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What are the physical and chemical properties of water that make it so unique and necessary for living things? Water remains liquid at a much higher temperatures than expected. It also boils and freezes at much too high, or low, of a temperature for a molecule of its size. Many of these unexpected properties of water can be explained by the structure of the water molecule and the characteristics of the atoms it contains. Pure water is virtually colorless and has no taste or smell, but the hidden qualities of water make it an interesting subject.
In the activities that follow, students will discover cool ways that water interacts with various materials, all due to its special properties.
Water is very important to life on Earth. Water is a major component of cells, typically forming between 70% and 95% of the mass of the cell. This means that we are made from approximately 80% water by mass (weight) and some soft-bodied creatures, like jellyfish, are made of up to 96% water. Water also provides an environment for organisms to live in, as 75% of the earth is covered in water. Water circulates through the land just as it does through the human body, transporting, dissolving and replenishing nutrients and other organic matter while carrying away waste material.
Water is the only substance that is widely found in natural environments and exists in all three states of matter (solid (ice), liquid (water), and gas (steam)) within Earth's ordinary temperature conditions.
Each water molecule is made up of two hydrogen atoms and one oxygen atom (H20). Water is not a linear molecule with the atoms all in a row. The two hydrogen atoms form a bond with the oxygen at an angle of 104.5 degrees, making the molecule V-shaped.
The two hydrogen atoms are attached to the oxygen atom by covalent bonds. This means that the hydrogen atoms share their electrons with the oxygen atom.
Although each water molecule is neutral (with the same number of negative electrons and positive protons), the electrons stay closer to the oxygen atom. The result is that the tips of the V (the hydrogen atoms) are more positive, and the bottom of the V (the oxygen atom) is more negative. We thus describe a water molecule as polar, which means that it has a positively charged "end" and a negatively charged "end". This polarity helps make water both unusual, and useful!
When water molecules are close together, the positively-charged hydrogen atoms are attracted to the negatively-charged oxygen atoms of another water molecule. These attractions are called hydrogen bonds. They are weak individually but the sheer number of them can make the total force keeping all the molecules together quite considerable.
Hydrogen bonding between water molecules leads to many interesting consequences. For example, the boiling point of water, its cohesion and surface tension, and its ability to dissolve salts are all related to hydrogen bonding.
The boiling point of water, 100°C, is unusually high for a molecule with such a low molecular weight. The high boiling point is due to its hydrogen bonding. Boiling water means breaking up all of the hydrogen bonds in liquid water, so the molecules can move further apart and become steam. Breaking those bonds takes energy; thus the higher boiling point for water.
Hydrogen bonds also give liquid water molecular cohesion and a high surface tension.
Because of the extensive hydrogen bonding in water, the molecules tend to stick to each other in a regular pattern. This phenomenon, called cohesion, is easily observed when you carefully overfill a glass with water (by just a little bit!) and observe the water molecules holding together above the rim; this is called a meniscus (eventually, however, gravity overcomes the hydrogen bonds and the water molecules spill down the side of the glass). Likewise, the cohesive property of water allows tall trees to bring water to their highest leaves from underground sources.
A special type of cohesion is surface tension. The tension on the surface of water occurs when water molecules on the surface are held together by hydrogen bonding. The result is that water behaves like it has a thin skin on the surface. When a water droplet is formed, its spherical shape is the result of surface tension.
adhesion: The attraction of water molecules to other substances.
cohesion: The attraction of water molecules to each other.
covalent bond: A form of chemical bonding that involves the sharing of electron pairs between atoms.
electrons: A subatomic particle carrying a negative electric charge.
force: A push or a pull.
hydraulics: The use of fluid to do work.
hydrogen bond: The attraction between an electropositive hydrogen atom of one molecule with an electronegative atom, such as oxygen, from a neighbouring molecule.
hydrophilic: “Water loving”.
hydrophobic: “Water fearing”.
hydrostatic equilibrium: The pressure throughout a fluid at rest (“hydro” + “static”) is due to the weight of the fluid above it.
incompressible fluid: A fluid having a constant density or volume.
ions: Atoms or molecules in which the total number of electrons is not equal to the total number of protons, giving it a net positive or negative electrical charge.
non-polar: Describes a molecule with an even charge throughout it.
nucleus: The very dense region at the center of an atom.
piston: A disk or short cylinder fitting tightly within a tube in which it moves up and down against a liquid or gas.
polar (polarity): A polar molecule has both a positively and negatively charged “end”.
proton: A subatomic particle with a positive electrical charge. One or more protons are present in the nucleus of each atom, along with neutrons.
solvent: A liquid, solid or gas that can dissolve another solid, liquid, or gas.
substance: Any physical matter or material.
surface tension: The "skin" on the surface of water, due to cohesion between its molecules.
viscous: Thick or “syrupy”, describing a liquid.
InfoPlease | The Chemistry of Biology | Water
U.S. Geological Survey | The USGS Water Science School | Water Properties and Measurements
PBS LearningMedia | Water Phases
Science Buddies | Project Ideas | Measuring Surface Tension of Water with a Penny
PBS Kids | ZOOM | Science Rocks! | Pennies and Water
eNotes | Homework Help | Water and its Properties
Hunkin's Experiments | Hot Water Bottles | How to Lift a Person on Water
Wikipedia | Capillary action
Super Teacher Worksheets | Science Projects | Colorful Celery Stalk
Reeko's Mad Scientist Lab | Science Experiments | Pressure | How Capillary Action Makes Water Go Up
Science Kids | Experiments | Escaping Water
McGraw-Hill | Human Anatomy | The Cell: Basic Unit of Structure and Function | Chapter 2 | How Osmosis Works (animation)
BC Dairy Association | Kids Activity | Carton Crafts | Floating Boats (page 2)
The Youth Online Club | Kids Crafts | Soap Powered Boat
WonderHowTo | Model Cars, Rockets & Trains | How to Make a Soap-Powered Boat
Wikipedia | Paper cup - Manufacture - Waterproofing
Science World Resources | Full unit & activities | Wet and Dry
(a water unit with a kindergarten focus)
Science World Resources | Full unit & activities | Water Savers
(an intermediate-level unit on water conservation)
Metro Vancouver | K-12 Field Trips | Watershed Education
Science World at TELUS World of Science | Galleries | Our World: BMO Sustainability Gallery
HowEverythingWorks | Supplements | Section 15.1: Water, Steam, and Ice
YouTube | kentchemistry.com | Hydrogen Bonding - Water Drops on a Penny
San Diego State University | Department of Astronomy | Article | Hydrostatic Equilibrium
YouTube | Educational Innovations | Sodium Polyacrylate - The "Diaper Polymer"
University of Regina | Centre for Mathematics, Science and Technology Education | QuickStarts | Soap Powered Boat
To purchase sodium polyacrylate (the "diaper polymer"): Educational Innovations