Too Much Water on Earth?

Too Much Water on Earth?
“God goofed when He made so much water and so little land!” I recently heard a real estate salesman say that in a sales pitch to sell expensive lots. If you have taken a long intercontinental trip by plane or ship, you might tend to agree. Water covers roughly 75% of the surface of our planet. With our huge growth in human population, land suitable for human occupation is becoming scarce. Is there too much water on Earth? The answer to that question is a resounding “NO!!!” Every living cell depends on water, but the properties of water combined with its distribution and abundance cause its importance to go far beyond that fact.

Water is highly reflective. Ocean water reflects much of the light energy from the Sun back into space, so Earth’s surface does not become overheated. This is especially important because most of our surface water is in the Southern Hemisphere. When Earth’s orbit brings it closest to the Sun, the Southern Hemisphere faces the Sun. There is a massive potential for solar energy to overheat the land. Since most of Earth’s land area is in the Northern Hemisphere and most of the surface water is in the Southern Hemisphere, overheating doesn’t happen. This designed distribution of the land masses combined with the reflectivity of water protects us from overheating. We do not have too much water on Earth.

Water is a unique substance in terms of thermodynamic values. It is the standard frame of reference for specific heat and has a value of 1 calorie/gram. Water’s freezing and boiling points are zero and 100 degrees Celsius, which is a minimal difference in temperature compared to other substances. Water also has a high specific heat which means it can store the energy it absorbs better than other materials. Water’s heat of vaporization is 539.6 calories per gram, which is huge. The heat of vaporization is the amount of energy required to change water from the liquid state to the vapor state without changing its temperature. The capacity of water to store heat radically controls the climate. Water absorbs energy from the Sun and carries it in various ocean currents around the world. We don’t have too much water on Earth because it moderates the climates along all coasts of our planet. Planets and moons with no surface water experience violent storms and enormous variations in temperature.

Because water is a polar molecule, it can dissolve virtually all salts and many chemicals essential for life. The polar nature of the water molecule also allows it to be a condensation nucleus for the production of rain. As the oceans warm in tropical areas, the rate of water evaporation increases. As the water vapor cools, it needs something on which to condense. We all know that when the humidity is high, water condenses on our windows, our grass, and virtually any other exposed surface. To make rain, the water condenses on particles in the atmosphere. On land, the particles would be dust. Over the oceans, the particles are salt which is also a polar molecule and provides the ideal structure to make rain.

These simplified explanations should help us see that there is not too much water on Earth. We need all of that water to make life on Earth possible. Our climates, our movement of heat, the production of rain and snow, and the very formation of life itself all depend on water.

Genesis 1:2 tells us that God established water as one of the building blocks that allowed the Earth to support life. Verses 9-10 tell us that the “waters were gathered together into one place” and that those waters “were called seas, and God saw that it was good.” Proverbs 8:24 finds wisdom speaking of God’s creation. Wisdom tells us that water was created before there were mountains, hills, or dust. It has taken science thousands of years to understand why there is so much water. Today we now know that it is not only good, but it is vital to our existence.
–John N. Clayton © 2019

Moving Heat Energy

Moving Heat Energy
Winter always reminds us of how important it is to have ways of moving heat energy from one place to another. We are considering how the complex heat transfer system is another evidence for God’s creative wisdom. Yesterday we looked at heat transfer by radiation. There are two more methods.

A second way of moving heat energy is by conduction. When you put a spoon into a hot cup of water the molecules that make up the spoon begin to vibrate faster as they absorb heat energy from the water. As one molecule gets energy, it bumps into the next molecule, and it also starts to vibrate. This happens down the length of the spoon, and eventually, the heat is conducted to your skin.

How fast heat conduction happens depends upon the size, mass, and density of the material in the object conducting the heat. Gases have poor conductivity because their molecules are far apart. A winter coat has lots of spaces between the fabric molecules filled with air. Fur has air spaces between the hairs and inside the hair strands themselves. Those low-density spaces insulate against heat transfer. You have heard the old story about never putting your tongue on a very cold metal object. The reason is that the water in your tongue conducts heat away to the metal surface which is very dense. The heat transfer process happens so fast that the water in your tongue freezes.

A third method of moving heat energy is by convection. Heating air or water is difficult by radiation alone or by conduction alone. The materials are transparent, so they absorb radiation poorly. Conductivity is slow and limited as to how far the heat can travel. What happens is that molecules change their density as they are heated or cooled. When heated, the gas or liquid becomes less dense it rises taking heat energy with it. As it cools, it sinks because it becomes denser. The motion mixes the hot and cold in the process we call convection.

The amazing ability of water to change its density as it is heated and cooled allows lakes to form ice on the surface rather than on the bottom. Water was designed to have its lowest density at 32 degrees Fahrenheit. It has a higher density both above and below that temperature. A very complex chemical property of water is designed to handle the heat energy by becoming more dense down to 32 degrees and then less dense as it freezes into ice. You can read more about this essential characteristic of water in THIS PREVIOUS POST and in our book Dandy Designs Volume 3, available HERE.

We take for granted the various methods of moving heat energy in and around us, but the complexities of this design are amazing. My physics students love to see how this allows us to exist on this planet.
–John N. Clayton © 2019

Heat Transfer Design

Heat Transfer Design
During this time when record cold temperatures have covered much of the United States, we should consider the design of heat transfer. One of the evidences for the existence of God is the wisdom built into the physical creation that makes it possible to move energy. God created a system of heat transfer design that is far more complex than most of us realize or can imagine.

The primary source of heat for the surface of our planet is the Sun. The question is how heat from the Sun can travel 93 million miles to Earth through what is essentially a vacuum. Realize that there is no substance between the Sun and us, so the heat can’t travel by contact. Atoms are constructed in such a way that they release excess energy by generating small energy packets called photons. Photons from the Sun carry the energy to Earth.

Photon particles are very strange. They have an electric property and a magnetic property, so they are called electromagnetic radiation. Photons have no thickness. They are two dimensional, vibrate with a frequency, and can exist only if they are moving. If you stop a photon, it disappears, and its energy is absorbed by whatever it struck.

Because photons are particles, they can travel across the vacuum of space from the Sun to the Earth. Their vibration frequency determines how we perceive them. We have different names for the frequencies. Xrays, gamma rays, ultraviolet, infrared, radio waves, and visible light are different only in their frequencies. The higher the frequency, the more energy is involved. Gamma rays have a much higher frequency than visible light, so they pack more energy.

Everything radiates some energy, even our bodies, but this is just one way heat is transferred. Besides radiation, heat transfer design also involves conduction and convection. We take for granted the various ways in which heat is transmitted in and around us, but the complexity of heat transfer design is amazing. It is that design which allows us to exist on this planet. We will look at the other two heat transfer methods tomorrow.
–John N. Clayton © 2019