Specific Heat Calculator (2024)

Last updated:Jul 17, 2024

Table of contents

How to calculate specific heatSpecific heat capacity formulaTypical values of specific heatFAQs

This specific heat calculator is a tool that determines the heat capacity of a heated or a cooled sample. Specific heat is the amount of thermal energy you need to supply to a sample weighing 1 kg to increase its temperature by 1 K. Read on to learn how to apply the heat capacity formula correctly to obtain a valid result.

💡 This calculator works in various ways, so you can also use it to, for example, calculate the heat needed to cause a temperature change (if you know the specific heat). To find specific heat from a complex experiment, calorimetry calculator might make the calculations much faster.

Prefer watching over reading? Learn all you need in 90 seconds with this video we made for you:

How to calculate specific heat

Determine whether you want to warm up the sample (give it some thermal energy) or cool it down (take some thermal energy away).
Insert the amount of energy supplied as a positive value. If you want to cool down the sample, insert the subtracted energy as a negative value. For example, say that we want to reduce the sample's thermal energy by 63,000 J. Then $Q = -63,\!000 \ \text{J}$ Q=−63,000J.
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Decide the temperature difference between the initial and final state of the sample and type it into the heat capacity calculator. If the sample is cooled down, the difference will be negative, and if warmed up - positive. Let's say we want to cool the sample down by 3 degrees. Then $\Delta T = -3 \ \text{K}$ ΔT=−3K. You can also select the Show initial and final temperatures checkbox to type the initial and final values of temperature manually.
Determine the mass of the sample. We will assume $m = 5 \ \text{kg}$ m=5kg.
Calculate specific heat as $c = \frac{Q}{m \Delta T}$ c=mΔTQ. In our example, it will be equal to:
$c = \mathrm{\frac{-63,000 \ J}{5 \ kg \cdot \ -3 \ K}} = \mathrm{4,\!200 \ \frac{J}{kg \cdot K}}$ c=5kg⋅−3K−63,000J=4,200kg⋅KJ
This is the typical heat capacity of water.

Specific heat capacity formula

The formula for specific heat looks like this:

$c = \frac{Q}{m \Delta T}$ c=mΔTQ

$Q$ Q is the amount of supplied or subtracted heat (in joules), $m$ m is the mass of the sample, and $\Delta T$ ΔT is the difference between the initial and final temperatures. Heat capacity is measured in J/(kg·K).

Typical values of specific heat

You don't need to use the heat capacity calculator for most common substances. The values of specific heat for some of the most popular ones are listed below.

Ice: $\mathrm{2,\!100 \ {J}/{kg\! \cdot\! K}}$ 2,100J/kg⋅K
Water: $\mathrm{4,\!200 \ {J}/{kg\! \cdot\! K}}$ 4,200J/kg⋅K
Water vapor: $\mathrm{2,\!000 \ {J}/{kg\! \cdot\! K}}$ 2,000J/kg⋅K
Basalt: $\mathrm{840 \ {J}/{kg\! \cdot\! K}}$ 840J/kg⋅K
Granite: $\mathrm{790 \ {J}/{kg\! \cdot\! K}}$ 790J/kg⋅K
Aluminum: $\mathrm{890 \ {J}/{kg\! \cdot\! K}}$ 890J/kg⋅K
Iron: $\mathrm{450 \ {J}/{kg\! \cdot\! K}}$ 450J/kg⋅K
Copper: $\mathrm{380 \ {J}/{kg\! \cdot\! K}}$ 380J/kg⋅K
Lead: $\mathrm{130 \ {J}/{kg\! \cdot\! K}}$ 130J/kg⋅K

Having this information, you can also calculate how much energy you need to supply to a sample to increase or decrease its temperature. For instance, you can check how much heat you need to bring a pot of water to a boil to cook some pasta. Or, you can use the water heating calculator for convenience, where all this information was already taken into account for you.

Wondering what the result actually means? Try our potential energy calculator to check how high you would raise the sample with this amount of energy. Or check how fast the sample could move with this kinetic energy calculator.

FAQs

How to calculate specific heat capacity?

Find the initial and final temperature as well as the mass of the sample and energy supplied.
Subtract the final and initial temperature to get the change in temperature (ΔT).
Multiply the change in temperature with the mass of the sample.
Divide the heat supplied/energy with the product.
The formula is C = Q / (ΔT × m).

What is specific heat capacity at constant volume?

The specific heat capacity is the heat or energy required to change one unit mass of a substance of a constant volume by 1 °C. The formula is Cv = Q / (ΔT × m).

What is the formula for specific heat?

The formula for specific heat capacity, C, of a substance with mass m, is C = Q /(m × ΔT). Where Q is the energy added and ΔT is the change in temperature. The specific heat capacity during different processes, such as constant volume, Cv and constant pressure, Cp, are related to each other by the specific heat ratio, ɣ= Cp/Cv, or the gas constant R = Cp - Cv.

What are the units for specific heat capacity?

Specific heat capacity is measured in J/kg·K or J/kg·°C, as it is the heat or energy required during a constant volume process to change the temperature of a substance of unit mass by 1 °C or 1 K.

What is the specific heat capacity value of water?

The specific heat of water at 25 °C is 4,181.3 J/kg·K, the amount of heat required to raise the temperature of 1 kg of water by 1 Kelvin.

What are the imperial units for specific heat?

Specific heat is measured in BTU / lb °F in imperial units and in J/kg·K in SI units.

What is the specific heat capacity value of copper?

The specific heat of copper is 385 J/kg·K. You can use this value to estimate the energy required to heat a 100 g of copper by 5 °C, i.e., Q = m × Cp × ΔT = 0.1 × 385 × 5 = 192.5 J.

What is the specific heat capacity value of aluminum?

The specific heat of aluminum is 897 J/kg K. This value is almost 2.3 times of the specific heat of copper. You can use this value to estimate the energy required to heat a 500 g of aluminum by 5 °C, i.e., Q = m × Cp × ΔT = 0.5 × 897 × 5 = 2242.5 J.

FAQs

How to calculate for specific heat? ›

Specific heat can be calculated without directly using joules by using the formula: c = Q / (m * ΔT) where: c = specific heat Q = heat energy transferred (which can be in units other than joules, such as calories) m = mass of the substance ΔT = change in temperature Remember to use consistent units in the formula.

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How do you answer specific heat capacity? ›

Find the energy and temperature change. Make a note of the final temperature change (which will be around 10 degrees) and the final energy value on the joulemeter. Rearrange the equation. Our equation for specific heat capacity is ∆E=mc∆T.

How to calculate the specific heat capacity of a solution? ›

Specific heat, denoted , is calculated with the following equation: C p = Q m Δ T , where is the mass of the substance, is the amount of heat energy added to the substance, and is the change in temperature of the substance.

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How much heat is needed to raise 27g of water from 10 to 90? ›

To raise 27.0 g of water from 10.0 °C to 90.0 °C, approximately 8978.4 J of heat is needed.

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What equation is commonly used to calculate specific heat? ›

The formula is: C_p = Q/mΔT. You can manipulate this formula if you want to find the change in the amount of heat instead of the specific heat. Here's what it would look like: ΔQ = mC_pΔT.

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How to calculate specific heat without Q? ›

What is the formula for finding specific heat with unknown Q? The formula for finding specific heat with unknown Q is Q = mcΔT, where Q is the heat energy, m is the mass of the substance, c is the specific heat, and ΔT is the change in temperature.

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What is specific heat answers? ›

specific heat, the quantity of heat required to raise the temperature of one gram of a substance by one Celsius degree. The units of specific heat are usually calories or joules per gram per Celsius degree. For example, the specific heat of water is 1 calorie (or 4.186 joules) per gram per Celsius degree.

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How to calculate specific capacity? ›

Specific capacity is the ratio of pumping rate (Q, L³/t) to water-level decline (drawdown = s, L; SC = Q/s).

Why do we calculate specific heat capacity? ›

It helps us understand how different materials respond to heat and why some materials heat up or cool down faster than others. For instance, metals typically have low specific heat capacities, meaning they heat up and cool down quickly, which is why they're often used in cooking utensils.

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How to do heat calculations? ›

The amount of heat gained or lost by a sample (q) can be calculated using the equation q = mcΔT, where m is the mass of the sample, c is the specific heat, and ΔT is the temperature change. Created by Jay.

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What is the formula for the specific heat of a solution? ›

ΔH = m × ΔT × S

ΔH is the heat of solution, m is the mass of solvent, ΔT is the change in temperature, S is the specific heat of solvent.

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How much heat is required to heat 20g of water? ›

So,for 20g we will require 1600 calories of latent heat.

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How much heat is needed to raise the temperature of 100g of water by 50c? ›

Hence the heat required is $10450J$ . Converting it to kJ, the heat required to raise the temperature of $100.0$ grams of water from ${25.0^0}C$ to ${50.0^0}C$ is $10.45kJ$ . Note: Water requires more heat to raise its temperature compared to other common substances.

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How much heat does it take to raise water 1 degree? ›

Precisely, water has to absorb 4,184 Joules of heat (1 kilocalorie) for the temperature of one kilogram of water to increase 1°C. For comparison sake, it only takes 385 Joules of heat to raise 1 kilogram of copper 1°C.

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What is the formula for the specific heat of a solid? ›

So, to raise the temperature of µ moles of solid through ∆T, you would need an amount of heat equal to ∆Q=µ C ∆T. The molar specific heat capacity of a substance is nothing but the amount of heat you need to provide to raise the temperature of one gram molecule of the substance through one degree centigrade.

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What is specific heat and how is it measured? ›

Specific heat capacity refers to a material's heat capacity divided by mass, which governs the amount of energy needed to raise the temperature of one gram by one degree Celsius (or one Kelvin). This is a useful physical quantity for a range of objectives, e.g. to optimize technical processes or assess thermal risk.

What is the formula for the specific heat capacity of a mixture? ›

However, if you know the specific heat capacities (c) and masses (m) of the individual components, you can calculate the specific heat capacity of the mixture (C_mixture) using the formula: C_mixture = (m₁c₁ + m₂c₂ + ... + m_nc_n) / (m₁ + m₂ + ...

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