Quickly translate heat capacity into practical units. Ideal for labs, cooking, materials, and engineering checks. See conversions, steps, and tables in one place today.
This tool converts specific heat capacity through a single base unit: J/(g·°C). Temperature differences in K and °C are equivalent in size.
Typical specific heat capacity values (approximate) are shown for reference.
| Material | J/(g·°C) | J/(kg·K) | cal/(g·°C) |
|---|---|---|---|
| Water (liquid) | 4.184 | 4184 | 1.000 |
| Aluminum | 0.897 | 897 | 0.214 |
| Copper | 0.385 | 385 | 0.092 |
| Steel (average) | 0.490 | 490 | 0.117 |
| Granite | 0.790 | 790 | 0.189 |
Specific heat capacity tells how much energy is needed to raise temperature. In J/(g·°C), the value means joules required to warm one gram by one Celsius degree. Water is about 4.184, so 1 g of water needs 4.184 J for a 1 °C rise.
A temperature difference of 1 K equals a difference of 1 °C. That is why J/(kg·K) and J/(kg·°C) behave the same for changes, even though their zero points differ. The calculator uses this equivalence to simplify heat-capacity conversions.
Mass units change by factors of 1000. Converting from J/(kg·K) to J/(g·°C) divides by 1000. Example: 4184 J/(kg·K) becomes 4.184 J/(g·°C). This is common when moving between engineering tables and lab measurements.
Many references still use calories. The thermochemical calorie uses 1 cal = 4.184 J. If a material is 0.214 cal/(g·°C), it equals about 0.214 × 4.184 = 0.895 J/(g·°C). The tool applies this factor consistently for both directions.
HVAC and older US data often appears in BTU/(lb·°F). This unit combines energy, mass, and Fahrenheit difference. The conversion uses 1 BTU = 1055.05585262 J, 1 lb = 453.59237 g, and 1 °F difference = 5/9 °C difference. These constants keep the result traceable.
If your data comes from heaters and power logs, Wh-based units can help. Since 1 Wh = 3600 J, Wh/(kg·K) converts to J/(g·°C) by multiplying by 3600 and dividing by 1000. For example, 0.30 Wh/(kg·K) is about 1.08 J/(g·°C).
Many metals fall between 0.35 and 0.95 J/(g·°C): copper is near 0.385 and aluminum is near 0.897. Rocks are often around 0.7 to 0.9. Liquid water near room temperature sits around 4.184, so values far above 1 usually indicate liquids or moisture-rich materials.
Higher precision is useful for intermediate calculations, but it does not improve input accuracy. If your source value is rounded, keep output rounding similar to avoid false certainty. For reporting, 3–4 decimals works well for J/(g·°C), while J/(kg·K) often uses whole numbers.
Yes. A 1000× mass change cancels a 1000× energy prefix, so 1 J/(g·°C) equals 1 kJ/(kg·K). Temperature step size is the same for °C and K.
This calculator converts temperature differences, not absolute temperatures. A 1 K rise equals a 1 °C rise, so specific heat capacity uses the same step size in both scales.
It uses the thermochemical calorie, defined as 4.184 joules. This constant is widely used in engineering and chemistry tables for heat-capacity conversions.
Yes. The tool applies standard constants for BTU, pound, and Fahrenheit temperature step. Results are suitable for calculations, provided your source BTU definition matches common IT usage.
Higher values mean a material absorbs more energy for the same temperature change. Water’s high value helps stabilize temperature, while many metals heat and cool faster due to lower values.
Match your source accuracy. If your input has two or three significant decimals, choose 3–4 output decimals. Too many decimals can imply unrealistic certainty.
No. Phase change energy uses latent heat, not specific heat capacity. Use this calculator for sensible heating or cooling where temperature changes without changing phase.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.