So with covalent bonding, we say that a key feature of covalent compounds is where molecular bonds involve sharing valence electrons between nonmetals. Remember, covalent compounds only involve nonmetals. Recall they do this in order to achieve 8 valence electrons or a filled outer shell like the noble gases. Now we're going to say with this idea we have what's called the octet rule and the duet rule. With the octet rule, that's when an element reacts in order to achieve 8 valence electrons. And with the duet rule, this is specifically for the element of hydrogen. Here, it reacts in order to achieve 2 valence electrons. Doing this helps it to establish a filled outer shell like the noble gas of helium. Remember, from hydrogen to helium, hydrogen only needs to gain one more electron to be just like the noble gas of helium. So just remember, nonmetals are forming bonds in order to obtain electron arrangements like the noble gases. They do this to fulfill either the octet rule or the duet rule in terms of hydrogen.
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Covalent Bonds - Online Tutor, Practice Problems & Exam Prep
Covalent bonding involves the sharing of valence electrons between nonmetals, allowing them to achieve stable electron configurations, following the octet rule or the duet rule for hydrogen. Covalent compounds can exist as solids, liquids, or gases at room temperature, are poor electrical conductors, and typically have lower melting and boiling points. This sharing of electrons enables nonmetals like fluorine to mimic the electron configuration of noble gases, enhancing their stability.
A covalent bond is the connection of different elements through the sharing of electrons.
Covalent Bonding
Covalent Bonds Concept 1
Video transcript
Covalent Bonds Concept 2
Video transcript
So with the duet rule and the octet rule, remember, hydrogen follows the duet rule. Here we have 2 hydrogens. Both of their electron configurations are 1s1. If they can gain 1 electron, they can become 1s2 and become just like the normal gas of helium. When it comes to covalent bonds though, there is no transferring of electrons. It's the sharing of valence electrons. So what they do here is that they each share their one valence electron. So basically, they don't have sole possession of both electrons, they're sharing amongst each other. That gives each of them an electron configuration of 1s2, just like the noble gases in terms of helium.
Other non-metals, they have more shells and therefore they want to follow the octet rule. If we take a look here at fluorine, fluorine is 1s2, 2s2, 2p5. If it can get to 2p6, it can become just like the noble gas of neon. What each fluorine decides to do is they decide to share their one electron. So here, neither one has sole possession of both electrons within this bond. They're sharing them with each other. And in that way, they each can have the 2p6 electron configuration that they desire. Doing this allows them to have or mimic the electron configuration of neon. So in both instances, the duet rule and the octet rule allow for a noble gas to mimic the electron configuration or electron arrangement of the nearest noble gases to them.
In order to obtain the electron configuration of noble gases, Hydrogen follows the duet rule while other non-metals follow the octet rule.
Covalent Bonds Example 1
Video transcript
Which of these elements is unlikely to form covalent bonds? So we have here sulfur, we have hydrogen, we have potassium, we have argon, and we have silicon. Remember, covalent bonds are the sharing of electrons between elements with nonmetallic characteristics. So, if we take a look here, sulfur is a nonmetal so sulfur could form covalent bonds. Hydrogen is a nonmetal. Potassium is a metal. We said that it's between nonmetals. So, this can't ever form covalent bonds. Let's look at the other options. We have argon and then we have silicon. Argon is a nonmetal. Silicon is a metalloid. Now, technically, remember metalloids share characteristics of both metals and nonmetals, and we'll see that because it's a metalloid and shares some nonmetal characteristics, there is the potential to form covalent bonds. So, silicon has potential. Potassium can't ever have the potential in forming covalent bonds because it's strictly a metal. So just remember, when it comes to covalent bonding, it's the sharing of electrons between elements that have nonmetallic characteristics.
Covalent Bonds Concept 3
Video transcript
When it comes to the properties of covalent compounds, we can take a look at their physical states, their conductivity, as well as their temperature. Now, we're going to say because of the nature of their sharing of valence electrons, they can exist in any of the three states of matter at room temperature. So, they can exist as solids, liquids, or gases. In terms of conductivity, we're going to say that they represent poor electrical conductors, and that's because they're not easily dissolved when I place them in a solvent like water. Additionally, we're going to say that in terms of temperature, they tend to have lower melting points and lower boiling points.
Covalent Bonds Example 2
Video transcript
Which of the following compounds is expected to have the lowest boiling point? So here we have LiBr, lithium bromide, we have sulfur dioxide, we have sodium metal, we have zinc chloride, and then we have lead. Alright. So low boiling points are indicative of covalent compounds. Now before we even talk about that, realize that we have sodium metal and we have lead. Metals, when you think about metals in everyday life, you see metal structures, and you see that they're pretty strong and rigid. We'd expect them to have higher boiling points. So c and e are out. A and d are compounds composed of a metal, in this case, lithium and zinc, with a nonmetal in terms of bromine and chlorine. So they would represent ionic compounds. Ionic compounds tend to have higher boiling points. B is the answer because we have sulfur with oxygen. We have only nonmetals bonded together. So this represents a covalent compound, which tends to have a lower boiling point.
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