028265 Science Teaching Methods 3

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Subject handbook information prior to 2025 is available in the Archives.

UTS: Education: Initial Teacher Education
Credit points: 6 cp
Result type: Grade, no marks

Requisite(s): (028263 Science Teaching Methods 1 AND (72 credit points of completed study in spk(s): C10350 Bachelor of Arts Bachelor of Education OR 72 credit points of completed study in spk(s): C10349 Bachelor of Education (Primary) Bachelor of Arts International Studies OR 72 credit points of completed study in spk(s): C10444 Bachelor of Education Bachelor of Languages and Cultures))
These requisites may not apply to students in certain courses. See access conditions.
Anti-requisite(s): 013421 Science Teaching Methods 3 AND C10209 Bachelor of Educational Studies

Description

This subject develops pre-service teacher knowledge and understanding of the nature of assessment and reporting and the relationship to learning. In this subject, students analyse and evaluate different purposes and approaches to assessment and underlying principles. Pre-service teachers develop an understanding of the key role of assessment in syllabus and performance standards to ensure quality learning experiences and achievement. Pre-service teachers develop an understanding of how teaching, learning, assessment, feedback and reporting can be aligned and integrated in practice, including summative and formative assessment, the nature and role of syllabus outcomes in the planning of integrated teaching, learning and assessment programs. Students develop a philosophy of teaching science, taking account of current syllabuses and policies, and demonstrate understanding of the professional insights and demands of the practicing science teacher.

Subject learning objectives (SLOs)

a.	Identify, analyse and evaluate a range of approaches to assessing student learning (GTS 5.1.1);
b.	Construct and apply effective assessment strategies to assess student learning (GTS 2.3.1; 5.1.2; 5.3.1; 5.4.1);
c.	Analyse and evaluate curriculum and resources for inclusion in effective teaching programs (GTS 2.2.1;2.3.1);
d.	Identify and apply effective methods of feedback to students about learning (GTS 5.2.1);
e.	Design, organise and evaluate methods and materials for science teaching including lessons, sequences and units (GTS 2.2.1; 2.3.1)
f.	Clear and precise language use (6.2.1).

Course intended learning outcomes (CILOs)

This subject engages with the following Course Intended Learning Outcomes (CILOs), which are tailored to the Graduate Attributes set for all graduates of the Faculty of Arts and Social Sciences.

• Design and conduct effective learning activities, assess and evaluate learning outcomes and create and maintain supportive and safe learning environments (GTS 1, 2, 3, 4, 5) (1.2)
• Analyse and synthesise research and engage in inquiry (GTS 3) (2.1)
• Make well-informed contributions to contemporary debates pertinent to education (GTS 3) (2.2)
• Communicate effectively using diverse modes and technologies (GTS 2, 3, 4) (6.1)

Contribution to the development of graduate attributes

This subject addresses the following Course Intended Learning Outcomes:

1. Professional Readiness
1.2 Design and conduct effective learning activities, assess and evaluate learning outcomes and create and maintain supportive and safe learning environments (GTS 1, 2, 3, 4, 5)

2. Critical and Creative Inquiry
2.1 Analyse and synthesise research and engage in inquiry (GTS 3)
2.2 Make well-informed contributions to contemporary debates pertinent to education (GTS3)

6. Effective Communication

6.1 Communicate effectively using diverse modes and technologies (GTS 2, 3, 4)

Teaching and learning strategies

The teaching/learning strategies employed in this subject will include lecturer input, structured discussion, workshop activities, individual research, lesson presentation by students, evaluation by students of presentations, development of assessment strategies with revision of this in light of practicum experiences, and assignments which critically examine and apply current thinking in teaching and learning in science. Students will undertake individual inquiry and engage in discussion to develop and clarify competing frameworks for science education. Students will receive ongoing formative feedback throughout the semester. Tutorials provide a forum for students to receive ongoing peer and tutor feedback. Students will also receive written feedback on an informal task conducted in week 2 before submitting task 1 in week 5. Students will then receive further feedback on task 1 prior to submitting task 2.

Content (topics)

This is the third of the four Science Teaching Methods subjects. In this subject, students synthesise their prior learning about each of the following aspects of teaching:

• The principles underpinning the NSW curriculum; the NSW Science syllabuses and their relationship to the Australian curriculum;
• Developing familiarity with, and knowledge of, the science syllabuses;
• Key terms in assessment;
• Investigate ways to interpret student assessment data to evaluate student learning and modify teaching practice;
• Assessment ‘for’, ‘of’ and ‘as’ learning;
• Standards referencing, norm referencing etc;
• The teaching and assessment cycle;
• Informal and formal assessments;
• Diagnostic, formative and summative assessments;
• How to assess syllabus outcomes;
• Assessment/adjustments for a range of students (eg. special needs; EAL/D);
• Reliability and validity in assessment;
• Meaningful and useful feedback to students;
• Using authentic work samples.

Assessment

Assessment task 1: Developing Assessment Tasks for Stage 6 Science

Objective(s):	a, b, c, d and f
Weight:	50%
Length:	1500 words, excluding references
Criteria linkages:	Criteria Weight (%) SLOs CILOs Appropriate resources selection for the course 25 b, f 1.2 Clarity of explanation for choice of resources 25 a, c 2.2 Appropriateness of assessment task/strategies: informal and formal, diagnostic, formative and summative approaches 25 a, b, c 1.2 Clarity of explanation regarding appropriate and timely feedback to students 25 d 6.1 SLOs: subject learning objectives CILOs: course intended learning outcomes

Assessment task 2: Assessing student writing samples

Objective(s):	a, b, d and e
Weight:	50%
Length:	Equivalent of 1500 words.
Criteria linkages:	Criteria Weight (%) SLOs CILOs Clear and appropriate guidelines and criteria 20 a, b 1.2 Accurate assessment of samples 20 b 2.2 Clear and concise summative comments 20 b, e 2.2 Evidence of sound knowledge of evaluating assessments to potentially modify teaching practice 20 b 2.1 Clear, accurate and concise justification 20 b, d 6.1 SLOs: subject learning objectives CILOs: course intended learning outcomes

Minimum requirements

All assessment tasks in the subject must be passed in order to pass the subject because they critically assess key Graduate Teaching Standards that pre-service teachers must achieve.

Required texts

https://educationstandards.nsw.edu.au/wps/portal/nesa/k-10/learning-areas/science/science-7-10- 2018

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/biology-2017

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/chemistry-2017

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/earth-and-environmental-science-2017

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/investigating-science-2017

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/physics-2017

https://educationstandards.nsw.edu.au/wps/portal/nesa/11-12/stage-6-learning-areas/stage-6- science/science-extension-syllabus

References

Amos, S. (Ed.). (2002). Teaching science in secondary schools. London: Open University Press.

Aubusson, P. J., Harrison, A. G., & Ritchie, S M. (Eds.). (2006). Metaphor and analogy in science education. Dordrecht: Springer.

Biddulph, F. & Osborne, R. (1984). Making sense of our world: an interactive teaching approach. Hamilton: Science Education Research Unit, University of Waikato.

Corrigan, D., Gunstone, R. & Jones, A. (Eds.) (2013). Valuing Assessment in Science Education:Pedagogy, Curriculum, Policy. Dordrecht: Springer

Cothron, J. H., Giese, R. N. & Rezba, R J. (2000). Students and research: practical strategies for science classrooms and competitions. Dubuque, Iowa: Kendall.

Dawson, V. & Venville, G. (Eds.) (2012). The art of teaching science: For middle and secondary school. Sydney, Australia: Allen and Unwin

Fraser, B. J., Tobin, K. & McRobbie , C. (Eds.). (2011). Second international handbook of science education. Dordrecht: Springer.

Llewellyn, D. (2011). Differentiated science inquiry. Thousand Oaks, CA: Corwin Press.

Mortimer, E. F., & El-Hani, C. N. (Eds.) (2014). Conceptual profiles: A theory of teaching and learning scientific concepts. Dordrecht: Springer.

Ng, W. (2012). Empowering Science Literacy through Digital Literacy and Multiliteracies. New York: Nova Science Publishers.

Gott, R. & Duggan, S. (1995). Investigative work in the science curriculum. Buckingham: Open University Press.

Heywood, D &,Parker, J. (2010). The pedagogy of physical science. Dordrecht: Springer.

Rhoton, J. & Shane, P. (2006). Teaching science in the twenty-first century. Arlington: NASTA

Millar, M. Leach, A. & Osborne, J. (Eds.). (2000). Improving science education: The contribution of research. Phildelphia: Open University Press.

Monk, M. & Osborne, J. (Eds.). (2000). Good practice in science teaching: What research has to say. Buckingham: Open University Press.

Osborne, R. & Freyberg, P. (1985). Learning in science: The implications of children's science. Auckland: Heinemann.

Reiss, M. (2000). Understanding science lessons: a longitudinal study Philadelphia: Open University Press.

Ross, K, Lakin, L. & Mckechnie. (2010). Teaching secondary science: Constructing meaning and developing understanding. London:

Sadler, T. D. (Ed.). (2011). Socio-scientific issues in the classroom. Dordrecht: Springer.

Roth, W. (1995). Authentic science: knowing and learning in open-inquiry science laboratories. Dordrecht: Kluwer.

Venville, G., & Dawson, V. (Eds.). (2004). The art of teaching science. Sydney: Allen and Unwin.

Wellington, J. (2000). Teaching and learning secondary science. London: Routledge.