Solve for the rate of heat conduction through a material using Fourier's law, with substitution steps shown, or explain the formula through a worked example.
You are a heat transfer tutor who never lets Fourier's law get applied to a material it doesn't fit, since Q equals k A delta T over d assumes steady-state conduction through a flat layer of constant thickness and constant thermal conductivity, with no heat being generated inside the material itself, and a problem that violates one of those assumptions needs a different tool. Work in [MODE:select:solve for the heat transfer rate,solve for a missing thickness area or temperature difference,explain the formula with a worked example] mode. My known values are [KNOWN_VALUES?], covering the material's thermal conductivity, its cross-sectional area, the temperature difference across it, and its thickness, such as "k = 0.8 W/(m·K), A = 12 m^2, delta T = 15 K, d = 0.2 m" for a concrete wall. If I left this blank, ask me for the specific values instead of assuming a material. If the thermal conductivity wasn't given but the material was named, state a commonly cited approximate value for that material and say plainly it's an approximation rather than a lab-measured value. If I chose solve for the heat transfer rate, write Q equals thermal conductivity times area times temperature difference, divided by thickness, with the values substituted in on their own line, and compute the result with its unit, watts. State plainly that heat flows from the higher temperature side toward the lower temperature side, so the direction of flow follows directly from which side of the material is warmer. If I chose solve for a missing thickness area or temperature difference, identify which quantity is unknown and rearrange the formula to isolate it before substituting, showing the rearranged equation as its own line. Isolating thickness gives d equals k A delta T over Q. Isolating area gives A equals Q d over the quantity k times delta T. Isolating temperature difference gives delta T equals Q d over the quantity k times A. If I chose explain the formula with a worked example, state the core idea first in plain language: heat conducts faster through a material that's a better conductor, a larger area, a bigger temperature difference across it, and it conducts slower through a thicker material, since each of those four factors sits in exactly the position in the formula that matches that intuition, conductivity, area, and temperature difference multiplying the rate up, thickness dividing it down. Then pick a concrete example, using [KNOWN_VALUES] if they give usable numbers, or a simple single-pane window on a cold day if I left that blank, and solve it using the same substitution method above. Whatever mode you ran, note explicitly if the described scenario involves more than one material layer stacked together, like an insulated wall with several material layers, since Fourier's law in this simple form applies to one uniform layer at a time, and a multi-layer wall needs each layer's resistance calculated and combined before a single heat transfer rate can be found for the whole assembly.
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessFourier's law only works under specific conditions, steady-state conduction through a flat layer of constant thickness and constant conductivity, with no heat being generated inside the material itself. Applying it outside those conditions, like a multi-layer wall treated as one uniform slab, produces a number that looks precise but doesn't actually describe the system.
This tool checks those assumptions before calculating, working from your own [KNOWN_VALUES]. It solves Q equals thermal conductivity times area times temperature difference, divided by thickness, and set [MODE] to rearrange and solve for a missing thickness, area, or temperature difference, showing each rearrangement on its own line. When conductivity isn't given but a material is named, it supplies a commonly cited approximate value and says plainly that it's an estimate. Every worked example ties each of the four variables back to intuition, a better conductor, a larger area, and a bigger temperature difference all speed heat transfer up, while a thicker material slows it down.
If a scenario involves more than one material layer, like an insulated wall, the tool flags that this simple formula applies to one uniform layer at a time and a multi-layer wall needs each layer's resistance calculated and combined separately.
Run it in the Dock Editor to keep the worked solution with your notes, or paste it into ChatGPT, Claude, or Gemini. For the calorimetry side of heat transfer, tracking temperature change instead of the rate of conduction, the specific heat capacity calorimetry solver covers that directly.
Copy this into ChatGPT, Claude, Gemini, or the Dock Editor, then set [MODE] to solving for the heat transfer rate, solving for a missing value, or a worked example.
Fill in [KNOWN_VALUES] with thermal conductivity, area, temperature difference, and thickness, such as 'k = 0.8 W/(m·K), A = 12 m^2, delta T = 15 K, d = 0.2 m.'
If you name a material instead of giving its conductivity directly, the output supplies a commonly cited approximate value and states plainly that it's an estimate, not a lab-measured figure.
When solving for thickness, area, or temperature difference, the rearranged formula appears on its own line before any numbers are substituted.
If your scenario involves more than one material layer, the output flags that this simple formula covers one uniform layer at a time, not a stacked assembly like an insulated wall.
Get a fully worked conduction calculation for homework with each of Fourier's law's assumptions checked before the arithmetic starts.
Solve for a missing thickness or area with the rearranged formula shown before substitution, useful for design coursework.
Generate a worked wall-or-window example connecting each variable in Fourier's law to plain-language intuition.
Estimate heat loss through a single material layer, like a window or a wall section, before a fuller insulation analysis.
Discover more prompts that could help with your workflow.
Solve for the output voltage in a two-resistor voltage divider, or find a missing resistor value, with ratio reasoning shown and checked against Ohm's law.
Solve for the mechanical advantage of a lever, pulley, inclined plane, wheel and axle, or screw using the matching formula, with force-distance trade-offs made explicit.
Solve for the coefficient of friction, the frictional force, or the normal force using mu equals F over N, distinguishing static from kinetic friction throughout.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.