Biology HL
Biology HL
4
Chapters
553
Notes
Theme A - Unity & diversity
Theme A - Unity & diversity
Theme B - Form & Function
Theme B - Form & Function
Theme C - Interaction & Interdependence
Theme C - Interaction & Interdependence
Theme D - Continuity & Change
Theme D - Continuity & Change
IB Resources
Theme A - Unity & diversity
Biology HL
Biology HL

Theme A - Unity & diversity

Unlocking Water’s Secrets: Hydrogen Bonds Explained!

Word Count Emoji
485 words
Reading Time Emoji
3 mins read
Updated at Emoji
Last edited on 14th Jun 2024

Table of content

Water molecules & hydrogen bonds 🌊

Polar Covalent Bonds in Water

  • What's Happening? Within water molecules (H₂O), there are covalent bonds between oxygen and hydrogen atoms. But they're not just sharing like best friends; one friend (oxygen) is pulling more towards itself. It's called a polar covalent bond.
  • Why Unequal Sharing? Think of oxygen as the popular kid in school, always attracting attention. It attracts electrons more than hydrogen, so it has a small negative charge (δ–). On the other hand, hydrogen gets a partial positive charge.

Bent Shape of Water Molecules

  • Two Poles, One Molecule! Imagine water as a bent magnet with two hydrogen atoms on one side (positive pole) and the oxygen on the other (negative pole).
  • Fun Fact: Because of this bent shape, water has some awesome properties essential to life on Earth, such as being an excellent solvent.

Hydrogen Bonds: Tiny but Mighty!

  • What Are Hydrogen Bonds? It's the force when the positive hydrogen of one water molecule is attracted to the negative atom of another water molecule. Think of it like a mini-magnet between water molecules.
  • Weak but Many: Though a hydrogen bond is weaker than your Wi-Fi signal at times, there are so many in a unit of water that collectively they make water special!

Experiment - demonstrating hydrogen bond strength 🧪

This hands-on experiment helps you see hydrogen bonding in action.

Setup

  • 10cm³ syringe held upside down in a clamp.
  • Weights hanging from the syringe.
  • A tube connected to the syringe with a gate clip to close it.

Steps

  • Empty Syringe: Add weights until the plunger is down (100 g ≅ 1 N). This measures how much force overcomes friction.
  • Air-Filled Syringe: Repeat with syringe half-filled with air. Note the force needed to increase the air volume.
  • Water-Filled Syringe: Repeat with syringe half-filled with water, no air bubbles. Note the force to increase the water volume to 10cm³. Careful with those weights!

Real-world examples 🌍

  • Why Ice Floats: Hydrogen bonds cause water to expand as it freezes, making ice less dense. That's why ice cubes float in your soda!
  • Cohesion in Plants: Hydrogen bonds enable water to stick together and move up against gravity in plant stems. It's like a water escalator for plants!

Conclusion ✏️

Water isn't just for splashing in the pool. Its unique structure, with polar covalent bonds and hydrogen bonds, makes it essential for life as we know it. So, next time you take a sip of water, remember you're enjoying a molecular marvel!
Happy learning! 🎉

Nail IB's App Icon
IB Resources
Theme A - Unity & diversity
Biology HL
Biology HL

Theme A - Unity & diversity

Unlocking Water’s Secrets: Hydrogen Bonds Explained!

Word Count Emoji
485 words
Reading Time Emoji
3 mins read
Updated at Emoji
Last edited on 14th Jun 2024

Table of content

Water molecules & hydrogen bonds 🌊

Polar Covalent Bonds in Water

  • What's Happening? Within water molecules (H₂O), there are covalent bonds between oxygen and hydrogen atoms. But they're not just sharing like best friends; one friend (oxygen) is pulling more towards itself. It's called a polar covalent bond.
  • Why Unequal Sharing? Think of oxygen as the popular kid in school, always attracting attention. It attracts electrons more than hydrogen, so it has a small negative charge (δ–). On the other hand, hydrogen gets a partial positive charge.

Bent Shape of Water Molecules

  • Two Poles, One Molecule! Imagine water as a bent magnet with two hydrogen atoms on one side (positive pole) and the oxygen on the other (negative pole).
  • Fun Fact: Because of this bent shape, water has some awesome properties essential to life on Earth, such as being an excellent solvent.

Hydrogen Bonds: Tiny but Mighty!

  • What Are Hydrogen Bonds? It's the force when the positive hydrogen of one water molecule is attracted to the negative atom of another water molecule. Think of it like a mini-magnet between water molecules.
  • Weak but Many: Though a hydrogen bond is weaker than your Wi-Fi signal at times, there are so many in a unit of water that collectively they make water special!

Experiment - demonstrating hydrogen bond strength 🧪

This hands-on experiment helps you see hydrogen bonding in action.

Setup

  • 10cm³ syringe held upside down in a clamp.
  • Weights hanging from the syringe.
  • A tube connected to the syringe with a gate clip to close it.

Steps

  • Empty Syringe: Add weights until the plunger is down (100 g ≅ 1 N). This measures how much force overcomes friction.
  • Air-Filled Syringe: Repeat with syringe half-filled with air. Note the force needed to increase the air volume.
  • Water-Filled Syringe: Repeat with syringe half-filled with water, no air bubbles. Note the force to increase the water volume to 10cm³. Careful with those weights!

Real-world examples 🌍

  • Why Ice Floats: Hydrogen bonds cause water to expand as it freezes, making ice less dense. That's why ice cubes float in your soda!
  • Cohesion in Plants: Hydrogen bonds enable water to stick together and move up against gravity in plant stems. It's like a water escalator for plants!

Conclusion ✏️

Water isn't just for splashing in the pool. Its unique structure, with polar covalent bonds and hydrogen bonds, makes it essential for life as we know it. So, next time you take a sip of water, remember you're enjoying a molecular marvel!
Happy learning! 🎉