The Name’s Bond ... Ionic Bond.
The Name’s Bond ... Ionic Bond.
This is the first in my short series of the three main types of bond - ionic, metallic and covalent. In this, you’ll learn about the properties of the compounds, which atoms they’re found between and how the bonds are formed. Enjoy!
When electrons are transferred from a metal to a non-metal, an ionic compound is formed. Metals usually lose electrons and non-metals usually gain them to get to a noble gas configuration. Transition metals do not always achieve this.
Charged particles that have either lost or gained electrons are called ions and are no longer neutral - metal atoms lose electrons to become positive ions (cations) whereas non-metals gain electrons to become negative ions (anions).
The formation of these ions is usually shown using electron configurations. Make sure you know that the transfer of electrons is not the bond but how the ions are formed.
An ionic bond is the electrostatic attraction between oppositely charged ions.
You need to know how to explain how atoms react with other atoms and for this the electron configurations are needed. You can use dot and cross diagrams for this.
Ionic solids hold ions in 3D structures called ionic lattices. A lattice is a repeating 3D pattern in a crystalline solid. For example, NaCl has a 6:6 arrangement - each Na+ ion is surrounded by 6 Cl- and vice versa.
Ionic solids have many strong electrostatic attractions between their ions. The crystalline shape can be decrepitated (cracked) on heating. Ionic Lattices have high melting and boiling points since they need more energy to break because atoms are held together by lots of strong electrostatic attractions between positive and negative ions. The boiling point of an ionic compound depends on the size of the atomic radius and the charge of the ion. The smaller the ion and the higher the charge, the stronger attraction.
Look at this diagram. It shows how atomic radius decreases across a period regularly. This is not the case with the ions. Positive ions are usually smaller than the atoms they came from because metal atoms lose electrons meaning the nuclear charge increases which draws the electrons closer to the nucleus. For negative ions, they become larger because repulsion between electrons moves them further away - nuclear charge also decreases as more electrons to the same number of protons.
Ionic substances can conduct electricity through the movement of charged particles when molten or dissolved (aqueous). This is because when they are like this, electrons are free to move and carry a charge. Ionic solids cannot conduct electricity.
Ionic compounds are usually soluble in water. This is because the polar water molecules cluster around ions which have broken off the lattice and so separate them from each other. Some substances like aluminium oxide have too strong electrostatic attractions so water cannot break up the lattice - it is insoluble in water.
Molecular ions such as sulfate, nitrate, ammonium or carbonate can exist within ionic compounds. These compounds may have covalent bonds within the ions but overall they are ionic and exhibit thee properties described above.
SUMMARY
When electrons are transferred from a metal to a non-metal, an ionic compound is formed.
Charged particles that have either lost or gained electrons are called ions and are no longer neutral - metal atoms lose electrons to become positive ions (cations) whereas non-metals gain electrons to become negative ions (anions).
The formation of these ions is usually shown using electron configurations. The transfer of electrons is not the bond but how the ions are formed.
An ionic bond is the electrostatic attraction between oppositely charged ions.
Ionic solids hold ions in 3D structures called ionic lattices. A lattice is a repeating 3D pattern in a crystalline solid.
Ionic solids have many strong electrostatic attractions between their ions. The crystalline shape can be decrepitated (cracked) on heating.
Ionic Lattices have high melting and boiling points since they need more energy to break because atoms are held together by lots of strong electrostatic attractions between positive and negative ions.
The boiling point of an ionic compound depends on the size of the atomic radius and the charge of the ion. The smaller the ion and the higher the charge, the stronger attraction.
Positive ions are usually smaller than the atoms they came from because metal atoms lose electrons meaning the nuclear charge increases which draws the electrons closer to the nucleus. Negative ions become larger because repulsion between electrons moves them further away - nuclear charge also decreases as more electrons to the same number of protons.
Ionic substances can conduct electricity through the movement of charged particles when molten or dissolved (aqueous). This is because when they are like this, electrons are free to move and carry a charge. Ionic solids cannot conduct electricity.
Ionic compounds are usually soluble in water because the polar water molecules cluster around ions which have broken off the lattice and so separate them from each other.
Some substances like aluminium oxide have too strong electrostatic attractions so water cannot break up the lattice - it is insoluble in water.
Molecular ions such as sulfate, nitrate, ammonium or carbonate can exist within ionic compounds. These compounds may have covalent bonds within the ions but overall they are ionic and exhibit thee properties described above.
More Posts from Amateurchemstudent and Others
#OTD a year ago, Moderna’s RNA vaccine became the first #COVID19 vaccine to enter phase 1 trials. The latest #ChemVsCOVID graphic with the Royal Society of Chemistry takes a brief look at how prior research helped COVID vaccines reach this point quickly: https://ift.tt/3cE5xHR https://ift.tt/3rV4v0F
#Thunderstorms are hitting the UK this week – here’s how thunder and lightning happen and some of the chemistry going on during a storm: https://ift.tt/2XUCKZc https://ift.tt/3gJ7ALD
Slice of Life
Water: Making a Splash
You don’t have to be a genius to know that water is essential for life. After all, we’re made up of it, we sweat it, we drink it, some people even opt to give birth in it. But what is it about two hydrogens and an oxygen which make it so sensational?
The answer is to do with water’s structure. A H2O molecule is covalently bonded, which means each atom shares electrons. In this case, the covalent bonds are between two hydrogen atoms and one oxygen atom. Oxygen is cool because it is highly electronegative. Electronegativity is the ability for one atom to “pull” the electrons towards it in a covalent bond. Since oxygen is highly electronegative, it pulls the electrons in the bond towards it which gives the oxygen a slight negative charge because of the electron proximity. This is represented by δ- (delta negative). The hydrogen is therefore δ+ (delta positive) and has a slight positive charge. Overall, the molecule is said to be polar, or to be dipolar in nature, because there is a difference in charge across the molecule.
Water being a dipole gives it different properties, which you need to know about if you are sitting the AS or A level biology exam.
A quick note on hydrogen bonding…
Being a dipole, water has areas of different charge. When many molecules come together, hydrogen bonds can form between H+ on one molecule and O- on another, shown in the diagram with a dashed line.
It is hydrogen bonds which give water a property called surface tension. Water has a high tendency to ‘stick together’, called cohesion. This is important in water transport through the xylem in later units. Surface tension is a bit like a “skin” because it can allow small organisms to walk along it. It occurs because water molecules on the surface bond to their neighbours much like throughout the whole liquid, but since one side is exposed to air and cannot form hydrogen bonds upwards, they will form stronger ones with the molecules beside them. The net attraction is downwards.
Water is good as a temperature buffer too. Heating a substance makes its particles gain more kinetic energy and therefore the overall temperature rises since particles are moving faster. With water, the temperature doesn’t rise as much as other liquids do. This is because it takes more heat energy to raise the temperature of water by 1 degree - it has a high specific heat capacity due to the many hydrogen bonds that have to be broken (even though they are weak on their own). It takes a lot of heat energy for water to raise its temperature significantly.
This is useful in organisms because our cells are mostly water, which can absorb heat energy without raising our temperature very much. Therefore it “buffers” or reduces heat changes. Seas, lakes and oceans are all good environments to live in because they do not change temperature as quickly as air. Aquatic organisms have an environment with less temperature fluctuation than land organisms.
Having a high latent heat of vaporisation means water can cool down organisms by evaporating a small amount of water. Evaporation is when water becomes a gas due to the large amount of KE. Fast-moving molecules are removed when this occurs and take their energy with them, therefore decreasing the amount of energy left behind and cooling it. Sweat is a good example of high latent heat of vaporisation. A small quantity of water is removed with a large cooling effect, meaning temperature is stabilised without losing a lot of water.
Water is also a good solvent (a substance which can dissolve other substances) and this is due to more hydrogen bonding. Water’s charges of H+ and O- are attracted to the positive and negative charges on molecules and therefore solutes such as NaCl are split into Na+ and Cl-, then spread out. Solvent properties are important in transport (such as blood plasma dissolving glucose, vitamins, urea etc), metabolic reactions, urine production and mineral transportation through the xylem and phloem in plants.
Water molecules can also take place in metabolic reactions. Hydrolysis reactions involve breaking down the covalent bonds between hydrogen and oxygen and making new ones, for example, in digestion. Condensation reactions produce water as a byproduct e.g. the formation of phosphodiester bonds. Water is referred to as a metabolite.
Summary
Water is a dipole due to the slight opposite charges on oxygen and hydrogen atoms.
Hydrogen bonds form between hydrogens on one water molecule and oxygens on another.
Because of this, water has the tendency to stick to itself - cohesion. Cohesion is the reason for surface tension.
Water is a good temperature buffer because of its high specific heat capacity. It takes a lot of energy to raise the temperature by a degree.
Water has a high latent heat of vaporisation so evaporating a little has a large cooling effect.
Water is a good solvent because of how the hydrogen bonds attract charged molecules and separate them. This is useful for transporting solutions.
Water is a metabolite important for hydrolysis reactions and produced in condensation reactions.
Happy studying!
Covalent and Dative Bonds
Covalent and dative (sometimes called co-ordinate) bonds occur between two or more non-metals, e.g. carbon dioxide, water, methane and even diamond. But what actually are they?
A covalent bond is a chemical bond that involves the sharing of electron pairs between atoms. They are found in molecular elements or compounds such as chlorine or sulfur, but also in macromolecular elements and compounds like SiO2 and graphite. Covalent bonds are also found in molecular ions such as NH4+ and HCO3-.
Single covalent bonds have just one shared pair of electrons. Regularly, each atom provides one unpaired electron (the amount of unpaired electrons is usually equal to the number of covalent bonds which can be made) in the bond. Double covalent bonds have two shared pairs of electrons, represented by a double line between atoms, for example, O=C=O (CO2). Triple covalent bonds can also occur such as those in N ≡ N.
Dot and cross diagrams represent the arrangement of electrons in covalently bonded molecules. A shared pair of electrons is represented by a dot and a cross to show that the electrons come from different atoms.
Unpaired electrons are used to form covalent bonds as previously mentioned. The unpaired electrons in orbitals of one atom can be shared with another unpaired electron in an orbital but sometimes atoms can promote electrons into unoccupied orbitals in the same energy level to form more bonds. This does not always occur, however, meaning different compounds can be formed - PCl3 and PCl4 are examples of this.
An example where promotion is used is in sulfur hexafluoride (SF6). The regular configuration of sulfur atoms is 1s2 2s2 2p6 3s2 3p4. It promotes, as shown in the diagram (see excited state), two electrons: one from the 3s electrons to the 3d orbital and one from the 3p to the 3d. Therefore there are 6 unpaired electrons for fluorine atoms to join. It has an octahedral structure.
An atom which has a lone pair (a pair of electrons uninvolved in bonding) of electrons can form a coordinate bond with the empty orbital of another atom. It essentially donates an electron into this orbital which when formed, acts the same as a normal covalent bond. A coordinate bond therefore contains a shared pair of electrons that have come from one atom.
When ammonia reacts with a H+ ion, a coordinate bond is formed between the lone pair on the ammonia molecule and the empty 1s sub-shell in the H+ ion. An arrow represents the dative covalent bond (coordinate bond). Charges on the final ion must be showed.
Summary
A covalent bond is a chemical bond that involves the sharing of electron pairs between atoms. They are found in molecular elements or compounds as well as in macromolecular elements and compounds. Also found in molecular ions.
Single covalent bonds have just one shared pair of electrons. Double covalent bonds have two shared pairs of electrons, represented by a double line between atoms. Triple covalent bonds can also occur.
Dot and cross diagrams represent the arrangement of electrons in covalently bonded molecules. A shared pair of electrons is represented by a dot and a cross to show that the electrons come from different atoms.
Unpaired electrons are used to form covalent bonds - they can be shared with another unpaired electron in an orbital but sometimes atoms can promote electrons into unoccupied orbitals in the same energy level to form more bonds. This does not always occur, however, meaning different compounds can be formed.
An example where promotion is used is in sulfur hexafluoride (SF6).
An atom which has a lone pair (a pair of electrons uninvolved in bonding) of electrons can form a coordinate bond with the empty orbital of another atom.
It donates an electron into this orbital which when formed, acts the same as a normal covalent bond. A coordinate bond therefore contains a shared pair of electrons that have come from one atom.
When ammonia reacts with a H+ ion, a coordinate bond is formed between the lone pair on the ammonia molecule and the empty 1s sub-shell in the H+ ion. An arrow represents the dative covalent bond (coordinate bond). Charges on the final ion must be showed.
It’s day 5 of #ChemAdvent – here’s why peppermint candy canes make your mouth feel cold! bit.ly/chemadvent2020 https://ift.tt/2JM6bZ7
i just learned from animal crossing that pondskaters stay on top of the water by secreting an oil from their feet
that seems kinda obvious in hindsight. i always figured they were just, like, light enough to not break surface tension
Plenty of opportunities to wear sunglasses this week! 😎 Here’s the science behind how the protect your eyes from the sun’s UV radiation in C&EN: https://ift.tt/2XW7h8L https://ift.tt/3gT8PI6
-
beau-lv13 reblogged this · 2 years ago -
svefnsmal liked this · 2 years ago -
number1nerd reblogged this · 3 years ago -
amateurchemstudent reblogged this · 4 years ago -
amateurchemstudent liked this · 4 years ago
-
random-stuff-i-guess liked this · 5 years ago -
thesoftestcherub liked this · 5 years ago -
rescuestudies reblogged this · 5 years ago -
khadooy8 reblogged this · 5 years ago -
jade12358 liked this · 6 years ago -
bioqueen liked this · 6 years ago -
the-holistic-stuff liked this · 6 years ago -
dolce-jasmine-blog liked this · 6 years ago -
prtty-littr-psyco liked this · 6 years ago -
mysugarvenom liked this · 6 years ago -
thefuturelawyer liked this · 6 years ago -
zephirahredrew liked this · 7 years ago -
kirbay-zh liked this · 7 years ago -
electronicstarlightfestival reblogged this · 7 years ago -
b4ngchanlover liked this · 7 years ago -
princessx-grunge reblogged this · 7 years ago -
poorarthoes reblogged this · 7 years ago -
hooyomatalo liked this · 7 years ago -
igot7stuff-blog liked this · 7 years ago -
studeres reblogged this · 7 years ago -
blueberry-pancakes-stuff liked this · 7 years ago -
as-studypeach reblogged this · 7 years ago -
k2study reblogged this · 7 years ago -
obsessxdmuch liked this · 7 years ago -
mamisgxrl-blog liked this · 7 years ago
-
future-geneius-study liked this · 7 years ago -
malfoyfever-blog reblogged this · 7 years ago -
malfoyfever-blog liked this · 7 years ago
-
chaoticcspice liked this · 7 years ago -
quantumskies-blog liked this · 7 years ago -
hihellobye-123-blog liked this · 7 years ago -
aphex789 liked this · 7 years ago
-
miastudys liked this · 7 years ago -
studeres reblogged this · 7 years ago
-
kristofer1979 liked this · 7 years ago -
as-studypeach reblogged this · 7 years ago
