Why does electronegativity increase across a period? Show Consider sodium at the beginning of period 3 and chlorine at the end (ignoring the noble gas, argon). Think of sodium chloride as if it were covalently bonded.  Both sodium and chlorine have their bonding electrons in the 3-level. The electron pair is screened from both nuclei by the 1s, 2s and 2p electrons, but the chlorine nucleus has 6 more protons in it. It is no wonder the electron pair gets dragged so far towards the chlorine that ions are formed. Electronegativity increases across a period because the number of charges on the nucleus increases. That attracts the bonding pair of electrons more strongly. Why does electronegativity fall as you go down a group? Think of hydrogen fluoride and hydrogen chloride. The bonding pair is shielded from the fluorine's nucleus only by the 1s2 electrons. In the chlorine case it is shielded by all the 1s22s22p6 electrons. In each case there is a net pull from the centre of the fluorine or chlorine of +7. But fluorine has the bonding pair in the 2-level rather than the 3-level as it is in chlorine. If it is closer to the nucleus, the attraction is greater. As you go down a group, electronegativity decreases because the bonding pair of electrons is increasingly distant from the attraction of the nucleus. Diagonal relationships in the Periodic Table What is a diagonal relationship? At the beginning of periods 2 and 3 of the Periodic Table, there are several cases where an element at the top of one group has some similarities with an element in the next group. Three examples are shown in the diagram below. Notice that the similarities occur in elements which are diagonal to each other - not side-by-side. For example, boron is a non-metal with some properties rather like silicon. Unlike the rest of Group 2, beryllium has some properties resembling aluminium. And lithium has some properties which differ from the other elements in Group 1, and in some ways resembles magnesium. There is said to be a diagonal relationship between these elements. There are several reasons for this, but each depends on the way atomic properties like electronegativity vary around the Periodic Table. So we will have a quick look at this with regard to electronegativity - which is probably the simplest to explain. Explaining the diagonal relationship with regard to electronegativity Electronegativity increases across the Periodic Table. So, for example, the electronegativities of beryllium and boron are: Electronegativity falls as you go down the Periodic Table. So, for example, the electronegativities of boron and aluminium are: So, comparing Be and Al, you find the values are (by chance) exactly the same. The increase from Group 2 to Group 3 is offset by the fall as you go down Group 3 from boron to aluminium. Something similar happens from lithium (1.0) to magnesium (1.2), and from boron (2.0) to silicon (1.8). In these cases, the electronegativities aren't exactly the same, but are very close. Similar electronegativities between the members of these diagonal pairs means that they are likely to form similar types of bonds, and that will affect their chemistry. You may well come across examples of this later on in your course. Water is an amazing solvent, and has remarkable physical and chemical properties that make it the essential ingredient to life as we know it. The special properties of water come from the fact that the elements hydrogen and oxygen have differing electronegativities. In Chapter 3 we learned that covalent bonds formed between atoms of differing electronegativity are polarized. Because electronegativity is a measure of how strongly a given atom attracts electrons to itself, the atom in the covalent bond with the highest electronegativity will tend to draw the bonding electrons towards itself, resulting in a bond that is electron-rich on one end and electron-poor on the other. Covalent bonds that are polarized are said to have a dipole, where the term dipole moment refers to the direction and magnitude of the charge separation. Consider water. The electronegativities of hydrogen and oxygen are 2.20 and 3.44, respectively. That means that in each covalent bond, the electrons will be attracted towards the oxygen, leaving the hydrogen electron-poor. In Chapter 3, we used a calculated electrostatic potential map to visualize the electron density around molecules. The map for water is shown to the left and is colored using red to indicate a high electron density and blue to show electron-poor regions. Because electrons carry a negative charge, this also means that the red regions of the molecule are anionic (negative) and that the blue regions are cationic (positive). In this explainer, we will learn how to explain the properties of the polar molecule of water. Water is critical for the survival of all organisms on our planet. Without adequate and sustainable water supply, agriculture and industry would not function. As individuals, we use water every day for cooking, cleaning, and drinking. A single molecule of water has one atom of oxygen and two atoms of hydrogen. There is a covalent bond between each hydrogen atom and the central oxygen atom. So, the molecule has two chemical bonds, and the angle between these chemical bonds is 104.5∘. The molecular formula of water is HO2. Every element in the periodic table has a property known as electronegativity. Electronegativity measures how strongly an atom attracts an electron pair (or electron pairs) from a chemical bond. Let’s consider a molecule of water. Oxygen is more electronegative than hydrogen. So, the electrons of the covalent bonds are closer to the oxygen atom and further from the hydrogen atoms. We can see this effect illustrated in Figure 2. The orange arrows show how the electrons forming each covalent bond are pulled closer to the oxygen atom due to its higher electronegativity. The electronegativity of oxygen being greater than hydrogen causes the negatively charged electrons to be positioned closer to the oxygen atom. As the electrons are closer, a partial negative charge forms on the oxygen atom. Partial charges (𝛿+,𝛿−) in chemistry are like the full charges you might find on ions. However, a partial charge is much weaker than a full charge. Scientists call molecules polar when they have permanent partial charges. There are some exceptions to this, but we do not need to investigate this in this explainer; we can say that water is a polar molecule. A polar molecule is a covalent molecule where the difference in electronegativity between the elements in the molecule is relatively large. In a polar molecule, one end of the molecule is slightly positive, while the other end is slightly negative. A single water molecule consists of two hydrogen atoms and one oxygen atom. Which of the following statements explains why water is a polar molecule?
AnswerA polar molecule is a covalent molecule with a significant difference in electronegativity between its elements. This difference in electronegativity means the molecule has permanent partial charges. Oxygen has a much higher electronegativity than hydrogen. The pairs of bonding electrons from the two covalent bonds are attracted closer to the oxygen atom. If we look at the answers, we can see that B is the correct answer; there is a big difference in electronegativity between hydrogen atoms and oxygen atoms. Oxygen is more electronegative than hydrogen and attracts the bonding electrons in a molecule of water closer to itself. 𝛿+ and 𝛿− are used to show partial charges in chemistry. Which diagram correctly shows the partial charges on a molecule of water? AnswerThe strength by which an atom attracts the pair of electrons used to form a chemical bond is measured by electronegativity. Since oxygen has a higher electronegativity value than hydrogen, the electrons that form covalent bonds are drawn closer to the oxygen atom and away from the two hydrogen atoms. Consequently, the oxygen atom has a partial negative charge (𝛿−), and the two hydrogen atoms have a partial positive charge (𝛿+) as a result. We can use this information to determine that the correct answer is A. Another common polar molecule is ammonia (NH3). Ammonia is a simple molecule consisting of one nitrogen atom and three hydrogen atoms. Similar to the oxygen in a water molecule, nitrogen is much more electronegative than hydrogen, resulting in partial charges within the molecule. Returning to our focus on water, the permanent partial charges in each water molecule cause a weak electrostatic attraction to form between the partial charges of neighboring water molecules. These attractions can also be referred to as intermolecular forces. We call these weak electrostatic attractions between water molecules’ hydrogen bonds. Although we use the word bond, it is not a true chemical bond and is best thought of as an interaction between molecules. Hydrogen bonds are weaker than covalent bonds but are incredibly important when explaining and describing the physical properties of water. If you were to try to imagine the billions upon billions of water molecules that exist in a glass of water, you could begin to see how hydrogen bonds form and break continuously as the molecules rotate and move around, colliding with each other and the container. This idea is shown in Figure 5, where the hydrogen bonds are shown as dotted blue lines. The chemical bonding and intermolecular forces of attraction we have just discussed give water some very unique properties. For example, Figure 6 shows examples of water in all three states: as a liquid in the ocean, as solid ice in the iceberg, and, although we do not see it, as water vapor in the air and clouds. Water is a polar molecule; as such, other polar compounds can dissolve into water, forming solutions. For this reason, we can describe water as a polar solvent. Substances such as sugar are polar substances, and they dissolve in water. Also, ionic substances like salt, which have contained charged ions, dissolve in polar substances. We only need to think about salt in oceans or in a cup of tea to realize that we have had first-hand experience of these examples. A nonpolar substance is a substance that does not contain partial charges because the difference in electronegativity between the elements of the atoms in the molecules is very small. A nonpolar molecule is a covalent molecule where the difference in electronegativity between the elements in the molecule is very small. However, nonpolar solvents, such as cooking oil, do not dissolve in water, and when added to water, they separate into two layers. Water is an excellent polar solvent for most ionic substances, such as salt, and some covalent compounds, such as sugar, that form hydrogen bonds with water molecules. What is the name given to a solvent like water that is able to dissolve ionic substances such as salt?
AnswerIonic substances such as sodium chloride and other salts contain ions. Ions have positive and negative charges. When the charge is spread out in this way in chemistry, it is referred to as polarity. Some other substances without ionic charge still have partial charges and are also referred to as polar. For example, water is a polar molecule. We can use a beaker of water to dissolve a tablespoon of sodium chloride. A substance that can dissolve polar substances such as ionic salts is known as a polar solvent, so the correct answer is A, a polar solvent. The hydrogen bonds between water molecules also significantly affect the boiling and melting points of water. Let’s take a moment to compare water with another compound: hydrogen sulfide (HS2). Hydrogen sulfide is very similar to water; it has a sulfur atom instead of an oxygen atom. Sulfur is in group 16 of the periodic table like oxygen, so we might imagine that the melting and boiling points are very similar. However, as shown in Table 1, the melting and boiling points of water and hydrogen sulfide are very different! Table 1: The melting and boiling points of water and hydrogen sulfide.
We can see from the table above that more energy is required to separate water molecules during melting and boiling. This extra energy is necessary to overcome the hydrogen bonds that exist between the individual water molecules. Hydrogen sulfide molecules cannot form hydrogen bonds as the difference in electronegativity between sulfur and hydrogen is not large enough. Another remarkable characteristic of water is its density when in the solid form known as ice. Most substances are denser when they are in their solid state; however, water is less dense. As liquid water cools down to less than 4∘C, the water molecules form large hexagonal crystals due to longer hydrogen bonds between the individual molecules. When the liquid freezes at 0∘C, these large hexagonal crystals are fully formed, and the longer hydrogen bonds create a relatively large amount of space between molecules. We know that density is a way to express the amount of mass in a given volume, and when water takes the form of solid ice, the ice has less mass than the same volume of liquid water; therefore, water gets less dense as it freezes and turns into ice. We can see the longer hydrogen bonds and hexagonal arrangement of water molecules in ice in the figure below. The picture shows water molecules in a uniform fixed hexagonal arrangement created by hydrogen bonds. What state of matter would you expect to find water in when it is in this structural arrangement?
AnswerWater molecules form large hexagonal crystals when liquid water freezes at 0∘C. These hexagonal crystals form due to the existence of hydrogen bonds between the individual molecules. In their liquid state, individual water molecules are free to move and rotate with hydrogen bonds, continually forming and breaking between different molecules. In the gaseous state, steam water molecules can be thought of as independent units with little interaction. If we compare these three descriptions to the diagram above, we can see that the correct answer is A, ice (solid). This decrease in density as water freezes explains the expansion of ice as water freezes. As the water freezes, the mass of the water of course does not change, but the volume increases, and therefore, the density must decrease. The expansion of ice as water freezes is responsible for physical weathering phenomena such as freeze–thaw action, shown in Figure 9. It might also be witnessed at home when bottles of drinks explode in the freezer! Which of the following sequences of statements correctly describes why ice floats on water? AnswerSo, we can start answering this question by stating that when water freezes, it becomes ice, so we know that answer C is incorrect. Due to the hydrogen bonds that exist between molecules of water, water has some unique physical properties. When water freezes and turns to ice, longer hydrogen bonds form as the water molecules form hexagonal crystals. These hexagonal crystals have a relatively large amount of space between them due to the longer hydrogen bonds and cause water to expand. We can now see that answer E is also incorrect. When water freezes, the amount of water and consequently its mass do not change, but as the water expands when it freezes and becomes ice, it has a greater volume. With this information, we are now able to eliminate answer D. If any substance transforms to have a greater volume but the same mass, then the density will decrease. In the case of water, this makes ice less dense, and so, the correct answer is A. Seawater contains salt, and this salt affects its density. In areas of the ocean where the concentration of salt is lower, such as the North and South Poles, it is more difficult to swim as it is harder to generate force against the less dense liquid. In contrast, there are some places, such as the Dead Sea in western Asia, where salt concentrations are so high that people can float with virtually no effort at all! We will begin to conclude this explainer by looking at some of the chemical properties of water. Water is a neutral compound and does not display any acidic or basic properties. We can test this by using litmus paper. Red or blue litmus does not change color if it is in water. We can break water apart into hydrogen and oxygen using a process known as electrolysis. During electrolysis, we use electricity to break the bonds in chemical compounds. When we are explicitly performing the electrolysis of water, we use a unique piece of scientific equipment known as the Hofmann voltameter. The Hofmann voltameter is filled with water we have acidified by adding a small quantity of dilute sulfuric acid. The addition of the acid improves its conductivity. A power pack is attached to the voltameter, and a dc current is passed through the acidified water. The water then separates according to the following chemical equation: 2HO()2H()+O()222lggwaterhydrogenoxygenelectrolysis In Figure 14 below, we can see the Hofmann voltameter apparatus. Notice how twice as much hydrogen gas has been produced as oxygen gas. Let’s look closely at the atoms in this chemical reaction. It is easy for us to see why we get twice as much hydrogen gas as oxygen gas produced. Figure 15 shows how the atoms in two molecules of water rearrange to form two molecules of hydrogen gas and one molecule of oxygen gas during the electrolysis of water. Water is a fascinating molecule with many unusual characteristics. Many of its properties result from being a polar molecule and the existence of hydrogen bonds between the molecules. Let’s summarize what we have learned about the properties of water.
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Imagine if o and h+ has the same electronegativity what would that do to the properties of water
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