Now the first law of thermodynamics says that energy cannot be created nor destroyed. What happens instead is that it's transferred between our system and its surroundings. Now when we say system, the system represents the chemical reaction because we're in chemistry, represents a chemical reaction or a substance that is being studied or analyzed. The surroundings are everything else that is not that substance or not that chemical reaction. So if we take a look here at this image, we have a container. Inside of this container, we have gas molecules. Let's suppose that the gas molecules are what I am studying and observing. The gas molecules represent my system. The container is just what holds my system. It itself is not the system. I'm only examining the gases, not the container. So the container and everything outside the container, including you, me, the universe would be our surroundings. Both of these ideas together deal with the first law of thermodynamics. So just remember, you can't create energy, you can't destroy energy. It just changes from one form to another, and changing from one form to another means the transferring of energy between systems and surroundings.
- 1. The Chemical World9m
- 2. Measurement and Problem Solving2h 25m
- 3. Matter and Energy2h 15m
- Classification of Matter18m
- States of Matter8m
- Physical & Chemical Changes19m
- Chemical Properties8m
- Physical Properties5m
- Temperature (Simplified)9m
- Law of Conservation of Mass5m
- Nature of Energy5m
- First Law of Thermodynamics7m
- Endothermic & Exothermic Reactions7m
- Heat Capacity16m
- Thermal Equilibrium (Simplified)8m
- Intensive vs. Extensive Properties13m
- 4. Atoms and Elements2h 33m
- The Atom (Simplified)9m
- Subatomic Particles (Simplified)12m
- Isotopes17m
- Ions (Simplified)22m
- Atomic Mass (Simplified)17m
- Periodic Table: Element Symbols6m
- Periodic Table: Classifications11m
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- Periodic Table: Representative Elements & Transition Metals7m
- Periodic Table: Phases (Simplified)8m
- Periodic Table: Main Group Element Charges12m
- Atomic Theory9m
- Rutherford Gold Foil Experiment9m
- 5. Molecules and Compounds1h 50m
- Law of Definite Proportions9m
- Periodic Table: Elemental Forms (Simplified)6m
- Naming Monoatomic Cations6m
- Naming Monoatomic Anions5m
- Polyatomic Ions25m
- Naming Ionic Compounds11m
- Writing Formula Units of Ionic Compounds7m
- Naming Acids18m
- Naming Binary Molecular Compounds6m
- Molecular Models4m
- Calculating Molar Mass9m
- 6. Chemical Composition1h 23m
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- 8. Quantities in Chemical Reactions1h 16m
- 9. Electrons in Atoms and the Periodic Table2h 32m
- Wavelength and Frequency (Simplified)5m
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- Bohr Model (Simplified)9m
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- Electronic Structure4m
- Electronic Structure: Shells5m
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- Electronic Structure: Orbitals11m
- Electronic Structure: Electron Spin3m
- Electronic Structure: Number of Electrons4m
- The Electron Configuration (Simplified)20m
- The Electron Configuration: Condensed4m
- Ions and the Octet Rule9m
- Valence Electrons of Elements (Simplified)5m
- Periodic Trend: Metallic Character4m
- Periodic Trend: Atomic Radius (Simplified)7m
- Periodic Trend: Ionization Energy (Simplified)9m
- Periodic Trend: Electron Affinity (Simplified)7m
- Electron Arrangements5m
- The Electron Configuration: Exceptions (Simplified)12m
- 10. Chemical Bonding2h 10m
- Lewis Dot Symbols (Simplified)7m
- Ionic Bonding6m
- Covalent Bonds6m
- Lewis Dot Structures: Neutral Compounds (Simplified)8m
- Bonding Preferences6m
- Multiple Bonds4m
- Lewis Dot Structures: Multiple Bonds10m
- Lewis Dot Structures: Ions (Simplified)8m
- Lewis Dot Structures: Exceptions (Simplified)12m
- Resonance Structures (Simplified)5m
- Valence Shell Electron Pair Repulsion Theory (Simplified)4m
- Electron Geometry (Simplified)7m
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- Dipole Moment (Simplified)14m
- Molecular Polarity (Simplified)7m
- 11 Gases2h 15m
- 12. Liquids, Solids, and Intermolecular Forces1h 11m
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- 15. Chemical Equilibrium1h 27m
- 16. Oxidation and Reduction1h 33m
- 17. Radioactivity and Nuclear Chemistry53m
First Law of Thermodynamics - Online Tutor, Practice Problems & Exam Prep
The first law of thermodynamics states that energy cannot be created or destroyed, only transferred between a system, such as a chemical reaction, and its surroundings. Heat (q) flows from hot to cold, with positive q indicating heat gain and negative q indicating heat loss. Work (w) is the force exerted by reacting molecules; negative w occurs when the system does work on the surroundings, while positive w occurs when the surroundings do work on the system. Understanding these concepts is crucial for analyzing energy changes in chemical reactions.
The First Law of Thermodynamics states that energy cannot be created nor destroyed, but instead is transferred.
Understanding the First Law of Thermodynamics
First Law of Thermodynamics
Video transcript
First Law of Thermodynamics Example 1
Video transcript
Now a chemist, wishing to determine the final temperature of 30 grams of a metal ore, places it into an insulated beaker containing 615.5 grams of water at 42.18 degrees Celsius. It is determined that the metal gains 19.11 kilojoules of energy. From the information provided, determine the system and the surroundings.
Alright. So, the chemist wishes to determine the final temperature of the metal ore, which means he is trying to analyze that metal ore. Therefore, the metal ore is what is of interest to us and must represent our system; it is our substance being analyzed. And then, what else is being talked about? Well, they're talking about the water, right? So the water itself is around; it submerges the metal ore, but we're not primarily concerned with it. Hence, the water itself must represent our surroundings.
Just remember, if we're trying to find some information on an object or chemical reaction, if we're trying to analyze them, they represent our system. Everything that is not the system has to be our surroundings.
First Law of Thermodynamics
Video transcript
Now to understand the transferring of energy between systems and surroundings, you first have to understand the idea of heat versus work. Heat uses the variable of q. Heat represents just the flow of thermal energy from a higher temperature object to a lower temperature object. So, heat is moving from something hotter to something colder. And we are going to say here work, which is represented by w, is just the movement of reacting molecules against gravity or an opposing force. If you are moving against an opposing force or against gravity, some work has to be done on your part. So, just remember, heat and work have to do with this transferring of energy between system and surroundings. Click on the next video and let's see what happens to the signs of q and w under different circumstances.
Heat is the flow of thermal energy while work is the movement of reacting molecules.
First Law of Thermodynamics
Video transcript
Now remember, heat is the flow of energy, more specifically thermal energy between a hotter object towards a colder object. So in heat applications, it transfers heat from a hotter object to a colder object. Let's assume that the sphere on the left is at a higher temperature, and then the sphere on the right is at a lower temperature. Heat naturally moves from a place that is hotter to a place that is colder. Now the system on the left is losing heat, and this one here is gaining heat. Well, if you are losing, so if it loses, evolves, releases, or gives off heat, then the sign of q would be negative. On the other side, the heat is going towards the colder object, so it is gaining heat. So if a system gains, absorbs, or takes any heat, then it has a positive q. That's the way we observe the signs of q. If heat is being moved, whoever is gaining the heat is positive q, whoever is losing the heat is negative q.
Work is a little bit different. Work is the force done by reacting molecules on a frictionless piston. Alright. So we're going to say here, let's say we have our gas molecules in this container and the piston here can move up or down. Let's say the gas molecules themselves want to be spread out even more from each other and they decide to push up against the piston, so they're doing work on the piston here. As a result of doing work on the piston here, they are going to have a negative w. If the system does work on the surroundings, it is a negative w. The surroundings here would be the piston or the container. Conversely, let's say the gas molecules are just hanging around, not doing anything, and some outside force decides to push down on this piston. The piston again is our surroundings. It's going to come down and it's going to squeeze down on the gas molecules. In this case, the surroundings are doing work on the system. If the surroundings are doing work on the system and the system is doing nothing, then work will be positive. That's because the system is not working against an opposing force. It's just sitting back and letting it happen. So just remember, q and w can be positive or negative depending on situations. So just remember, if our system gains heat, it's positive q. If it loses heat, it's negative q. If the system does any type of work, it's going to be a negative w, and if the surroundings do work on the system, then it's positive w.
What are the signs of q and w when a system loses heat while doing work on the surroundings?
Here’s what students ask on this topic:
What is the first law of thermodynamics?
The first law of thermodynamics states that energy cannot be created or destroyed, only transferred between a system and its surroundings. In other words, the total energy of an isolated system remains constant. This principle is also known as the law of energy conservation. In a chemical context, the system refers to the chemical reaction or substance being studied, while the surroundings include everything else. Energy can be transferred in the form of heat (q) or work (w), but the total energy change of the system and surroundings combined is always zero.
How does heat transfer between systems and surroundings?
Heat transfer between systems and surroundings occurs from a higher temperature object to a lower temperature object. This flow of thermal energy is represented by the variable q. If a system loses heat, it has a negative q, indicating heat is being released to the surroundings. Conversely, if a system gains heat, it has a positive q, indicating heat is being absorbed from the surroundings. The direction of heat flow is always from hot to cold, following the natural tendency to reach thermal equilibrium.
What is the difference between heat (q) and work (w) in thermodynamics?
In thermodynamics, heat (q) and work (w) are two forms of energy transfer between a system and its surroundings. Heat represents the flow of thermal energy from a higher temperature object to a lower temperature object. Work, on the other hand, is the energy transfer that occurs when a force is applied over a distance. Work is done by the system when it exerts a force on its surroundings, resulting in a negative w. Conversely, work is done on the system by the surroundings, resulting in a positive w. Both heat and work contribute to the overall energy change in a system.
How do the signs of q and w change under different circumstances?
The signs of q and w change based on the direction of energy transfer. For heat (q), if the system gains heat, q is positive, indicating heat absorption. If the system loses heat, q is negative, indicating heat release. For work (w), if the system does work on the surroundings, w is negative, indicating energy expenditure. If the surroundings do work on the system, w is positive, indicating energy gain. These sign conventions help in analyzing energy changes in chemical reactions and other thermodynamic processes.
What is the significance of the first law of thermodynamics in chemical reactions?
The first law of thermodynamics is significant in chemical reactions because it helps in understanding and quantifying energy changes. During a chemical reaction, energy can be transferred as heat or work between the system (the reacting substances) and the surroundings. By applying the first law, we can determine the energy balance and predict the behavior of the reaction. This principle is crucial for calculating enthalpy changes, understanding reaction spontaneity, and designing energy-efficient processes in chemistry and engineering.