Climate Change, Biotechnology and Modern Physics

MYP Unit Framework

Key Concept: SYSTEMS Related Concepts: Consequences. Evidence. Sustainability. Global Context: Globalisation and Sustainability (How can science help us address the most URGENT challenges facing humanity?) Statement of Inquiry: Scientific understanding of COMPLEX SYSTEMS — from Earth's climate to the human genome to the atomic nucleus — empowers us to address global challenges, but the APPLICATION of that knowledge raises PROFOUND ETHICAL QUESTIONS that science alone cannot answer.


Inquiry Questions

TypeQuestion
FactualWhat is the greenhouse effect? How does CRISPR work? What is nuclear fission?
ConceptualWhy is there a CONSENSUS among scientists about climate change — and yet PUBLIC DEBATE continues? How do we balance the BENEFITS of biotechnology against the RISKS?
DebatableShould we pursue NUCLEAR ENERGY as a solution to climate change — despite the risks? Is it ETHICAL to genetically modify human embryos? Who DECIDES which technologies are 'safe enough' — and who bears the CONSEQUENCES if they're WRONG?

1. Climate Change — The Defining Challenge

The Greenhouse Effect — The Science

  1. SOLAR RADIATION (shortwave) passes through the atmosphere and warms the Earth.
  2. The Earth radiates heat back as INFRARED (longwave) radiation.
  3. GREENHOUSE GASES (CO₂, CH₄, H₂O, N₂O) in the atmosphere ABSORB some of this outgoing infrared — trapping heat.
  4. 'WITHOUT the natural greenhouse effect, Earth's average temperature would be −18°C — FROZEN. The greenhouse effect makes Earth HABITABLE. The PROBLEM is the ENHANCED greenhouse effect — humans adding EXTRA greenhouse gases, trapping TOO MUCH heat.'

The Evidence

EvidenceWhat It Shows
Temperature recordsGlobal average temperature has risen ~1.2°C since pre-industrial times. The rate of warming is UNPRECEDENTED.
Ice core dataCO₂ levels today (~420 ppm) are HIGHER than at any point in at least 800,000 years.
Glacier retreatGlaciers worldwide are SHRINKING. The Arctic is warming ~4× faster than the global average.
Sea level rise~20 cm since 1900. ACCELERATING. Caused by: thermal expansion (warmer water occupies more volume) + melting ice sheets.
Extreme weatherHeatwaves, floods, droughts, and intense storms are becoming more FREQUENT and more INTENSE.

The Human Causes

  • Burning FOSSIL FUELS (coal, oil, gas) for energy — the LARGEST source. Deforestation (trees absorb CO₂ — cutting them RELEASES it). Agriculture (livestock — methane. Fertilisers — nitrous oxide). Industrial processes (cement production releases CO₂).

What Can Be Done?

  • MITIGATION (reduce emissions): Shift to RENEWABLE ENERGY (solar, wind). Energy efficiency. Electrify transport. Reforestation. Carbon capture.
  • ADAPTATION (cope with the changes already coming): Sea walls. Drought-resistant crops. Early warning systems for extreme weather.
  • GEOENGINEERING (radical — controversial): Deliberately modifying Earth's climate system — e.g., injecting aerosols into the stratosphere to reflect sunlight. 'Risky. Unknown side effects. Who gets to decide for the ENTIRE PLANET?'

The Political Dimension

'The Paris Agreement (2015): 196 countries agreed to limit warming to WELL BELOW 2°C and pursue efforts to limit it to 1.5°C. But the commitments made so far (Nationally Determined Contributions) are INSUFFICIENT to meet these targets. There is a GAP between what science says is NECESSARY and what politics is willing to DELIVER.' The principle of 'Common But Differentiated Responsibilities' (CBDR) — rich countries who EMITTED MOST historically should bear GREATER responsibility.


2. Biotechnology — Rewriting the Code of Life

CRISPR-Cas9 — The Genetic Scissors

Discovered 2012 (Jennifer Doudna & Emmanuelle Charpentier — Nobel Prize 2020). 'CRISPR allows scientists to EDIT DNA — to CUT a specific gene and REPLACE it with a different sequence. It is CHEAP. It is PRECISE. It is REVOLUTIONARY.'

Applications

  • Medicine: Correcting genetic diseases (sickle cell, cystic fibrosis). Engineering immune cells to ATTACK cancer. 'The first CRISPR-based therapies have been APPROVED.'
  • Agriculture: Drought-resistant crops. Pest-resistant crops (reducing pesticide use).
  • Conservation: Engineering corals to survive warmer oceans. 'De-extinction' — bringing back extinct species (e.g., the woolly mammoth).

The Ethical Questions

  • SOMATIC editing (changes die with the individual — affects only that patient). Generally accepted.
  • GERMLINE editing (changes passed to FUTURE GENERATIONS — affects the human gene pool). EXTREMELY CONTROVERSIAL. 'In 2018, a Chinese scientist announced he had created the world's first CRISPR-edited BABIES — twin girls, edited to be RESISTANT TO HIV. The scientific community CONDEMNED the action. He was sent to PRISON. The question remains: Should we edit the human germline — and if so, under WHAT CIRCUMSTANCES?'

The 'Designer Baby' Debate

'If we edit genes to eliminate DISEASE — most people agree that is good. But what about editing for ENHANCEMENT? Taller? Smarter? Stronger? A specific eye colour? Where does "therapy" END and "enhancement" BEGIN? And who gets ACCESS — only the wealthy? Biotechnology could REDUCE suffering — or it could ENTRENCH inequality.'


3. Modern Physics — The Atom and the Universe

Radioactivity

Discovered by Henri Becquerel (1896). Named by Marie Curie. Three types: Alpha (α) — helium nucleus. Least penetrating. Beta (β) — electron/positron. Moderate. Gamma (γ) — electromagnetic wave. MOST penetrating.

Half-Life: T₁/₂ = ln 2 / λ. Exponential decay.

'Radioactive isotopes are used in: MEDICINE (cancer radiotherapy, PET scans). ARCHAEOLOGY (carbon-14 dating). INDUSTRY (smoke detectors).'

Nuclear Energy — Fission

Heavy nucleus (Uranium-235) splits → HUGE energy release. Chain reaction. '1 kg of uranium-235 releases ~3 MILLION times more energy than 1 kg of coal.' Nuclear power: ZERO carbon emissions during operation. BUT: Radioactive WASTE (dangerous for thousands of years). Accidents (Chernobyl 1986, Fukushima 2011). Nuclear weapons proliferation.

Nuclear Fusion — The Holy Grail

Light nuclei (hydrogen) COMBINE → heavier nucleus + ENORMOUS energy. This is what powers the SUN. Advantages over fission: FUEL ABUNDANT (hydrogen from water). NO long-lived radioactive waste. NO risk of meltdown. 'The challenge: fusion requires temperatures of ~150 MILLION °C — hotter than the Sun's core. No material can contain it. Scientists use MAGNETIC CONFINEMENT. After decades of research, we are CLOSER than ever — but not yet there. Fusion is the "energy of the future — and always will be."'


Your Summative Assessment — The Interdisciplinary Investigation

Task: 'Science, Ethics and Action' Choose ONE of the following:

  • Climate: Propose a CLIMATE ACTION PLAN for your school or community. Base it on SCIENTIFIC EVIDENCE. Address ECONOMIC and SOCIAL dimensions.
  • Biotechnology: Write a POSITION PAPER on a specific application of genetic engineering. Argue for or against. Address ETHICAL concerns.
  • Energy: Evaluate the role of NUCLEAR ENERGY in the transition to a carbon-neutral future. Weigh benefits against risks.

Your response must: Use SCIENTIFIC EVIDENCE. Acknowledge UNCERTAINTIES. Address ETHICAL DIMENSIONS. 'This is preparation for the MYP Sciences eAssessment — and for the interdisciplinary thinking the IB Diploma Programme demands.'


ATL Skills

SkillFocus
Critical ThinkingEvaluating evidence on contested issues. Weighing risks and benefits.
Ethical ReasoningEngaging with the moral dimensions of scientific applications.
CommunicationConstructing evidence-based arguments.
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