Table of contents

1. Matter and Measurements4h 29m
2. Atoms and the Periodic Table5h 23m
3. Ionic Compounds2h 18m
4. Molecular Compounds2h 18m
5. Classification & Balancing of Chemical Reactions3h 17m
6. Chemical Reactions & Quantities2h 35m
7. Energy, Rate and Equilibrium3h 46m
8. Gases, Liquids and Solids3h 25m
9. Solutions4h 10m
10. Acids and Bases3h 29m
11. Nuclear Chemistry56m
BONUS: Lab Techniques and Procedures1h 38m
BONUS: Mathematical Operations and Functions47m
12. Introduction to Organic Chemistry1h 34m
13. Alkenes, Alkynes, and Aromatic Compounds2h 12m
14. Compounds with Oxygen or Sulfur1h 6m
15. Aldehydes and Ketones1h 1m
16. Carboxylic Acids and Their Derivatives1h 11m
17. Amines38m
18. Amino Acids and Proteins1h 51m
19. Enzymes1h 37m
20. Carbohydrates1h 46m
21. The Generation of Biochemical Energy2h 8m
22. Carbohydrate Metabolism2h 22m
23. Lipids2h 26m
24. Lipid Metabolism1h 45m
25. Protein and Amino Acid Metabolism1h 37m
26. Nucleic Acids and Protein Synthesis2h 54m

5. Classification & Balancing of Chemical Reactions

Balancing Redox Reactions (Simplified)

5. Classification & Balancing of Chemical Reactions

Balancing Redox Reactions (Simplified) - Online Tutor, Practice Problems & Exam Prep

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Balancing redox reactions involves understanding the transfer of electrons, focusing on both atom and charge balance. This process starts with identifying half reactions, which represent either oxidation or reduction. Typically, half reactions are derived from elements like oxygen and hydrogen. Mastering this method is essential for accurately balancing overall redox reactions, which are crucial in various chemical processes, including metabolic pathways and energy production.

Balancing Redox Reactions requires a new approach that accounts for the transfer of electrons between reactants.

Balancing Redox Reactions

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Balancing Redox Reactions (Simplified) Concept 1

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Balancing redox reactions requires a new approach that accounts for the transferring of electrons between reactants. Now we're going to say here that redox reactions not only balance the atoms of elements, but also charge and the number of electrons. To talk about balancing half of redox reactions, we take a look at half reactions. We're going to say here balancing a redox reaction begins with identifying its half reactions, and a half reaction is either the oxidation or reduction reaction portion of a redox reaction. Now we're going to say here usually a half reaction is obtained by identifying the elements that are found as oxygen and hydrogen. So we're going to go step by step in first identifying what half reactions are, and then later on the best way to balance an overall redox reaction.

Balancing a redox reaction begins with identifying its half reactions.

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Balancing Redox Reactions (Simplified) Example 1

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Identify the half reactions from the following redox reaction. We have manganese 5 ion reacting with chloride ion to produce manganese 2 ion and chlorine gas. To give our 2 half reactions, we basically match up elements that are not oxygen and hydrogen. So manganese will be matched up with manganese, chlorine will be matched up with chlorine. So my first half reaction would just be the manganese 5 ion giving directly the manganese 2 ion. And my other half reaction would be the chloride ion, giving me directly the chlorine gas. Here, don't forget the phases that are included, so these would be aqueous, and then here this would be aqueous, and this would be a gas. So we'd have 2 half reactions, one between the manganese ions and one with the chlorine elements.

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Balancing Redox Reactions (Simplified) Example 2

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So here we're going to balance this redox reaction. Here we have solid nickel and cobalt(III) ions reacting to produce nickel(II) ions and cobalt(II) ions. So, step 1 is we have to break the full redox reaction into two half-reactions. Remember, to do that, we match up elements with elements. So nickel matched with nickel ion. That'd be solid nickel gives me nickel(II) aqueous as one half-reaction, and then cobalt with cobalt. So cobalt(III) ion giving me cobalt(II) ion. Step 2, we balance the overall charge by adding electrons to the more positively charged side of each half-reaction. So what we're going to say here is, if we look, solid nickel here has no charge that we can see. If it did have a charge, it would be present, so its overall charge is 0. On the other side, we have nickel(II) ions, so the overall charge on this side is +2. We add electrons to the more positive side, so the right side, and we add enough electrons so that its overall charge here will match up with the overall charge over on the other side. So I need to go from +2 to 0 in terms of overall charge, that means I need to add 2 electrons. Let's go to the other half-reaction. Here this cobalt ion is +3, so the overall charge on this side is +3. And then here the overall charge is +2. I have to add electrons to the more positive side, so the cobalt(III) ion side, and I add enough electrons so that its charge overall matches the charge overall here on the lesser side. To do that, I'd have to add 1 electron. Alright. So one half-reaction has 2 electrons, the other one has 1. Now here underneath step 2, we say if the number of electrons of both reactions differ, then multiply to get the lowest common multiple. So here this is 2 electrons in this half-reaction, and this one here is 1 electron. So I'd have to multiply this half-reaction by 2 in order for this to become 2 electrons. Lastly, we combine the half-reactions and we cross out the electrons on both sides. Alright. So everything's going to come down. So we're going to have here solid nickel gives me nickel(II) aqueous, plus the 2 electrons. The other half-reaction I multiplied everything by 2, so that's 2 Co(III) aqueous plus 2 electrons gives me 2 Co(II) aqueous. So here the electrons cancel out, everything else comes down, so my balanced equation will be nickel solid + 2 cobalt(III) ions aqueous gives me 1 nickel(II) ion + 2 cobalt(II) ions. So this here would represent my balanced redox reaction.

Problem

Balance the following redox reaction.

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Here we have to balance the following redox reaction. So remember to do that, we match up elements with elements. So iron will be matched up with iron. So Fe^{2+}_{(aq)} gives me Fe_{(s)}, and then chromium with chromium. So chromium solid gives me Cr^{3+}_{(aq)}. So I've broken up my redox reaction into two half reactions. Next, I add electrons to the more positive side of each half reaction. Overall, the charge here is plus 2. Iron here has no charge whatsoever, if it did we would show it. So the overall charge here is 0. We add enough electrons on the more positive side so that both sides have the same overall charge at the end. So plus 2, I need to add 2 electrons, so that this side here comes out to 0 just like on the right side. Go to the other half reaction, this would be 0, and here plus 3, this would be plus 3. I have to add electrons with more positive sides, so I would have to add 3 electrons here, so that this side overall is 0, just like on the left side. Now remember, check to see if your electrons are the same. If they're not the same number, then we multiply by the lowest common multiple to get the lowest common multiple. The lowest common multiple between 2 and 3 is 6. So I'd multiply this by 3, and I'd multiply this by 2, so that I have 6 electrons in both half reactions. Bring down everything. So I've multiplied everything in the first half reaction by 3, and in the other half reaction I multiply everything by 2. Finally, I cancel out my electrons, and then what's left will be my balanced redox reaction. It doesn't matter the order that I write them in, as long as my reactants are still my reactants and my products are still the products with the correct coefficients, that's all that matters. Plus 3 iron solids. So this would be my balanced redox reaction.

Problem

Balance the following redox reaction.

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Balance the following redox reaction. So remember, to do that, we're going to match up elements with elements. So here's cerium four plus (Ce4+) aqueous will be related directly to cerium three plus (Ce3+) aqueous. Tin two plus (Sn2+) aqueous, we connect it to tin four plus (Sn4+) aqueous. Next, we're going to balance out the overall charges in both half reactions by adding electrons to the more positive side of each half reaction. So here, this side is plus four because the charge here is plus four, and here this is plus three. Here this is plus two, and this is plus four. I have to add electrons to the more positive side so that both sides are the same in terms of overall charge. So this side is plus four, and this side is plus three. I'll have to add one electron here, so at the end both sides are plus three. This side here is plus two, and this side here is plus four. Add electrons to the more positive side. I have to add two electrons here, so that this right side is plus two overall, just like this left side is plus two overall. Now, the number of electrons in both half reactions has to be the same. If not, you multiply to get the lowest common multiple, which would be two. Now bring down everything. So I multiplied everything by two. And then I didn't do anything to this half reaction, so I just bring it down as is. Cancel out electrons. Well, electrons are not equal; it's just electrons. Electrons have been canceled out. Bring down everything else that remains. So we have 2 Ce4+ aqueous plus Sn2+ aqueous, gives me 2 Ce3+ aqueous plus Sn4+ aqueous. So this would represent my balanced redox reaction at the end after I've eliminated electrons from both sides of the equations, the half reactions.

Problem

Balance the following redox reaction.

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Here we need to balance the following redox reaction. Now here's the thing, to correctly balance this, remember redox reaction involves reduction and oxidation. So you're only looking at the elements where oxidation numbers are changing. If an element's oxidation number doesn't change, it's not being oxidized or reduced and therefore should not be included within this balancing process. Alright. So we're gonna say here, if we look, Cl is in its natural state, so its oxidation number here is 0. Potassium is with iodide, potassium here is plus 1, iodide is minus 1. Potassium here is still plus 1, but now chlorine is minus 1. These are ionic compounds, so it's their charges are those numbers. Iodine here is in its natural state, so its oxidation number is 0. If you look carefully you'll see that potassium, its oxidation number stays the same throughout the whole process. So it's not being oxidized or reduced. It's chlorine and iodine whose oxidation numbers are changing, so they are what's important in terms of the redox reaction. So what we'd actually have is Cl2(aq)+I-(aq)⇒Cl-(aq)+I2(aq). These are what have oxidation numbers changing. So now we can break this up into its 2 half reactions. So chlorine with chlorine, iodine with iodine. So Cl2(aq)⇒Cl-(aq), I-(aq)⇒I2(aq). Alright. So now let's balance these half reactions. What's important here is to realize that the number of chlorines don't match on both sides. They have to when we're starting to balance out redox reactions. So I'd have to put a 2 here. Here there are 2 iodines here, but only 1 here, so I put a 2 here. Here. Now that I've balanced out my chlorine iodine, now I can start talking about adding electrons. Remember, we add electrons to the more positive side of each half reaction. Here, Cl2 is neutral, so the total charge on this side is 0. Here, chlorine, chlorine actually is minus 1, but there are 2 of them. So the overall charge here is minus 2. Add electrons to the more positive side, enough electrons so that both sides have the same overall charge at the end. I need 0 to become minus 2, so I have to add 2 electrons. Let's go to the other side. Here we have 2 times minus 1, so the overall charge here is minus 2. Iodine here, it doesn't have a charge that we can see, so overall charge here is 0. Again adding electrons to the more positive side, I have to add 2 electrons to this side here, so that both sides are minus 2 at the end. Notice now that both numbers of electrons are the same, so I don't need to multiply anything to get the lowest common multiple. So just bring down everything and cancel out your electrons to get your balanced overall redox reaction. So electrons here cancel out, So we're gonna have now Cl2(aq)+2I-(aq)⇒2Cl-(aq)+I2(aq) as my balanced redox reaction.

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What are the steps to balance a redox reaction?

Balancing a redox reaction involves several steps: (1) Identify the oxidation and reduction half-reactions. (2) Balance the atoms in each half-reaction, starting with elements other than oxygen and hydrogen. (3) Balance oxygen atoms by adding H₂O. (4) Balance hydrogen atoms by adding H⁺. (5) Balance the charge by adding electrons (e^-). (6) Multiply the half-reactions by appropriate coefficients to equalize the number of electrons transferred. (7) Add the half-reactions together and cancel out common species. (8) Verify that both mass and charge are balanced.

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How do you identify oxidation and reduction half-reactions?

To identify oxidation and reduction half-reactions, first determine the oxidation states of the elements in the reactants and products. The element whose oxidation state increases is undergoing oxidation (losing electrons), and the element whose oxidation state decreases is undergoing reduction (gaining electrons). Write separate half-reactions for each process, showing the transfer of electrons explicitly.

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Why is it important to balance both mass and charge in redox reactions?

Balancing both mass and charge in redox reactions is crucial because it ensures the conservation of matter and charge. In chemical reactions, atoms and charge cannot be created or destroyed. Balancing mass ensures that the number of atoms of each element is the same on both sides of the equation, while balancing charge ensures that the total charge is the same on both sides, reflecting the principle of charge conservation.

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What role do half-reactions play in balancing redox reactions?

Half-reactions play a critical role in balancing redox reactions by separating the oxidation and reduction processes. This separation allows for a more straightforward approach to balancing the atoms and charges involved. By focusing on each half-reaction individually, you can ensure that the electrons lost in oxidation are equal to the electrons gained in reduction, facilitating the overall balance of the redox reaction.

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Can you provide an example of balancing a redox reaction?

Sure! Let's balance the redox reaction between MnO₄^- and Fe²⁺ in acidic solution. (1) Write the half-reactions: MnO₄^- → Mn²⁺ and Fe²⁺ → Fe³⁺. (2) Balance atoms other than O and H: Mn is already balanced. (3) Balance O by adding H₂O: MnO₄^- → Mn²⁺ + 4H₂O. (4) Balance H by adding H⁺: MnO₄^- + 8H⁺ → Mn²⁺ + 4H₂O. (5) Balance charge by adding e^-: MnO₄^- + 8H⁺ + 5e^- → Mn²⁺ + 4H₂O and Fe²⁺ → Fe³⁺ + e^-. (6) Multiply half-reactions to equalize electrons: 5Fe²⁺ → 5Fe³⁺ + 5e^-. (7) Add half-reactions: MnO₄^- + 8H⁺ + 5Fe²⁺ → Mn²⁺ + 4H₂O + 5Fe³⁺. (8) Verify balance: both mass and charge are balanced.