🧺 Te Kete Ako

Traditional Materials Science

Traditional Materials Science · Years 7–10

Year LevelYears 7–10
TypeStudent handout — classroom resource

Ngā Whāinga Akoranga · Learning Intentions

  • Investigate a significant question using evidence from multiple sources
  • Analyse and evaluate information to form and support a reasoned position
  • Connect learning to real-world contexts, including Aotearoa New Zealand settings
  • Communicate understanding clearly and accurately for a specific audience

Paearu Angitu · Success Criteria

  • I use at least two sources and can evaluate their credibility
  • My position is clearly stated and supported by specific evidence
  • I can connect my learning to at least one real-world Aotearoa context
  • My communication is clear, organised, and appropriate for the audience
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Engineering the Taiao

Traditional Materials Science & Technology

Focus: Physics + Engineering Context: Tools & Textiles

Advanced Lithic & Fibre Technology

Early Māori weren't just "gathering" materials; they were engineering them. Whether selecting stone that wouldn't shatter in battle or weaving fibers to hold tons of tension in a sailing waka, they applied deep understanding of material properties.

🧶

Harakeke: The Master Bio-Composite

Phormium tenax

Harakeke (Flax) is a natural composite material. It has strong cellulose fibers embedded in a softer lignin matrix—just like carbon fiber!

Mātauranga Engineering

  • Processing (Muka): Scraping the green "skin" off reveals the inner fibers (muka). This removes the weak material and leaves the high-tensile core.
  • Weaving Patterns (Raranga): Weaving at 45° angles (diagonal) distributes stress better than 90° grids. This creates baskets (Kete) that can expand without breaking.
  • Plaited Ropes: Braiding 4, 8, or 12 strands distributes the load so if one strand snaps, the rope holds.

The Material Physics

  • Tensile Strength: Muka fiber is incredibly strong under tension. Some tests show it rivals steel wire by weight!
  • Anisotropy: The leaf is strong length-wise (longitudinal) but weak width-wise (transverse). You can strip it easily by hand, but you can't snap it.
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Pounamu: The Unbreakable Stone

Nephrite Jade
Myth Buster: Diamond is the hardest stone (scratches anything), but Pounamu is the toughest (hardest to break). If you hit a diamond with a hammer, it shatters. If you hit Pounamu, the hammer bounces back!

Crystal Structure (Science)

Most stones (like Quartz or Obsidian) have crystalline structures that line up perfectly. When hit, a crack runs straight down the line (cleavage).

Pounamu / Nephrite is different. Its crystals are made of microscopic interlocking fibers (a felted structure). It's like a microscopic wool mat made of rock!

Tool Making (Technology)

Because it doesn't chip (flake) like obsidian, you can't knap it. You must preserve its toughness by grinding it with sandstone and water.

  • Toki (Adzes): Used for carving wood canoes. Pounamu holds a sharp edge even when hitting hard timber.
  • Mere (Clubs): A thin Pounamu club is stronger than a thick bone one.

Waka: Engineering Flexible Strength

Lashing vs. Nailing

Western boats used iron nails (rigid). Polynesian Waka used fiber lashing (flexible).

  • The Problem: In big ocean swells, a hull twists. A rigid structure (nails) concentrates stress at the join, causing wood to split or nails to pop.
  • The Solution: Lashing allows the waka components to move slightly ("give") with the waves, distributing the stress across the whole rope system. It's a kinetic structure.

⚗️ Lab Challenge: The Strength of Structure

Testing Weave Strength

Goal: Determine whether a woven structure is stronger than separate strands.

Materials

  • Paper strips or Flax strips
  • Weights (coins/washers)
  • Tape

Method

  1. Control: Tape 4 strips of paper side-by-side (parallel). Hang weights until they tear.
  2. Test: Weave 4 horizontal and 4 vertical strips into a square mat. Hang weights.
  3. Analyze: Why does the weave hold more? (Hint: Explain using "Force Distribution" and "Friction").

Hononga Marautanga · Curriculum Alignment

Social Sciences — Tikanga ā-Iwi

Level 3–4: Investigate social, cultural, environmental, and economic questions; gather and evaluate evidence from diverse sources; communicate findings and reasoning clearly for different audiences and purposes.

English — Communication

Level 3–4: Read, interpret, and evaluate information texts; write clearly and purposefully for specific audiences; apply critical thinking skills to evaluate sources and construct well-reasoned responses.

Tuhia ōu whakaaro · Write Your Thoughts

Reflect on your learning. What was the most important idea? What question do you still have?

Aronga Mātauranga Māori

This resource sits within a kaupapa that recognises mātauranga Māori as a living knowledge system with its own frameworks, values, and ways of understanding the world. The New Zealand Curriculum calls for learning that reflects the bicultural partnership of Te Tiriti o Waitangi, which means every subject area has an obligation to engage authentically with Māori perspectives — not as cultural decoration but as substantive contributions to how we understand our topics. The concepts of manaakitanga (care for others), kaitiakitanga (guardianship), whanaungatanga (relationship and belonging), and tino rangatiratanga (self-determination) provide a values framework applicable across all learning areas, and all are relevant to the work in this handout.

Ngā Rauemi Tautoko · Resources already provided

This handout is designed to be used alongside other resources in the same unit. Related materials are linked in the unit planner. All content is provided — no additional preparation is required to use this handout in your classroom.

📋 Teacher Planning Snapshot

Ngā Whāinga Ako — Learning Intentions

Students will engage with this resource to explore the intersection of STEM disciplines and mātauranga Māori — understanding how Indigenous knowledge systems and Western science share complementary ways of knowing the world.

Ngā Paearu Angitū — Success Criteria

  • ✅ Students can identify connections between mātauranga Māori and STEM concepts in this resource.
  • ✅ Students can explain how dual knowledge systems strengthen understanding of natural phenomena.

Differentiation & Inclusion

Scaffold support: Provide concept maps or sentence frames to scaffold access for students at the entry level. Offer extension tasks exploring specific mātauranga Māori knowledge domains (e.g., tohu āhua rangi, rongoā, whakapapa o te taiao) in greater depth.

ELL / ESOL: Pre-teach key vocabulary in both te reo Māori and English — including domain-specific STEM terms. Bilingual glossaries and visual anchors support comprehension. Allow students to demonstrate understanding in their preferred language.

Inclusion: Tasks are designed for a range of readiness levels. Neurodiverse learners benefit from structured, chunked activities with clear success criteria. Use hands-on, inquiry-based formats where possible. Affirm the value of different ways of knowing.

Mātauranga Māori lens: Mātauranga Māori encompasses astronomy, ecology, navigation, agriculture, and medicine — systems of knowledge developed over centuries. This unit treats mātauranga Māori as epistemically equal to Western science, not supplementary. Bring kaitiakitanga as a guiding ethic: knowledge is held in relationship, not extracted.

Prior knowledge: Students benefit from baseline understanding of the relevant STEM domain. No specialist te reo Māori knowledge required — glossaries provided. Best used after introductory lessons or as a standalone exploration.

Curriculum alignment