Geography HL
Geography HL
13
Chapters
193
Notes
Option A - Freshwater – Drainage basins
Option A - Freshwater – Drainage basins
Option B - Oceans & Coastal Margins
Option B - Oceans & Coastal Margins
Option C - Extreme Environments
Option C - Extreme Environments
Option D - Geophysical Hazards
Option D - Geophysical Hazards
Option E - Leisure, Tourism & Sport
Option E - Leisure, Tourism & Sport
Option F - The Geography Of Food & Health
Option F - The Geography Of Food & Health
Option G - Urban Environments
Option G - Urban Environments
Unit 1 - Changing Population
Unit 1 - Changing Population
UNIT 2 - Global Climate - Vulnerability & Resilience
UNIT 2 - Global Climate - Vulnerability & Resilience
Unit 3 - Global Resource Consumption & Security
Unit 3 - Global Resource Consumption & Security
Unit 4 - Power, Places & Networks
Unit 4 - Power, Places & Networks
Unit 5 - Human Development & Diversity
Unit 5 - Human Development & Diversity
Unit 6 - Global Risks & Resilience
Unit 6 - Global Risks & Resilience
IB Resources
Option B - Oceans & Coastal Margins
Geography HL
Geography HL

Option B - Oceans & Coastal Margins

Unlock The Secrets How Oceans Regulate Earth's CO2 Levels And Climate

Word Count Emoji
678 words
Reading Time Emoji
4 mins read
Updated at Emoji
Last edited on 5th Nov 2024

Table of content

Oceans - the carbon keepers 🌊

Oceans act like a giant carbon vault. They absorb about 25% of the CO2 that we humans release into the air. In fact, they've swallowed over 90% of the world's carbon over a really, really long time (a.k.a. geological time). It's like the sea is playing a cosmic game of tag with carbon dioxide, saying, "Tag, you're it, and now you're mine!"

 

Photosynthesis, the plant's way of cooking up its food, converts CO2 into organic material. Picture this as the oceanic chefs turning raw ingredients (CO2) into a lip-smacking dish (organic carbon). 🍽️ These organics eventually sink deep into the ocean floor, making the upper ocean a low-carbon zone, while the deep ocean becomes carbon-rich.

 

Imagine if all this carbon stored deep down got a free lift to the surface because of processes like thermohaline circulation. Uh-oh! We might find the ocean becoming a source, not a sink, of CO2. This has happened in the past during glacial and interglacial periods, showing how oceans can affect atmospheric CO2 levels.

 

For instance, let's look at the numbers. CO2 levels during cold glacial phases may have dipped to around 180 ppmv (think of it as parts per million by volume, a way of measuring the concentration), and much of it was stored in the oceans. Contrastingly, during warm interglacials, CO2 was released from the oceans, pushing atmospheric CO2 levels to around 280 ppmv. Fast forward to now, and we're at around 400 ppmv. This indicates significant warming! 🌡️

 

Where's all this CO2 stored, you ask? Well, the major reservoirs are fossil fuels, the atmosphere, and (you guessed it) our oceans. The oceans' role in the carbon cycle is thanks to photosynthesis by tiny creatures called plankton, which transforms CO2 into organic compounds. Some of this carbon-rich material ends up on the ocean floor, where it decomposes into sediments. Over time, this material is destroyed at subduction zones - places where the ocean crust dives beneath continental plates. It's like a deep-sea wrestling match where the ocean crust loses and gets pushed beneath the heavier continental plate. 🤼‍♂️ This CO2 is later released during volcanic eruptions, connecting the ocean and atmospheric carbon cycles.

The acid test - ocean acidification 🧪

Fun fact: oceans have gulped down almost half of the CO2 released by burning fossil fuels since the 1880s. But when CO2 gets absorbed in seawater, it forms carbonic acid, which makes the water more acidic, triggering a phenomenon known as ocean acidification.

 

Freshwater has a pH of 7, which is considered neutral (like Switzerland in world wars). Ocean water was once at 8.2 (mildly alkaline), but it's dropped to 8.1 now due to CO2 absorption. You may think, "Oh, a 0.1 change? Big deal!" But here's the catch - the pH scale is logarithmic. So, a 0.1 shift translates to a 30% increase in acidity. Projections suggest that by 2100, the pH could drop to 7.8, an acidity spike of around 150%. It's like someone sneaked in and turned up the volume of acidity in the oceans. 📢

 

Our industrial age activities have added a lot of extra CO2 to the atmosphere, half of which has been absorbed by the oceans, lowering its pH. So, the cause of ocean acidification isn't a natural phenomenon; it's mostly human-made, like those pesky emissions from industrial plants, power stations, cars, and planes.

 

The effects are staggering. Many species are now threatened with extinction, fisheries face possible eradication, and coral reefs that protect coastal areas are eroding. It's like a domino effect, and the oceans are the first tile to fall.

 

One side effect of ocean acidification is that it hampers the formation of calcium carbonate, which forms the shells and skeletons of many sea creatures. Think of it as taking away the building blocks these creatures need to grow and survive. For example, the growth rate of some coral species has declined by 14% on the Great Barrier Reef since 1990. Oyster beds and other shellfish populations are struggling, and tiny shellfish known as pteropods, crucial in the food chain, are seeing a reduction in numbers.

 

By 2050, it's estimated that over 90% of coral will be affected by both local and global threats. It's like playing a game of Jenga where the tower is about to collapse, and each added piece is another stressor on the already fragile corals.

 

What's the take-home message? Well, while oceans have done a stellar job at storing carbon, our human activities are upsetting this natural balance. The evidence is in the more acidic waters and the declining health of marine ecosystems. Let's try to make more environmentally conscious decisions to help keep the ocean's balance intact! 🌏🤝

 

P.S. Don't forget to check your understanding of these concepts by going through the 'Check Your Understanding' section in the original text!

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IB Resources
Option B - Oceans & Coastal Margins
Geography HL
Geography HL

Option B - Oceans & Coastal Margins

Unlock The Secrets How Oceans Regulate Earth's CO2 Levels And Climate

Word Count Emoji
678 words
Reading Time Emoji
4 mins read
Updated at Emoji
Last edited on 5th Nov 2024

Table of content

Oceans - the carbon keepers 🌊

Oceans act like a giant carbon vault. They absorb about 25% of the CO2 that we humans release into the air. In fact, they've swallowed over 90% of the world's carbon over a really, really long time (a.k.a. geological time). It's like the sea is playing a cosmic game of tag with carbon dioxide, saying, "Tag, you're it, and now you're mine!"

 

Photosynthesis, the plant's way of cooking up its food, converts CO2 into organic material. Picture this as the oceanic chefs turning raw ingredients (CO2) into a lip-smacking dish (organic carbon). 🍽️ These organics eventually sink deep into the ocean floor, making the upper ocean a low-carbon zone, while the deep ocean becomes carbon-rich.

 

Imagine if all this carbon stored deep down got a free lift to the surface because of processes like thermohaline circulation. Uh-oh! We might find the ocean becoming a source, not a sink, of CO2. This has happened in the past during glacial and interglacial periods, showing how oceans can affect atmospheric CO2 levels.

 

For instance, let's look at the numbers. CO2 levels during cold glacial phases may have dipped to around 180 ppmv (think of it as parts per million by volume, a way of measuring the concentration), and much of it was stored in the oceans. Contrastingly, during warm interglacials, CO2 was released from the oceans, pushing atmospheric CO2 levels to around 280 ppmv. Fast forward to now, and we're at around 400 ppmv. This indicates significant warming! 🌡️

 

Where's all this CO2 stored, you ask? Well, the major reservoirs are fossil fuels, the atmosphere, and (you guessed it) our oceans. The oceans' role in the carbon cycle is thanks to photosynthesis by tiny creatures called plankton, which transforms CO2 into organic compounds. Some of this carbon-rich material ends up on the ocean floor, where it decomposes into sediments. Over time, this material is destroyed at subduction zones - places where the ocean crust dives beneath continental plates. It's like a deep-sea wrestling match where the ocean crust loses and gets pushed beneath the heavier continental plate. 🤼‍♂️ This CO2 is later released during volcanic eruptions, connecting the ocean and atmospheric carbon cycles.

The acid test - ocean acidification 🧪

Fun fact: oceans have gulped down almost half of the CO2 released by burning fossil fuels since the 1880s. But when CO2 gets absorbed in seawater, it forms carbonic acid, which makes the water more acidic, triggering a phenomenon known as ocean acidification.

 

Freshwater has a pH of 7, which is considered neutral (like Switzerland in world wars). Ocean water was once at 8.2 (mildly alkaline), but it's dropped to 8.1 now due to CO2 absorption. You may think, "Oh, a 0.1 change? Big deal!" But here's the catch - the pH scale is logarithmic. So, a 0.1 shift translates to a 30% increase in acidity. Projections suggest that by 2100, the pH could drop to 7.8, an acidity spike of around 150%. It's like someone sneaked in and turned up the volume of acidity in the oceans. 📢

 

Our industrial age activities have added a lot of extra CO2 to the atmosphere, half of which has been absorbed by the oceans, lowering its pH. So, the cause of ocean acidification isn't a natural phenomenon; it's mostly human-made, like those pesky emissions from industrial plants, power stations, cars, and planes.

 

The effects are staggering. Many species are now threatened with extinction, fisheries face possible eradication, and coral reefs that protect coastal areas are eroding. It's like a domino effect, and the oceans are the first tile to fall.

 

One side effect of ocean acidification is that it hampers the formation of calcium carbonate, which forms the shells and skeletons of many sea creatures. Think of it as taking away the building blocks these creatures need to grow and survive. For example, the growth rate of some coral species has declined by 14% on the Great Barrier Reef since 1990. Oyster beds and other shellfish populations are struggling, and tiny shellfish known as pteropods, crucial in the food chain, are seeing a reduction in numbers.

 

By 2050, it's estimated that over 90% of coral will be affected by both local and global threats. It's like playing a game of Jenga where the tower is about to collapse, and each added piece is another stressor on the already fragile corals.

 

What's the take-home message? Well, while oceans have done a stellar job at storing carbon, our human activities are upsetting this natural balance. The evidence is in the more acidic waters and the declining health of marine ecosystems. Let's try to make more environmentally conscious decisions to help keep the ocean's balance intact! 🌏🤝

 

P.S. Don't forget to check your understanding of these concepts by going through the 'Check Your Understanding' section in the original text!

Unlock the Full Content! File Is Locked Emoji

Dive deeper and gain exclusive access to premium files of Geography HL. Subscribe now and get closer to that 45 🌟