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NCEA Education
23/3/2023 11:24 AM  |  Science  |  https://ncea.education.govt.nz/science/science

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  • What is Science about?
  • Big Ideas and Significant Learning
  • Key Competencies in Science
  • Connections
  • Learning Pathway
[ Previous Learning Matrices ]

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  • Title: Draft for Pilot 2023
  • Description: Science Learning Matrix
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Past Matrices

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  • Title: Draft for Pilot 2022
  • Description: Science Learning Matrix
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    • Description: Science Learning Matrix
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Draft for Pilot 2022

Science Learning Matrix
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Current Learning Matrix:

[ File Resource ]

  • Title: Draft for Pilot 2023
  • Description: Science Learning Matrix
  • File URL: https://ncea-live-3-storagestack-53q-assetstorages3bucket-2o21xte0r81u.s3.amazonaws.com/s3fs-public/2022-12/SC%20Learning%20Matrix_2.pdf?VersionId=yzLp9_DeyopGMD91F1u0c1fyK8E0ZeLl
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  • Draft for Pilot 2023.pdf
    • Description: Science Learning Matrix
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Draft for Pilot 2023

Science Learning Matrix
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pdf  |  214KB Download Download Download

Past Matrices:

[ File Resource ]

  • Title: Draft for Pilot 2022
  • Description: Science Learning Matrix
  • File URL: https://ncea-live-3-storagestack-53q-assetstorages3bucket-2o21xte0r81u.s3.amazonaws.com/s3fs-public/2022-12/SC%20Learning%20Matrix_0.pdf?VersionId=SNyDNLFusFjIx2JsomP85V8_2aK.0H7O
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  • Draft for Pilot 2022.pdf
    • Description: Science Learning Matrix
Download
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Draft for Pilot 2022

Science Learning Matrix
Science Learning Matrix
pdf  |  209KB Download Download Download

[ File Resource ]

  • Title: Draft for Pilot 2023
  • Description: Science Learning Matrix
  • File URL: https://ncea-live-3-storagestack-53q-assetstorages3bucket-2o21xte0r81u.s3.amazonaws.com/s3fs-public/2022-12/SC%20Learning%20Matrix_2.pdf?VersionId=yzLp9_DeyopGMD91F1u0c1fyK8E0ZeLl
  • File Extension: pdf
  • File Size: 214KB
  • Draft for Pilot 2023.pdf
    • Description: Science Learning Matrix
Download
Download

Draft for Pilot 2023

Science Learning Matrix
Science Learning Matrix
pdf  |  214KB Download Download Download

[ File Resource ]

  • Title: Draft for Pilot 2022
  • Description: Science Learning Matrix
  • File URL: https://ncea-live-3-storagestack-53q-assetstorages3bucket-2o21xte0r81u.s3.amazonaws.com/s3fs-public/2022-12/SC%20Learning%20Matrix_0.pdf?VersionId=SNyDNLFusFjIx2JsomP85V8_2aK.0H7O
  • File Extension: pdf
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  • Draft for Pilot 2022.pdf
    • Description: Science Learning Matrix
Download
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Draft for Pilot 2022

Science Learning Matrix
Science Learning Matrix
pdf  |  209KB Download Download Download

What is Science about?

[ Video Resource ]

  • Title: Science
  • Description: Science Subject Expert Group members discuss their experiences in the Review of Achievement Standards
  • Video Duration: 5 minutes
  • Video URL: https://player.vimeo.com/video/571925804
  • Transcript: In conversation with Sabina Cleary Andrea Tritton Faye Booker Transcript below: I think

Subject-specific terms can be found in the glossary.

Science involves generating and testing ideas and gathering evidence to understand, explain, and develop knowledge about the natural world. Scientists do this by making observations, carrying out investigations and modelling, and by communicating and debating with others.

Scientific thinking does not belong to one culture. It is a global collection of understandings that have come from logical, systematic work, and from creative insight built on a foundation of respect for evidence.

Scientific progress comes from questioning that knowledge and how it is applied, so that new evidence and different perspectives can contribute to the global understanding of our natural world.

In Aotearoa New Zealand, Science uses the nature of science strand from the New Zealand Curriculum to teach ākonga what science is, and how scientists work. Ākonga will develop their scientific literacy, and their understanding of mātauranga Māori as a body of knowledge that both supports and challenges scientific thinking.

Science learning is theoretical and practical. It has diverse areas of specialization with internationally recognised symbols, languaging and conventions. Through developing science literacies and inquiry methods, and understanding different knowledge systems and perspectives, ākonga will be further empowered to make decisions, and take action in an ever-changing local and global landscape.

Whakataukī

Mā te whakaaro nui e hanga te whare; mā te mātauranga e whakaū.

Big Ideas create the house; knowledge maintains it.

The Science Learning Area whakataukī draws on the image of the wharenui to describe important ideas. This is significant in several ways.

Before the wharenui is built, the foundation must be firm and level. In science, respect for evidence is the foundation on which all ideas are built. The wharenui is constructed using various materials, and each serves a specific purpose with its own uniqueness. A poupou (wall post) is not the same as a heke (rafter), but they are joined and connected to make one wharenui. Science is also made of various disciplines, with their own properties, that focus on different areas of knowledge. The different areas of science connect and overlap to strengthen our understanding of complex ideas.

The wharenui is built by people, for people. It is a place of meeting and learning, built to protect and serve people through time. Science too, is a knowledge base built by people, for people. It informs decisions we make about health and our environment, it leads to technological advancement, and wellbeing. It is important that people and their wellbeing are housed at the centre of scientific developments, so that the wharenui of ideas can protect and serve us well.

The whakataukī also refers to the maintenance of the wharenui through knowledge. To maintain the wharenui, scientists must think critically about new and old ideas, and constantly work to refine understanding. As new knowledge comes to light, scientists must adjust their thinking to carry the knowledge and ideas of the past into the future.

This wharenui of collected wisdom is a shared responsibility. Everyone who lives in this wharenui is responsible for its maintenance, and we, as kaitiaki, must learn the tools needed to maintain it well. Science learning from the past is a gift to us from our ancestors, and science literacy is how ākonga access this gift and contribute to it. Kaiako, ākonga, scientists, and society, build and maintain the wharenui of knowledge and ideas.

Subject-specific terms can be found in the glossary.

Science involves generating and testing ideas and gathering evidence to understand, explain, and develop knowledge about the natural world. Scientists do this by making observations, carrying out investigations and modelling, and by communicating and debating with others.

Scientific thinking does not belong to one culture. It is a global collection of understandings that have come from logical, systematic work, and from creative insight built on a foundation of respect for evidence.

Scientific progress comes from questioning that knowledge and how it is applied, so that new evidence and different perspectives can contribute to the global understanding of our natural world.

In Aotearoa New Zealand, Science uses the nature of science strand from the New Zealand Curriculum to teach ākonga what science is, and how scientists work. Ākonga will develop their scientific literacy, and their understanding of mātauranga Māori as a body of knowledge that both supports and challenges scientific thinking.

Science learning is theoretical and practical. It has diverse areas of specialization with internationally recognised symbols, languaging and conventions. Through developing science literacies and inquiry methods, and understanding different knowledge systems and perspectives, ākonga will be further empowered to make decisions, and take action in an ever-changing local and global landscape.

Whakataukī

Mā te whakaaro nui e hanga te whare; mā te mātauranga e whakaū.

Big Ideas create the house; knowledge maintains it.

The Science Learning Area whakataukī draws on the image of the wharenui to describe important ideas. This is significant in several ways.

Before the wharenui is built, the foundation must be firm and level. In science, respect for evidence is the foundation on which all ideas are built. The wharenui is constructed using various materials, and each serves a specific purpose with its own uniqueness. A poupou (wall post) is not the same as a heke (rafter), but they are joined and connected to make one wharenui. Science is also made of various disciplines, with their own properties, that focus on different areas of knowledge. The different areas of science connect and overlap to strengthen our understanding of complex ideas.

The wharenui is built by people, for people. It is a place of meeting and learning, built to protect and serve people through time. Science too, is a knowledge base built by people, for people. It informs decisions we make about health and our environment, it leads to technological advancement, and wellbeing. It is important that people and their wellbeing are housed at the centre of scientific developments, so that the wharenui of ideas can protect and serve us well.

The whakataukī also refers to the maintenance of the wharenui through knowledge. To maintain the wharenui, scientists must think critically about new and old ideas, and constantly work to refine understanding. As new knowledge comes to light, scientists must adjust their thinking to carry the knowledge and ideas of the past into the future.

This wharenui of collected wisdom is a shared responsibility. Everyone who lives in this wharenui is responsible for its maintenance, and we, as kaitiaki, must learn the tools needed to maintain it well. Science learning from the past is a gift to us from our ancestors, and science literacy is how ākonga access this gift and contribute to it. Kaiako, ākonga, scientists, and society, build and maintain the wharenui of knowledge and ideas.

Big Ideas and Significant Learning

This section outlines the meaning of, and the connection between the Big Ideas and Significant Learning, which together form the Learning Matrix. It then explains each Science Big Idea. 

The Science Learning Area, including its whakataukī, informs this subject's Significant Learning – learning that is critical for students to know, understand, and do in a subject by the end of each Curriculum Level. This covers knowledge, skills, competencies, and attitudes. It also includes level-appropriate contexts students should encounter in their education.

The subject's Big Ideas and Significant Learning are collated into a Learning Matrix for Curriculum Level 6. Teachers can use the Learning Matrix as a tool to construct learning programmes that cover all the not-to-be missed learning in a subject.

There is no prescribed order to the Learning Matrix within each Level. A programme of learning might begin with a context that is relevant to the local area of the school or an idea that students are particularly interested in. This context or topic must relate to at least one Big Idea and may also link to other Big Ideas.

There are four Big Ideas in Science. The nature of this subject as a discipline means aspects of Significant Learning often cross over multiple Big Ideas, and vice versa.

The Science Learning Area has four distinct subjects at NCEA Level 1. These are: Science; Chemistry and Biology; Physics, Earth and Space Science; and Agricultural and Horticultural Science.

These subjects are distinct but also interconnected. Ākonga who explore more than one of these subjects will find connecting themes in the Significant Learning and the Nature of Science, but the Achievement Standards for these subjects assess different competencies.

This section outlines the meaning of, and the connection between the Big Ideas and Significant Learning, which together form the Learning Matrix. It then explains each Science Big Idea. 

The Science Learning Area, including its whakataukī, informs this subject's Significant Learning – learning that is critical for students to know, understand, and do in a subject by the end of each Curriculum Level. This covers knowledge, skills, competencies, and attitudes. It also includes level-appropriate contexts students should encounter in their education.

The subject's Big Ideas and Significant Learning are collated into a Learning Matrix for Curriculum Level 6. Teachers can use the Learning Matrix as a tool to construct learning programmes that cover all the not-to-be missed learning in a subject.

There is no prescribed order to the Learning Matrix within each Level. A programme of learning might begin with a context that is relevant to the local area of the school or an idea that students are particularly interested in. This context or topic must relate to at least one Big Idea and may also link to other Big Ideas.

There are four Big Ideas in Science. The nature of this subject as a discipline means aspects of Significant Learning often cross over multiple Big Ideas, and vice versa.

The Science Learning Area has four distinct subjects at NCEA Level 1. These are: Science; Chemistry and Biology; Physics, Earth and Space Science; and Agricultural and Horticultural Science.

These subjects are distinct but also interconnected. Ākonga who explore more than one of these subjects will find connecting themes in the Significant Learning and the Nature of Science, but the Achievement Standards for these subjects assess different competencies.

Title: Science knowledge is contested and refined over time

Big Idea Body:

Science as a body of knowledge has rules and it is held accountable to them. Evidence must be collected in a manner that is repeatable, and established theories can be challenged by new evidence or new understanding. This means that scientists take part in peer review and discuss evidence, theories, and conclusions. Scientists work hard to identify bias in their work and in the work of others.

Scientists also draw on understandings from other bodies of knowledge to gain insights through different ways of looking at the world. People working in science in Aotearoa New Zealand learn from and build on knowledge that has been generated by those who came before them, especially from Māori and Pacific Peoples’ knowledge sources.

By understanding how science knowledge has developed, extended, and changed over time, ākonga can appreciate how science operates and can use appropriate tools in their own science practice.

Finally, ākonga will understand that wānanga and talanoa can be used to discuss existing knowledge and in so doing, allow new knowledge to emerge.

Big
Idea

Science knowledge is contested and refined over time

Science as a body of knowledge has rules and it is held accountable to them. Evidence must be collected in a manner that is repeatable, and established theories can be challenged by new evidence or new understanding. This means that scientists take part in peer review and discuss evidence, theories, and conclusions. Scientists work hard to identify bias in their work and in the work of others.

Scientists also draw on understandings from other bodies of knowledge to gain insights through different ways of looking at the world. People working in science in Aotearoa New Zealand learn from and build on knowledge that has been generated by those who came before them, especially from Māori and Pacific Peoples’ knowledge sources.

By understanding how science knowledge has developed, extended, and changed over time, ākonga can appreciate how science operates and can use appropriate tools in their own science practice.

Finally, ākonga will understand that wānanga and talanoa can be used to discuss existing knowledge and in so doing, allow new knowledge to emerge.

Title: Science uses different inquiry approaches to develop understanding

Big Idea Body:

Investigations are used to generate and evaluate knowledge to answer questions. A variety of investigation methods exist that involve making observations, gathering evidence, and collecting and interpreting data. Different investigation approaches are appropriate for answering different questions.

By engaging in investigations themselves, ākonga are more likely to think critically about information, data, and claims from the investigations of others. A lifelong learner is able to collect, investigate, and evaluate data to enhance their participation in society.

Big
Idea

Science uses different inquiry approaches to develop understanding

Investigations are used to generate and evaluate knowledge to answer questions. A variety of investigation methods exist that involve making observations, gathering evidence, and collecting and interpreting data. Different investigation approaches are appropriate for answering different questions.

By engaging in investigations themselves, ākonga are more likely to think critically about information, data, and claims from the investigations of others. A lifelong learner is able to collect, investigate, and evaluate data to enhance their participation in society.

Title: Science uses subject-specific literacy to communicate knowledge

Big Idea Body:

Young people have access to a huge volume of information from the internet and other sources. This information can be presented in many different modes including infographics, diagrams, tables, and anecdotes. The tools to discern valid evidence and to distinguish science from disinformation, are vital in this information-rich world. Ākonga need to understand how science is communicated and miscommunicated.

Science texts use subject specific vocabulary and science specific strategies to communicate information. Experimental reports, graphs, and data sets are also used to communicate in science. Different audiences will require ākonga to communicate their own findings and understandings in different styles. Clear, logical, well-reasoned arguments based on solid evidence are a cornerstone of science practice.

Big
Idea

Science uses subject-specific literacy to communicate knowledge

Young people have access to a huge volume of information from the internet and other sources. This information can be presented in many different modes including infographics, diagrams, tables, and anecdotes. The tools to discern valid evidence and to distinguish science from disinformation, are vital in this information-rich world. Ākonga need to understand how science is communicated and miscommunicated.

Science texts use subject specific vocabulary and science specific strategies to communicate information. Experimental reports, graphs, and data sets are also used to communicate in science. Different audiences will require ākonga to communicate their own findings and understandings in different styles. Clear, logical, well-reasoned arguments based on solid evidence are a cornerstone of science practice.

Title: Science based information can be used in decision making and action

Big Idea Body:

Ākonga are empowered when they learn to explore different perspectives, develop and express their own reasoned opinions, and make decisions to take action. Ākonga will use the practices and knowledge drawn from science to inform their perspectives, opinions, and actions.

Ākonga will engage with real world issues (including problems, needs, and opportunities) at a personal, community, or global level. They will bring their own worldview, experiences, and knowledge while building new capabilities such as critical inquiry, to develop evidence-based opinions.

By engaging with real world examples, ākonga will understand the complexity of decision making, and the importance of mātauranga Māori in conjunction with science knowledge for responsible decision making and action.

Big
Idea

Science based information can be used in decision making and action

Ākonga are empowered when they learn to explore different perspectives, develop and express their own reasoned opinions, and make decisions to take action. Ākonga will use the practices and knowledge drawn from science to inform their perspectives, opinions, and actions.

Ākonga will engage with real world issues (including problems, needs, and opportunities) at a personal, community, or global level. They will bring their own worldview, experiences, and knowledge while building new capabilities such as critical inquiry, to develop evidence-based opinions.

By engaging with real world examples, ākonga will understand the complexity of decision making, and the importance of mātauranga Māori in conjunction with science knowledge for responsible decision making and action.

Key Competencies in Science

Developing Key Competencies through Science

Learning in Science provides meaningful contexts for developing Key Competencies from the New Zealand Curriculum. These Key Competencies are woven through, and embedded in, the Big Ideas and Significant Learning. Students will engage with critical thinking and analysis, explore different perspectives on scientific issues, and develop their understanding of the role of science in society.

Thinking

Students of Science will:

  • understand that there is no one scientific method
  • develop a greater understanding of the nature of science
  • recognise how science and mātauranga Māori can help solve world problems
  • understand how models and theories have developed through time and are influenced by culture and politics
  • grasp increasingly complex science concepts and apply them to an ever-growing range of contexts 
  • understand that science knowledge is developed through investigation
  • select, plan, and carry out a range of appropriate investigations (including evaluating method and data) 
  • analyse information in its various forms and know how to check the sources of information
  • identify the assumptions that underlie claims made by journalists, scientists, and themselves, and to check these against the evidence
  • learn to distinguish science from disinformation.

Using language, symbols, and texts

Students of Science will:

  • develop knowledge of the vocabulary, numeric and symbol systems, and conventions of science such as graphs, significant figures, formulae, units, and diagrams
  • use appropriate ways to communicate their own science ideas and understanding of evidence.

Relating to others

Students of Science will:

  • learn to define the problem or issue to be investigated and establish what knowledge they already bring and what new knowledge they may need to gain
  • learn how to determine the different perspectives that people apply to their views of a science issue
  • use scientific understandings to make decisions and respond in social and cultural contexts.

Managing self

Students of Science will:

  • engage in scientific conversations about their science experiences, the quality of their evidence and the evidence of others
  • be open-minded and able to distinguish between their own and others' positions and findings.

Participating and contributing

Students of Science will:

  • use the science conclusions to generate and evaluate a range of possible responses (including consideration of cultural, social, environmental, ethical, economic, and political implications)
  • understand that science is a collaborative activity and practise talanoa or mahi tahi in their own science activities
  • engage in wānanga or talanoa to consult a body of knowledge and the work and ideas of others
  • where appropriate, debate evidence and justify points of view using a scientific perspective.

Key Competencies

This section of The New Zealand Curriculum Online offers specific guidance to school leaders and teachers on integrating the Key Competencies into the daily activities of the school and its Teaching and Learning Programmes.

Developing Key Competencies through Science

Learning in Science provides meaningful contexts for developing Key Competencies from the New Zealand Curriculum. These Key Competencies are woven through, and embedded in, the Big Ideas and Significant Learning. Students will engage with critical thinking and analysis, explore different perspectives on scientific issues, and develop their understanding of the role of science in society.

Thinking

Students of Science will:

  • understand that there is no one scientific method
  • develop a greater understanding of the nature of science
  • recognise how science and mātauranga Māori can help solve world problems
  • understand how models and theories have developed through time and are influenced by culture and politics
  • grasp increasingly complex science concepts and apply them to an ever-growing range of contexts 
  • understand that science knowledge is developed through investigation
  • select, plan, and carry out a range of appropriate investigations (including evaluating method and data) 
  • analyse information in its various forms and know how to check the sources of information
  • identify the assumptions that underlie claims made by journalists, scientists, and themselves, and to check these against the evidence
  • learn to distinguish science from disinformation.

Using language, symbols, and texts

Students of Science will:

  • develop knowledge of the vocabulary, numeric and symbol systems, and conventions of science such as graphs, significant figures, formulae, units, and diagrams
  • use appropriate ways to communicate their own science ideas and understanding of evidence.

Relating to others

Students of Science will:

  • learn to define the problem or issue to be investigated and establish what knowledge they already bring and what new knowledge they may need to gain
  • learn how to determine the different perspectives that people apply to their views of a science issue
  • use scientific understandings to make decisions and respond in social and cultural contexts.

Managing self

Students of Science will:

  • engage in scientific conversations about their science experiences, the quality of their evidence and the evidence of others
  • be open-minded and able to distinguish between their own and others' positions and findings.

Participating and contributing

Students of Science will:

  • use the science conclusions to generate and evaluate a range of possible responses (including consideration of cultural, social, environmental, ethical, economic, and political implications)
  • understand that science is a collaborative activity and practise talanoa or mahi tahi in their own science activities
  • engage in wānanga or talanoa to consult a body of knowledge and the work and ideas of others
  • where appropriate, debate evidence and justify points of view using a scientific perspective.

Key Competencies

This section of The New Zealand Curriculum Online offers specific guidance to school leaders and teachers on integrating the Key Competencies into the daily activities of the school and its Teaching and Learning Programmes.

Connections

Science uses transferrable, interdisciplinary skills that connect with other subjects, particularly those that use critical thinking, systems thinking, analysis, and research.

Some examples of links to other subjects are:

Mathematics and Statistics

  • All sciences use Statistics conventions for collecting and analysing data and Mathematics conventions for recognising and interpreting patterns.

Technology

  • Advances in science can lead to new materials and resources for technological applications. New technologies allow science advancements and novel applications in fields such as medical science, engineering, product development, and resource management.

Geography

  • Science includes geology and the study of natural forces that shape the land and bodies of water. Geography includes the way that land and water resources are used by people.

Music

  • Physics includes the study of soundwaves. Musical instruments create soundwaves and musical performance includes the use of acoustics, amplification, and resonance.

Health and Physical Education

  • Health and Physical Education shares understandings with Biology of how the human body works and behaves.

Science uses transferrable, interdisciplinary skills that connect with other subjects, particularly those that use critical thinking, systems thinking, analysis, and research.

Some examples of links to other subjects are:

Mathematics and Statistics

  • All sciences use Statistics conventions for collecting and analysing data and Mathematics conventions for recognising and interpreting patterns.

Technology

  • Advances in science can lead to new materials and resources for technological applications. New technologies allow science advancements and novel applications in fields such as medical science, engineering, product development, and resource management.

Geography

  • Science includes geology and the study of natural forces that shape the land and bodies of water. Geography includes the way that land and water resources are used by people.

Music

  • Physics includes the study of soundwaves. Musical instruments create soundwaves and musical performance includes the use of acoustics, amplification, and resonance.

Health and Physical Education

  • Health and Physical Education shares understandings with Biology of how the human body works and behaves.

Learning Pathway

Science offers ākonga a platform for gaining and applying skills across a wide range of potential pathways. Science thinking is logical and creative, subject specific and transferrable. Through Science, ākonga will learn skills in critical thinking, communication, collaboration, analysis, research, inquiry, peer review, and systems thinking.

Learning in Science may lead ākonga to a career in research and development, medicine, dentistry, food and nutrition, psychology, engineering, education, agriculture, viticulture, biosecurity, forestry, conservation, resource management, architecture, or politics.

There are many pathways for furthering science studies at tertiary level. Ākonga may wish to study a general science course, or specialise in areas such as neuroscience, zoology, medical laboratory science, forensic pathology, physiotherapy, veterinarian science, electrical engineering, psychology, or aeronautics.

More broadly, science skills are used in career pathways such as hairdressing, dairy farming, production management, health and safety advisor, pest control, or the armed forces.

Science fosters the ability to interpret and communicate information about complex issues which will help ākonga to make informed, responsible decisions related to themselves, their communities, and the world. Science encourages looking at the world from multiple perspectives and seeking out evidence to support conclusions. These skills are valuable in every career pathway.

Science offers ākonga a platform for gaining and applying skills across a wide range of potential pathways. Science thinking is logical and creative, subject specific and transferrable. Through Science, ākonga will learn skills in critical thinking, communication, collaboration, analysis, research, inquiry, peer review, and systems thinking.

Learning in Science may lead ākonga to a career in research and development, medicine, dentistry, food and nutrition, psychology, engineering, education, agriculture, viticulture, biosecurity, forestry, conservation, resource management, architecture, or politics.

There are many pathways for furthering science studies at tertiary level. Ākonga may wish to study a general science course, or specialise in areas such as neuroscience, zoology, medical laboratory science, forensic pathology, physiotherapy, veterinarian science, electrical engineering, psychology, or aeronautics.

More broadly, science skills are used in career pathways such as hairdressing, dairy farming, production management, health and safety advisor, pest control, or the armed forces.

Science fosters the ability to interpret and communicate information about complex issues which will help ākonga to make informed, responsible decisions related to themselves, their communities, and the world. Science encourages looking at the world from multiple perspectives and seeking out evidence to support conclusions. These skills are valuable in every career pathway.

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Introduction to Sample Course Outlines

Sample course outlines are being produced to help teachers and schools understand the new NCEA Learning and Assessment Matrices. We will have three examples of how a year-long Science course could be constructed using the new Learning and Assessment Matrices. They are indicative only and do not mandate any particular choice of text or approach.

Sample course outlines are being produced to help teachers and schools understand the new NCEA Learning and Assessment Matrices. We will have three examples of how a year-long Science course could be constructed using the new Learning and Assessment Matrices. They are indicative only and do not mandate any particular choice of text or approach.

Assessment Matrix

Conditions of Assessment for internally assessed standards

This section provides guidelines for assessment against internally assessed Standards. Guidance is provided on:

  • appropriate ways of, and conditions for, gathering evidence
  • ensuring that evidence is authentic
  • any other relevant advice specific to an Achievement Standard.

NB: Information on additional generic guidance on assessment practice in schools is published on the NZQA website. It would be useful to read in conjunction with these Conditions of Assessment.

The school's Assessment Policy and Conditions of Assessment must be consistent with the Assessment Rules for Schools With Consent to Assess. These rules will be updated during the NCEA review. This link includes guidance for managing internal moderation and the collection of evidence.

For all Achievement Standards

Internal assessment provides considerable flexibility in the collection of evidence. Evidence can be collected in different ways to suit a range of teaching and learning styles, and a range of contexts. Care needs to be taken to offer students opportunities to present their best evidence against the Standard(s) that are free from unnecessary constraints.

It is recommended that the design of assessment reflects and reinforces the ways students have been learning. Collection of evidence for the internally assessed Standards could include, but is not restricted to, an extended task, an investigation, digital evidence (such as recorded interviews, blogs, photographs or film), or a portfolio of evidence.

It is also recommended that the collection of evidence for internally assessed Standards should not use the same method that is used for any external Standards in a course, particularly if that method is using a time-bound written examination. This could unfairly disadvantage students who do not perform well under these conditions.

A separate assessment event is not needed for each Standard. Often assessment can be integrated into one activity that collects evidence towards two or three different Standards from a programme of learning. Evidence can also be collected over time from a range of linked activities (for example, in a portfolio). This approach can also ease the assessment workload for both students and teachers.

Effective assessment should suit the nature of the learning being assessed, provide opportunities to meet the diverse needs of all students, and be valid and fair.

Authenticity of student evidence needs to be assured regardless of the method of collecting evidence. This needs to be in line with school policy. For example: an investigation carried out over several sessions could include teacher observations or the use of milestones such as a meeting with the student, a journal, or photographic entries recording progress etc.

This section provides guidelines for assessment against internally assessed Standards. Guidance is provided on:

  • appropriate ways of, and conditions for, gathering evidence
  • ensuring that evidence is authentic
  • any other relevant advice specific to an Achievement Standard.

NB: Information on additional generic guidance on assessment practice in schools is published on the NZQA website. It would be useful to read in conjunction with these Conditions of Assessment.

The school's Assessment Policy and Conditions of Assessment must be consistent with the Assessment Rules for Schools With Consent to Assess. These rules will be updated during the NCEA review. This link includes guidance for managing internal moderation and the collection of evidence.

For all Achievement Standards

Internal assessment provides considerable flexibility in the collection of evidence. Evidence can be collected in different ways to suit a range of teaching and learning styles, and a range of contexts. Care needs to be taken to offer students opportunities to present their best evidence against the Standard(s) that are free from unnecessary constraints.

It is recommended that the design of assessment reflects and reinforces the ways students have been learning. Collection of evidence for the internally assessed Standards could include, but is not restricted to, an extended task, an investigation, digital evidence (such as recorded interviews, blogs, photographs or film), or a portfolio of evidence.

It is also recommended that the collection of evidence for internally assessed Standards should not use the same method that is used for any external Standards in a course, particularly if that method is using a time-bound written examination. This could unfairly disadvantage students who do not perform well under these conditions.

A separate assessment event is not needed for each Standard. Often assessment can be integrated into one activity that collects evidence towards two or three different Standards from a programme of learning. Evidence can also be collected over time from a range of linked activities (for example, in a portfolio). This approach can also ease the assessment workload for both students and teachers.

Effective assessment should suit the nature of the learning being assessed, provide opportunities to meet the diverse needs of all students, and be valid and fair.

Authenticity of student evidence needs to be assured regardless of the method of collecting evidence. This needs to be in line with school policy. For example: an investigation carried out over several sessions could include teacher observations or the use of milestones such as a meeting with the student, a journal, or photographic entries recording progress etc.

1.1
Develop a science-informed response to a local socio-scientific issue

Ākonga could either be given the socio-scientific issue they are required to address or they could select it for themselves. If the latter applies, the issue selected should be approved by the teacher.

This Standard assumes ākonga have engaged in a sequence of kaitiakitanga-based learning opportunities to develop their understanding of various socio-scientific issues. Ākonga should be exposed to multiple issues during the year.

With this type of assessment, checkpoints are recommended as ākonga explore the issue and develop their response. Checkpoints support ākonga to stay on track and get the feedback they need. Feedback is usually oral and checks for gaps and balance but does not involve detailed pre-marking. Checkpoints also provide a means of determining authenticity and collecting naturally occurring evidence.

1.2
Use a range of scientific investigative approaches in a taiao context

Assessment evidence will be collected from a minimum of three investigative approaches, then a summary will be completed to compare the different investigative approaches used.

Ākonga may be given an appropriate template, a suitable aim or question, and a skeletal method for the investigations.

It may be appropriate for ākonga to develop their methods and gather data in groups, but each learner should be actively involved and the teacher needs to collect evidence that each one has met all aspects of the Standard. Development and recognition of the value of wānanga and talanoa are important in this learning and assessment.

Range of investigative approaches for this Standard means at least three different approaches from:

  • pattern seeking
  • exploring and observing
  • modelling
  • classifying and identifying
  • fair testing.

The teacher can determine the time taken by the assessment as this is dependent on the investigations chosen.

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