy, fast and slow: but where?2019Ingår i: Physics Education, ISSN 0031-9120, E-ISSN 1361-6552, Vol. 54, nr 2Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    Vertical amusement rides let your body experience the tickling sensation of feeling light, but also feeling much heavier than as usual, due to velocity changes as you move up and down. Family rides offer different possibilities to visualize the forces that are experienced by your accelerating body. This paper presents a number of different ways to view and experience the motion in a small vertical amusement ride. A smartphone includes an accelerometer that can provide a graph of the forces acting during the ride. A movie from the smartphone camera lets students recall the motion which can then be analysed in more detail. The complementary representations may help students develop a deeper understanding of the relation between force and motion. The affordances of these different semiotic resources are analysed in some detail. In addition, we discuss responses from a number of students to questions about where you feel light and where you feel heavy. We find that the experience of the body is an underused resource in physics teaching.

  • 74.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Nationellt resurscentrum för fysik, Lunds universitet.
    Pendrill, Ann-Marie
    Nationellt resurscentrum för fysik.
    Up and down, light and heavy, fast and slow: but where?2019Ingår i: Physics Education, ISSN 0031-9120, E-ISSN 1361-6552, Vol. 54, nr 2Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    Vertical amusement rides let your body experience the tickling sensation of feeling light, but also feeling much heavier than as usual, due to velocity changes as you move up and down. Family rides offer different possibilities to visualize the forces that are experienced by your accelerating body. This paper presents a number of different ways to view and experience the motion in a small vertical amusement ride. A smartphone includes an accelerometer that can provide a graph of the forces acting during the ride. A movie from the smartphone camera lets students recall the motion which can then be analysed in more detail. The complementary representations may help students develop a deeper understanding of the relation between force and motion. The affordances of these different semiotic resources are analysed in some detail. In addition, we discuss responses from a number of students to questions about where you feel light and where you feel heavy. We find that the experience of the body is an underused resource in physics teaching.

  • 75.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Lunds universitet.
    Rosberg, Maria
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Disciplinary discernment from Hertzsprung-Russell-diagrams2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    This paper aim at investigating what astronomy students and experts discern from the multitude of different disciplinary affordances available in Hertzsprung-Russell (HR) diagrams. HR-diagrams are central to all of astronomy and astrophysics and used extensively in teaching. However, knowledge about what students and experts discern from these disciplinary representations are not well known at present. HR-diagrams include many disciplinary affordances that may be hidden to the novice student, hence we aim at investigating and describing what astronomy students at different university levels (introductory, undergraduate, graduate), and astronomy educators/professors, discern from such representation – referred to as disciplinary discernment (Eriksson, Linder, Airey, & Redfors, 2014). Data from a web based questionnaire were analysed using the Anatomy of Disciplinary Discernment (ADD) framework by Eriksson et al. (2014). Preliminary results show (1) the developmental nature of disciplinary discernment from the HR-diagram by the participants and (2) the large discrepancy between disciplinary discernment by the astronomy educators and their students. We describe and discuss the qualitative nature of these differences and how this can have implications for teaching and learning astronomy.

  • 76.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Nationellt resurscentrum för fysik, Lunds universitet.
    Rosberg, Maria
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Disciplinary discernment in astronomy education: Hertzsprung-Russell-diagrams2017Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    This paper aim at investigating what astronomy students and experts discern from the multitude of different disciplinary affordances available in Hertzsprung-Russell (HR) diagrams. HR-diagrams are central to all of astronomy and astrophysics and used extensively in teaching. However, knowledge about what students and experts discern from these disciplinary representations are not well known at present. HR-diagrams include many disciplinary affordances that may be hidden to the novice student, hence we aim at investigating and describing what astronomy students at different university levels (introductory, undergraduate, graduate), and astronomy educators/professors, discern from such representation – referred to as disciplinary discernment. Data from a web based questionnaire were analysed using the Anatomy of Disciplinary Discernment (ADD) framework by Eriksson et al.(2014). Preliminary results show (1) the developmental nature of disciplinary discernment from the HR-diagram by the participants and (2) the large discrepancy between disciplinary discernment by the astronomy educators and their students. We describe and discuss the qualitative nature of these differences and implications for teaching and learning astronomy.

  • 77.
    Eriksson, Urban
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Nationellt resurscentrum för fysik, Lunds universitet.
    Steffen, Wolfgang
    UNAM.
    Extrapolation of 3D and its importance for teaching and learning physics and astronomy: an example from astrophysics2019Konferensbidrag (Refereegranskat)
    Abstract [en]

    Learning astronomy at higher level can be both exciting and challenging. Entering the discipline of astronomy involves learning the way that astronomers communicate knowledge, using a multitude of disciplinary specific semiotic recourses to understand the multidimensional universe. A new-to-the-discipline student will need to learn to “read” and “write” all these resources in her endeavour to learn astronomy and become part of the discipline. In this paper, we present a study where university students and professors are presented by different 2D and pseudo-3D resources—representations of astronomical objects—and asked about how these objects may look in 3D, i.e. we ask them to extrapolate three-dimensionality from 2D inputs. These inputs are 2D pictorial representation and world-class 3D rotating volumetric models presented on flat screens. Data were collected using a web-based questionnaire from 53 participants in four different countries. From the results, we find that all participants struggle to find cues for depth perception in the 2D pictorial representations. As could be expected, the student participants were much worse in doing so than the astronomers, but with one exception: students used the offered motion parallax as their main cue when this was available. The astronomers used many cues in their struggle to perceive depth but surprisingly did not use the presented parallax motion to a large extent. We interpret this as follows: for the students, they lack the knowledge to use disciplinary cues and used the only cue that they know from experience, namely, parallax motion. For the astronomers, they used a multitude of disciplinary cues based on their extensive disciplinary knowledge, and did not find the new cue, motion parallax, as useful as the ones that they were used to use. In this paper, we present and discuss these results and its implication for teaching astronomy.

  • 78.
    Eskilsson, Olle
    et al.
    Högskolan Kristianstad, Institutionen för matematik och naturvetenskap.
    Helldén, Gustav
    Högskolan Kristianstad, Institutionen för matematik och naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    A longitudinal study on 10-12-year-olds' conceptions of the transformations of matter2003Ingår i: Chemistry education, ISSN 1109-4028, E-ISSN 1109-4028, Vol. 4, nr 3, s. 291-304Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    The main aim of this project was to study young people’s ability to use science knowledge when talking about and explaining everyday phenomena involving transformations of matter. Students’ individual knowledge was studied both as their spontaneous explanations and as their explanations with appropriate help in discussions with the researcher or with other students. The framework for learning in this study was a social constructivist perspective of learning. In the project students discussed everyday phenomena with peers and with the researcher. The role of the discourse was stressed in the interviews as well as the development of students’ use of their mental models when explaining everyday phenomena. Data were gathered through four interviews with each one of 40 students, between 9 and 11 years of age.. The development of the basic particle model was one of the themes during the instructional units. Other recurrent themes were states of matter, gases and chemical reaction. Most of the students were able to use knowledge of science when talking about known everyday phenomena. Almost all of the students in the group developed the use of their own mental models during the project.

  • 79.
    Eskilsson, Olle
    et al.
    Högskolan Kristianstad, Institutionen för matematik och naturvetenskap.
    Redfors, AndreasHögskolan Kristianstad, Institutionen för matematik och naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Ämnesdidaktik ur ett nationellt och internationellt perspektiv: rapport från Rikskonferensen i ämnesdidaktik 20062007Konferensmeddelanden, proceedings (Övrigt vetenskapligt)
    Abstract [en]

    Den 4-5 maj 2006 anordnade Högskolan Kristianstad i samarbete med det nationella nätverket för ämnesdidaktik Ämnesdidaktik ur ett nationellt och internationellt perspektiv, den tredje Rikskonferensen i ämnesdidaktik.

    Den ämnesdidaktiska forskningen syftar till att öka kunskapen om undervisning och lärande i specificerade och tydligt avgränsade ämnesinnehåll. Den söker inte efter innehållsoberoende beskrivningar på en generell nivå, utan istället karakteriseras forskningen av en insikt om det specifika innehållets avgörande betydelse för lärande och undervisning.

    Konferens genomfördes i nätverkets anda och såväl ämnesspecifika som ämnesblandade sessioner genomfördes. Stimulerande diskussioner upp­kommer då forskare från olika ämnens ämnesdidaktik träffas och bryter perspektiv. Ett internationellt perspektiv var speciellt i fokus denna gång.

    På konferensen gavs sex plenarföreläsningar och det presenterades ca 60 forskningsprojekt om lärande och undervisning i skola och högskola av författare från de nordiska länderna. Huvuddelen av svenska högskolor och universitet var representerade. Nationella, nordiska och internationella projekt presenterades och diskuterades.

    I denna konferensbok presenteras ett urval av de på konferensen presenterade projekten. Urvalet är baserat på kvalitet och representativitet.

  • 80.
    Freij, Maria
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Humaniora.
    Edfors, Ellinor
    Högskolan Kristianstad, Fakulteten för hälsovetenskap, Forskningsmiljön PRO-CARE, Patient Reported Outcomes - Clinical Assessment Research and Education. Högskolan Kristianstad, Fakulteten för hälsovetenskap, Avdelningen för sjuksköterskeutbildningarna och integrerad hälsovetenskap. Högskolan Kristianstad, Forskningsplattformen för Hälsa i samverkan.
    Ljung Djärf, Agneta
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Umans, Timurs
    Högskolan Kristianstad, Fakulteten för ekonomi, Forskningsmiljön Auditing, Organisation and Society (AOS). Högskolan Kristianstad, Fakulteten för ekonomi, Avdelningen för ekonomi.
    Rehnstam-Holm, Ann-Sofi
    Högskolan Kristianstad, Fakulteten för naturvetenskap, Forskningsmiljön Man & Biosphere Health (MABH). Högskolan Kristianstad, Fakulteten för naturvetenskap, Avdelningen för miljö- och biovetenskap.
    Pedagogisk karriärstege vid Högskolan Kristianstad: några reflektioner från beredningsgruppens arbete2014Konferensbidrag (Övrigt vetenskapligt)
  • 81.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Jonsson, Agneta
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för utbildningsvetenskap inriktning fritidshem och förskola. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Thulin, Susanne
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Teaching Chemistry and Physics in Preschool: a Matter of Establishing Intersubjectivity2019Ingår i: International Journal of Science Education, ISSN 0950-0693, E-ISSN 1464-5289Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    This paper describes analysis of teaching instances that are part of an in-service preschool teachers programme about chemistry and physics in preschool. The aim is to develop knowledge about the communication established between teacher and children in relation to an object of learning, specifically the role of intersubjective communication in relation to an object of learning. A set of science activities with a specified object of learning was developed in groups of teachers and researchers. A qualitative analysis of the communication in relation to the chosen object of learning was performed. The focus of the analysis was excerpts representing differences in intersubjectivity related to the object of learning and what can be said to characterise the communication between teachers and children in these situations. The results show that intersubjectivity can occur in different ways with different consequences for children’s opportunities to experience the intended object of learning. In connection to this, the importance of teachers having a mutual simultaneity in the communication with children about a specific content is highlighted. The teachers have to create links between the child’s perspective and the object of learning. Intermediary objects of learning are discussed as supporting elements in the conquest of new knowledge.

  • 82.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Högskolan Kristianstad, Forskningsplattformen Lärande i samverkan.
    Jonsson, Agneta
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för utbildningsvetenskap inriktning fritidshem och förskola. Högskolan Kristianstad, Forskningsplattformen Lärande i samverkan.
    Steen, Ann
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för utbildningsvetenskap inriktning fritidshem och förskola.
    Thulin, Susanne
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för utbildningsvetenskap inriktning fritidshem och förskola. Högskolan Kristianstad, Forskningsplattformen Lärande i samverkan.
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Högskolan Kristianstad, Forskningsplattformen Lärande i samverkan.
    Undervisning och lärande i förskolan om kemi- och fysikrelaterade vardagsfenomen2018Konferensbidrag (Refereegranskat)
    Abstract [sv]

    Genom ett flerårigt projekt studeras modellbaserad undervisning och lärande i förskolor av kemiska reaktioner och fysikaliska fenomen relaterat till hållbarhet i samhällsfrågor. Forskare arbetar tillsammans med ledning och personal vid förskolor i ett skolområde. Undervisning och lärandeprocesser med och utan stöd av modern informationsteknik implementeras och analyseras. Projektet syftar till att utveckla en teoretisk ram för analys av olika erfarenheter under kemi- och fysikunder­visning i förskolan med fokus på lärarens förhållningssätt och barns agerande. I samverkan utvecklas nuvarande kunskap om hur ny digital teknik kan användas för att stödja samarbete och lärande om kemiska processer och fysikaliska fenomen relaterade till barns vardag och dagens samhälle. 

  • 83.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Children’s collaborative learning in science scaffolded by tablets2017Ingår i: Digital Childhoods: technologies and children's everyday lives / [ed] Susan Jill Danby, Marilyn Fleer, Christina Davidson, Maria Hatzigianni, Singapore: Springer, 2017Kapitel i bok, del av antologi (Övrigt vetenskapligt)
  • 84.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Naturvetenskap och datorplattor – i barnens regi2016Ingår i: Naturvetenskap i ett förskoleperspektiv: kreativa lärandeprocesser / [ed] Susanne Thulin, Malmö: Gleerups Utbildning AB, 2016, s. 105-124Kapitel i bok, del av antologi (Övrigt vetenskapligt)
  • 85.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Thulin, Susanne
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Children’s collaborative learning of evaporation scaffolded by iPads2015Konferensbidrag (Refereegranskat)
    Abstract [en]

    This paper reports on a project aiming to extend the current understanding of how emerging technologies, i.e. iPads, can be used in pre-schools to support collaborative learning of real-life science phenomena. The importance of this is associated with the “west world” problem of current educational systems to respond to the needs of modern youth. Educational systems are currently in need of reform (Fullan, 2007, Thulin, 2011; Tytler, 2007). Research on the potential of web-based technologies to support collaborative inquiry-based science learning in schools, with a special interest in inquiry-based science learning is here continued by investigating the role of time-lapse and stop-motion animations in developing children’s understanding of science phenomena. We report on a study of groups of children working with evaporation. A video-based qualitative analysis of the communication in the pre-school groups has given rise to a number of categories used to distinguish and identify variations of children’s expressed experiences in discussions during group work in different contexts. An enhanced and focused reasoning about the natural science phenomenon in group discussions where the iPad is involved and used for stimulated recall is reported. Furthermore, it is shown that children communicate extensively about practical issues and problem solving, in stop-motion producing contexts, but less about the science phenomenon. However, when the children participate in real-time experimentation, the communication focuses more around the phenomenon itself and less about practical issues. Hence, again establishing the importance of real-time experimentation for children’s science learning. The analysis of the empirical data from the first phase of the project is on going and will be completed during the first months of 2015.  The final results will be presented at the conference.

  • 86.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Thulin, Susanne
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Science in early childhood education: children and tablets2016Konferensbidrag (Refereegranskat)
    Abstract [en]

    Research aims

    To extend current understanding of how emerging technologies, i.e tablets, can be used in pre-schools to support collaborative learning of real-life science phenomena.

    Relationship to previous research works

    We continue our study of the potential of tablets as scaffolds in collaborative inquiry-based science

    learning in preschools. We investigate the role of Timelapse photography and Slowmation production in scaffolding communication and learning during work with light and shadow. The teaching attempts to synthesise the two domains defined by Eshach (2006) for children´s science learning: content and

    investigations.

    Theoretical and conceptual framework

    The theoretical framework is primarily based on phenomenography focusing on developmental pedagogy. (Marton & Booth, 1997, Pramling Samuelsson & Asplund Carlsson, 2008).

    Paradigm, methodology and methods

    Design-based research (Barab & Squire, 2004) is used to bridge the worlds of academia with the realities of educational practice, to foster viable practices. A mixed-methods approach, including video and qualitative and quantitative data measures is used.

    Ethical Considerations

    The research will adhere to the ethical guidelines of the Swedish Research Council. All participants and children’s caregivers are informed and agree to voluntary and anonymous participation with a right to abandon participation.

    Main finding or discussion

    In this paper we report on an on-going project where children investigate light and shadow by constructing, discussing, formulating and using explanatory models during work with time-lapse and Slowmations. (Fridberg et al. 2016).

    Implications, practice or policy

    The potential of teachers, students and researchers jointly developing, enacting and evaluating learning processes supported by ubiquitous technologies in pre-school will be discussed. Slowmation production focus explanatory models of science experiences and elicits critical aspects of the learning object.

  • 87.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Thulin, Susanne
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    The role of science in Swedish pre-schools: children’s collaborative learning scaffolded by iPads2014Konferensbidrag (Refereegranskat)
    Abstract [en]

    To extend current understanding of how emerging technologies, i.e. iPads, can be used in pre-schools to support collaborative learning of real-life science phenomena. Research on the potential of web-based technologies to support collaborative inquiry-based science learning in schools (Redfors et al. 2013) is continued by investigating the role of stop-motion animations (Fleer, 2013, Hoban, 2007) in developing children’s understanding of science phenomena, by synthesising the two domains defined by Eshach (2006) for kids’ science learning, content and investigations. The theoretical framework is primarily based on phenomenography focusing on developmental pedagogy (Marton & Booth, 1997, Pramling Samuelsson & Asplund Carlsson, 2008). Design-based research (Barab & Squire, 2004) is used to bridge the worlds of academia and theory with the realities, complexities, and constraints of educational practice, and foster viable practices. A mixed-methods approach, including video and qualitative and quantitative data measures is used. The research adheres to the ethical guidelines of the Swedish Research Council. All participants and children’s caregivers are informed and agree to voluntary and anonymous participation with a right to abandon participation. In this paper we report on the first phase of the project where videos of children’s work with constructing and discussing time-lapse and stop motion sequences of science phenomena have been analysed within our theoretical framework. Stop-motion animations (Fleer 2013) help children, teachers and students to more consciously consider concepts. We see a great potential in work where teachers, students and researchers jointly develop, enact and evaluate learning processes supported by ubiquitous technologies in pre-school.

  • 88.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Thulin, Susanne
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Preschool children's collaborative science learning scaffolded by tablets2017Ingår i: Research in science education, ISSN 0157-244X, E-ISSN 1573-1898, Vol. 48, nr 5, s. 1007-1026Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    This paper reports on a project aiming to extend the current understanding of how emerging technologies, i.e. tablets, can be used in preschools to support collaborative learning of real-life science phenomena. The potential of tablets to support collaborative inquiry-based science learning and reflective thinking in preschool is investigated through the analysis of teacher-led activities on science, including children making timelapse photography and Slowmation movies. A qualitative analysis of verbal communication during different learning contexts gives rise to a number of categories that distinguish and identify different themes of the discussion. In this study, groups of children work with phase changes of water. We report enhanced and focused reasoning about this science phenomenon in situations where timelapse movies are used to stimulate recall. Furthermore, we show that children communicate in a more advanced manner about the phenomenon, and they focus more readily on problem solving when active in experimentation or Slowmation producing contexts.

  • 89.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap.
    Thulin, Susanne
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Preschool children’s collaborative science learning scaffolded by tablets: a teachers view2017Konferensbidrag (Övrigt vetenskapligt)
  • 90.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Thulin, Susanne
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för utbildningsvetenskap inriktning fritidshem och förskola.
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Pre­school children’s collaborative science learning scaffolded by tablets – a teacher’s view2018Ingår i: Journal of Emergent Science, ISSN 2046-4754, E-ISSN 2046-4754, nr 15, s. 13-19Artikel i tidskrift (Refereegranskat)
  • 91.
    Fridberg, Marie
    et al.
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Thulin, Susanne
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Jonsson, Agneta
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Barndom, Lärande och Utbildning (BALU).
    Chemistry and physics in preschool –: teaching and learning through socio-scientific issues2018Konferensbidrag (Övrigt vetenskapligt)
  • 92.
    Galway, Lindsay P
    et al.
    Canada.
    Beery, Thomas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för naturvetenskap, Forskningsmiljön Man & Biosphere Health (MABH).
    Jones-Casey, Kelsey
    USA.
    Tasala, Kirsti
    Canada.
    Mapping the solastalgia literature: a scoping review study2019Ingår i: International Journal of Environmental Research and Public Health, ISSN 1661-7827, E-ISSN 1660-4601, Vol. 16, nr 15Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    Solastalgia is a relatively new concept for understanding the links between human and ecosystem health, specifically, the cumulative impacts of climatic and environmental change on mental, emotional, and spiritual health. Given the speed and scale of climate change alongside biodiversity loss, pollution, deforestation, unbridled resource extraction, and other environmental challenges, more and more people will experience solastalgia. This study reviewed 15 years of scholarly literature on solastalgia using a scoping review process. Our goal was to advance conceptual clarity, synthesize the literature, and identify priorities for future research. Four specific questions guided the review process: (1) How is solastalgia conceptualized and applied in the literature?; (2) How is solastalgia experienced and measured in the literature?; (3) How is 'place' understood in the solastalgia literature?; and (4) Does the current body of literature on solastalgia engage with Indigenous worldviews and experiences? Overall, we find there is a need for additional research employing diverse methodologies, across a greater diversity of people and places, and conducted in collaboration with affected populations and potential knowledge, alongside greater attention to the practical implications and applications of solastalgia research. We also call for continued efforts to advance conceptual clarity and theoretical foundations. Key outcomes of this study include our use of the landscape construct in relation to solastalgia and a call to better understand Indigenous peoples' lived experiences of landscape transformation and degradation in the context of historical traumas.

  • 93.
    Granklint Enochson, Pernilla
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Helldén, Gustav
    Högskolan Kristianstad, Sektionen för lärande och miljö. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Lindahl, Britt
    Högskolan Kristianstad, Institutionen för matematik och naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Students' understanding about the function of human body in relation to their own health2007Konferensbidrag (Refereegranskat)
  • 94.
    Granklint Enochson, Pernilla
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Helldén, Gustav
    Högskolan Kristianstad, Sektionen för lärande och miljö. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Lindahl, Britt
    Högskolan Kristianstad, Institutionen för matematik och naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Students' understanding about the water transportation in the human body and their understanding of why water is healthy for them2008Konferensbidrag (Refereegranskat)
  • 95.
    Granklint Enochson, Pernilla
    et al.
    Linnéuniversitetet.
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Dempster, Edith R.
    Sydafrika.
    Tibell, Lena
    Linköpings universitet.
    Ideas about the human body among secondary students in South Africa2015Ingår i: African Journal of Research in Mathematics, Science and Technology Education, ISSN 1028-8457, Vol. 19, nr 2, s. 199-211Artikel i tidskrift (Refereegranskat)
    Abstract [en]

    In this paper we focus on how South African students’ ideas about the human body are constituted in their descriptions of three different scenarios involving the pathway of a sandwich, a painkiller and a glass of water through the body. In particular, we have studied the way in which the students transferred ideas between the sandwich and the painkiller compared with the students’ ability to explain the water pathway. The study surveyed 161 ninth-grade students in five different schools in South Africa. Data collection methods used were: drawings, written questions (open-ended items) and interviews with selected students. The questions emerged from the three scenarios — what happens in the body when you eat a sandwich, swallow a painkiller and drink a glass of water. We report that it is difficult for the students to transfer knowledge of the digestive system horizontally from the sandwich scenario to descriptions of the painkiller and water scenarios. The integration of three organ systems (digestive, circulatory and excretory) to describe the water scenario was even more difficult for the students than the horizontal transfer from the sandwich scenario. The students also showed a diversity of non-scientific descriptions, especially concerning the water scenario. The paper discusses why a large percentage of the students (∼50%) included non-scientific ideas in their descriptions of the water scenario.

  • 96.
    Granklint Enochson, Pernilla
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Redfors, Andreas
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Tibell, L.
    Linköpings universitet, Tekniska högskolan.
    Dempster, E.
    University of KwaZulu-Natal, South Africa.
    Similarities and differences in students' ideas about the human body and health in South Africa and SwedenManuskript (preprint) (Övrigt vetenskapligt)
    Abstract [en]

    In both Sweden and South Africa, the science curriculum for the secondary level emphasizes learning about the functioning of the human body. Both curricula also emphasize the importance of living a healthy life. In this paper the focus is on how students’ ideas about the human body are constituted in explanations of three different scenarios, and in what way the students are transferring explanations between these scenarios. The study surveyed 161 9th grade students in five different schools in South Africa, and discusses the results in perspective of a previous study involving 88 students in Sweden. In both countries issues about body and health are discussed in several different subjects in school. The same data collection methods were used in both countries: drawings, written questions (open-ended and multiple-choice items), and interviews with selected students. The questions emerge from three scenarios: what happens in the body when you eat an open sandwich, drink water, and swallow a painkiller. We report that it is difficult for the students to horizontally transfer knowledge of the digestive system to other less well-known scenarios. In comparing the use of three systems in the painkiller-scenario to the horizontal transfer between the sandwichand the painkiller-scenarios we see that the difference is much less pronounced in South African results compared to the Swedish study. There are more similarities than differences between the results of this South Africa study and results obtained in Europe, but there are also differences especially with regard to non-scientific ideas about the human body.

  • 97.
    Greca, Ileana
    et al.
    Spain.
    García Terceño, Eva
    Spain.
    Cronquist, Björn
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Fridberg, Marie
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Robotics and STEM education for 4-8 y.o. children in Spanish Pre and Primary schools.2019Konferensbidrag (Refereegranskat)
    Abstract [en]

    botSTEM is an ERASMUS+ project aiming to raise the utilisation of inquiry-based collaborative learning and robots-enhanced education. The project outputs are specifically aimed to provide in- and pre-service teachers in Childhood and Primary Education and children aged between 4 and 8, with research-based materials and best practices that use integrated Science, Technology, Engineering, Mathematics (STEM) and robot-based approaches, including code-learning, for enhancing scientific literacy in young children. Initial results from the project from a qualitative analysis of implemented activities during science teaching in preschools in Spain are presented here. Despite the possible obstacles that preschool teachers initially expressed, the preliminary analysis of the implementations indicates that the proposed STEM integrated framework, including inquiry teaching and engineering design methodologies, can be used with kids as young as 4 y.o. In the case of a project about magnets, the children seem to have improved/used? some scientific ideas, applied these ideas to design a magnetic toy and learnt about spatial orientation through use of robots. Also, the development of the project seems have allowed a fruitful intersubjective communication between teachers and students.

  • 98.
    Greca, Ileana M.
    et al.
    Spanien.
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Cronquist, Björn
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Fridberg, Marie
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Robotics and STEM education for children and primary schools – botSTEM2018Konferensbidrag (Övrigt vetenskapligt)
    Abstract [en]

    BotSTEM is an ERASMUS+ project aiming to raise the utilisation of inquiry-based collaborative learning and robots-enhanced education. The project outputs are specifically aimed to provide in- and pre-service teachers in Childhood and Primary Education and children aged between 4 and 8, with research-based materials and best practices that use integrated Science Technology Engineering Mathematics (STEM) and robot-based approaches, including  code-learning, for enhancing scientific literacy in young children. Initial results from the project will be presented at the conference. 

  • 99.
    Greca, Ileana
    et al.
    Spain.
    Redfors, Andreas
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Cronquist, Björn
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik. Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Fridberg, Marie
    Högskolan Kristianstad, Fakulteten för lärarutbildning, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Fakulteten för lärarutbildning, Avdelningen för matematik- och naturvetenskapernas didaktik.
    Robotics and STEM education for 4-8 y.o children and primary schools2019Ingår i: EU corner, 2019Konferensbidrag (Övrigt vetenskapligt)
  • 100.
    Green, Jenny
    et al.
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Juter, Kristina
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Jönsson, Anders
    Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Naturvetenskap. Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA).
    Ottosson, Torgny
    Högskolan Kristianstad, Forskningsmiljön Learning in Science and Mathematics (LISMA). Högskolan Kristianstad, Sektionen för lärande och miljö, Avdelningen för Pedagogik.
    Formative mathematics assessment in upper secondary school2014Ingår i: Proceedings of the 38 th Conference of the International Group for the Psychology of           Mathematics Education in Vancouver, Canada 2014 / [ed] P. Liljedahl, C Nicol, S. Oesterle & D. Allan, 2014, Vol. 6, s. 312-312Konferensbidrag (Övrigt vetenskapligt)
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