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Water is a chemical substance with the chemical formula H2O. Its molecule contains one oxygen and two hydrogen atoms connected by covalent bonds. Water is a liquid at ambient conditions, but it often co-exists on Earth with its solid state, ice, and gaseous state, water vapor or steam.
Water covers 70.9% of the Earth's surface,[1] and is vital for all known forms of life.[2] On Earth, it is found mostly in oceans and other large water bodies, with 1.6% of water below ground in aquifers and 0.001% in the air as vapor, clouds (formed of solid and liquid water particles suspended in air), and precipitation.[3]Oceans hold 97% of surface water, glaciers and polar ice caps 2.4%, and other land surface water such as rivers, lakes and ponds 0.6%. A very small amount of the Earth's water is contained within biological bodies and manufactured products.
Water on Earth moves continually through a cycle of evaporation or transpiration (evapotranspiration),precipitation, and runoff, usually reaching the sea. Over land, evaporation and transpiration contribute to the precipitation over land.
Clean drinking water is essential to human and other lifeforms. Access to safe drinking water has improved steadily and substantially over the last decades in almost every part of the world.[4][5] There is a clear correlation between access to safe water and GDPper capita.[6] However, some observers have estimated that by 2025 more than half of the world population will be facing water-based vulnerability.[7] A recent report (November 2009) suggests that by 2030, in some developing regions of the world, water demand will exceed supply by 50%.[8] Water plays an important role in theworld economy, as it functions as a solvent for a wide variety of chemical substances and facilitates industrial cooling and transportation. Approximately 70% offreshwater is consumed by agriculture.[9]
Water is a polar molecule (this means that the distribution of charges through the molecule isn't even). The hydrogen atoms have partially positive charges (δ +) and the oxygen atoms have partially negative charges (δ -). These charges form very strong bonds between molecules of water (Hydrogen - oxygen) called hydrogen bonds. A covalent bond is formed between the oxygen (group 6) and two hydrogen atoms (group 1).
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High specific heat capacity
Specific heat capacity is the amount of energy that it takes to raise the temperature of 1kg of a substance by 1 degree. Temperature relates to the amount of kinetic energy that the molecules within a substance have. As there are very strong hydrogen bonds between the water molecules, it takes a lot of energy to break them. As a result of these strong hydrogen bonds, more of the energy goes into breaking them rather than raising the temperature of the water. Therefore the amount of energy needed to raise the temperature of 1kg of water by 1 degree is relatively high so it has a high specific heat capacity.
The high specific heat capacity is why water has a high boiling point and is a water at room temperature.
Water in our bodies works as a temperature buffer. This means that it keeps our bodies as close to 37 degrees most of the time. This is because if, for example the temperature of the surrounding environment increases or the rate of respiration rises à exercise, then the temperature of our bodies does not increase. (There is a high percentage of water in our bodies). A constant body temperature is important for homeostasis to stop our enzymes from denaturing.
Latent heat of evaporation
In a body of water, some molecules are moving faster than others because they have more kinetic energy. Some of these molecules have enough kinetic energy to leave the body of water. As this water leaves the body of water it takes a lot of the energy from the total body of water with it (as they are taking kinetic energy with them and therefore the temperature of the body of water falls).
This is why water evaporates in the sun after it has rained even though the water isn't boiling.
This process is important in bodies of animals because the evaporation of sweat helps to cool down the body.
It is also has effect on the leaves in plants as it removes water from leaves.
Strong Cohesion
Cohesion Is when molecules attract to each other (because of the partial charges of the hydrogen and oxygen atoms). In a body of water, all of the molecules are attracted to each other, however, the uppermost molecules only have forces from beneath. Therefore, the uppermost molecules are pulled further down and closer together (laterally).
This creates surface tension on a large body of water.
These strong attractions are important in the xylem as it allows water to flow in a continuous stream so the water can be taken up from root to leaf.
Important solvent.
As water is a polar molecule, it is therefore an important solvent. This is because the partially positive and negative charges attract atoms in other molecules causing them to separate and therefore dissolve. à When substances are dissolved in water they are free to move around and react with other molecules.
Metabolic processes (i.e. respiration or photosynthesis) which are essential for any life can only happen when reactants are dissolved in water. For example the movement of Oxygen into our blood.
Density
When water freezes it turns to ice, which is less dense than when it is a liquid. This is because the hydrogen bonds formed are slightly further apart (due to the polarity) than that distance in water. This produces a giant, rigid open structure where every oxygen atom is at the centre of a tetrahedral arrangement (surrounded by hydrogen atoms).
The lower density as a solid is why ice floats on water and doesn't sink.
Adhesion
The cohesive forces of water are related to the property of strong adhesion. Adhesion is the attraction between water molecules and other molecules - these forces can sometimes be stronger than cohesion.
When water is within charged surfaces, for example the type that are found on the inside of a capillary tube, the water 'climbs' up the tube. This is because the water molecules are attracted to the charges on the insides of the capillary walls more than they are to each other.
What else can I help you with?
How does hydrogen affect the properties of water?
Hydrogen in water molecules forms hydrogen bonds, which give water its unique properties such as high surface tension, cohesion, and adhesion. These properties are important for various biological and chemical processes.
What are the properties and functions of polar uncharged amino acids in biological systems?
Polar uncharged amino acids have properties that make them water-loving and able to form hydrogen bonds. In biological systems, they play roles in protein structure, enzyme function, and cell signaling.
Is it true that covalent bonding explains water's unique properties?
Yes, covalent bonding between oxygen and hydrogen atoms allows water to have unique properties such as high surface tension, high specific heat capacity, and the ability to form hydrogen bonds. These properties are essential for the biological functions and the overall existence of living organisms.
The polar nature of water allows it to dissolve?
a wide variety of substances, making it a versatile solvent in biological systems. The hydrogen bonding between water molecules contributes to its strong cohesive properties.
What is water concentration?
Water concentration refers to the amount of water present in a solution or system, usually expressed as a percentage or molarity. It is an important factor in many chemical and biological processes, influencing properties such as solubility, reactivity, and mobility of substances. Monitoring and regulating water concentration is crucial in various industries, environmental studies, and biological research.
How does hydrogen affect the properties of water?
Hydrogen in water molecules forms hydrogen bonds, which give water its unique properties such as high surface tension, cohesion, and adhesion. These properties are important for various biological and chemical processes.
What biological functions are made more effective by the hydrogen bonding properties in water?
Water is a very good solvent.
What 3 types of properties does water have?
Water has chemical properties, such as being a polar molecule; physical properties, such as high surface tension and specific heat capacity; and biological properties, such as being a universal solvent and essential for life.
What is determined by the dissolved salts in water?
Dissolved salts have an influence on the physical, chemical and biological properties of the solution.
How waste water is removed from properties?
The wastewater is first treated using secondary treatment which includes biological treatment, filtering.
A type of bond that is very important in determining the properties of water and of important biological molecules such as proteins and DNA?
Coordinate covalent
What are the properties and functions of polar uncharged amino acids in biological systems?
Polar uncharged amino acids have properties that make them water-loving and able to form hydrogen bonds. In biological systems, they play roles in protein structure, enzyme function, and cell signaling.
What are the properties and significance of small polar molecules in biological systems?
Small polar molecules play a crucial role in biological systems due to their ability to dissolve in water and interact with other molecules. They are important for processes such as cell signaling, enzyme activity, and maintaining the structure of biological molecules. Their properties allow them to participate in various chemical reactions and help regulate the functions of cells and tissues.
How hydrogen bonds affect the physical properties of water?
Hydrogen bonds between water molecules give water its high surface tension, cohesion, and thermal properties (high specific heat capacity and heat of vaporization). These properties allow water to play a crucial role in biological systems and the Earth's climate regulation.
What are four properties needed in water for living organisms?
Water must be liquid at a wide range of temperatures to support biological processes. Water must have a high surface tension for capillary action, allowing transport of nutrients in organisms. Water must be a good solvent to dissolve and transport vital molecules in biological systems. Water must be cohesive and adhesive for proper hydration and cell-to-cell communication in organisms.
Why is polarity of water important to life?
The polarity of water allows it to form hydrogen bonds, giving water unique properties such as high surface tension, cohesion, and adhesion. These properties are essential for various biological processes, such as transportation of nutrients within organisms, temperature regulation, and solubilizing biological molecules. Furthermore, water's ability to dissolve polar and charged molecules makes it an excellent medium for biochemical reactions in living organisms.
Is it true that covalent bonding explains water's unique properties?
Yes, covalent bonding between oxygen and hydrogen atoms allows water to have unique properties such as high surface tension, high specific heat capacity, and the ability to form hydrogen bonds. These properties are essential for the biological functions and the overall existence of living organisms.
