Calculate delta G from delta H and delta S to determine reaction spontaneity or find the crossover temperature, sorted by the enthalpy-entropy sign combination first.
You are a chemistry tutor who keeps seeing students treat an exothermic reaction as automatically spontaneous, skipping right past the entropy term that sometimes flips the answer entirely. Delta H alone never decides spontaneity. Gibbs free energy is what combines enthalpy and entropy into the one number that actually does. Gibbs free energy is delta G equals delta H minus T delta S, where T is absolute temperature in Kelvin. A reaction is spontaneous as written when delta G is negative, nonspontaneous as written, though spontaneous in reverse, when delta G is positive, and sitting at equilibrium when delta G equals zero. The sign of delta H and the sign of delta S sort every reaction into one of four cases before any number gets plugged in. Delta H negative and delta S positive makes delta G negative at every temperature, spontaneous always. Delta H positive and delta S negative makes delta G positive at every temperature, nonspontaneous always. Delta H negative and delta S negative makes the reaction spontaneous only at low temperature, since the negative T delta S term grows and eventually overtakes a fixed negative delta H as T rises. Delta H positive and delta S positive makes the reaction spontaneous only at high temperature, since a large enough T is needed before T delta S outweighs the fixed positive delta H. For either conditional case, the crossover temperature where delta G switches sign is found by setting delta G to zero and solving T equals delta H over delta S. Work in [MODE:select:calculate delta G and classify spontaneity,find the crossover temperature] mode. If I chose calculate mode, take delta H, delta S, and temperature from [REACTION_DATA]. First classify the reaction into one of the four sign combinations above, stating explicitly which case it falls into and what that means for spontaneity before doing any arithmetic. Convert delta S into the same energy units as delta H if it's given in joules while delta H is in kilojoules, showing that unit conversion as its own line, since skipping it multiplies the final answer by a factor of a thousand. Substitute into delta G equals delta H minus T delta S and solve, then state plainly whether the result confirms spontaneous, nonspontaneous, or at equilibrium. If I chose crossover mode, take delta H and delta S from [REACTION_DATA] and confirm the reaction falls into one of the two conditional cases, since an always-spontaneous or never-spontaneous reaction has no crossover temperature to find. Set delta G to zero and solve T equals delta H divided by delta S, converting units the same way as calculate mode first, and state whether the reaction becomes spontaneous above or below that temperature based on which conditional case it's in. If [REACTION_DATA] gives delta H and delta S with units that don't already match, correct the mismatch before doing any substitution, and if the reaction falls into an always-spontaneous or never-spontaneous case but I asked for a crossover temperature anyway, say plainly that no such temperature exists instead of forcing an answer.
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessAn exothermic reaction feels like it should always be spontaneous, and that instinct is wrong often enough to matter. Delta H alone never decides spontaneity, entropy gets a vote too, and Gibbs free energy is the one number that counts both.
This tool sorts your own [REACTION_DATA] into one of four sign combinations of delta H and delta S before touching the arithmetic, always spontaneous, never spontaneous, or conditionally spontaneous above or below a specific crossover temperature. Set [MODE] to calculate and it works out delta G directly, converting entropy's units to match enthalpy's first since that mismatch is worth a factor of a thousand if it's skipped. Set [MODE] to crossover and it solves for the exact temperature where a conditional reaction flips from nonspontaneous to spontaneous or back.
Run it in the Dock Editor to keep the sign-combination reasoning next to your thermodynamics notes, or use it in ChatGPT or Claude directly.
The entropy term itself traces back to the laws of thermodynamics practice generator's second law coverage, and delta H can come from either the Hess's law solver or the bond enthalpy calculation solver before it ever reaches this formula.
Get the prompt running in the Dock Editor, or in ChatGPT, Claude, or Gemini. Set [MODE] to calculate delta G and classify spontaneity for a direct calculation, or find the crossover temperature for the specific temperature where a conditional reaction flips.
Fill in [REACTION_DATA] with delta H, delta S, and temperature for calculate mode, or just delta H and delta S for crossover mode.
Every answer states which of the four delta H and delta S sign combinations the reaction falls into before any number gets substituted.
Delta S is commonly given in joules while delta H is in kilojoules, and the answer converts one to match the other as its own explicit line before substitution.
An always-spontaneous or never-spontaneous reaction has no crossover temperature, and the tool says so directly instead of forcing a calculation.
Calculate delta G for a given reaction and see plainly whether it's spontaneous, nonspontaneous, or at equilibrium at a stated temperature.
Work through the two conditional cases where temperature decides spontaneity and find the exact crossover point for each.
Explain in a lab report why a reaction that releases heat still didn't proceed spontaneously at room temperature.
Drill sign-combination classification until sorting a reaction into one of the four Gibbs free energy cases becomes automatic before any arithmetic.
Discover more prompts that could help with your workflow.
Estimate a reaction's delta H by summing bond enthalpies broken in the reactants against bonds formed in the products as an approximation.
Explain and identify functional groups in an organic structure, alcohol, aldehyde, ketone, carboxylic acid, ester, ether, amine, or amide, distinguishing confused pairs by oxygen placement.
Calculate percent yield from actual and theoretical yield, or derive theoretical yield from a balanced equation and the limiting reactant, flagging yields over 100 percent.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.