Half-Life Calculator

Calculate radioactive decay, remaining quantity, and half-life for nuclear chemistry applications

Initial Amount (N₀): atoms/g/moles

Elapsed Time (t):

Half-Life (t½):

Decay Results

Remaining Amount (N): 0

Decayed Amount: 0

Percentage Remaining: 0%

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Initial Amount (N₀):

Remaining Amount (N):

Elapsed Time (t):

Half-Life Results

Half-Life (t½): 0

Decay Constant (λ): 0

Initial Amount (N₀):

Remaining Amount (N):

Half-Life (t½):

Decay Time Results

Decay Time (t): 0

Number of Half-Lives: 0

Remaining Amount (N):

Elapsed Time (t):

Half-Life (t½):

Initial Quantity Results

Initial Amount (N₀): 0

Common Radioactive Isotopes

Radium-226 (1620 years)

Carbon-14 (5730 years)

Uranium-238 (4.5 billion years)

Iodine-131 (24.1 days)

Cesium-137 (30.17 years)

Polonium-210 (138.4 days)

Understanding Radioactive Decay and Half-Life

Radioactive decay is a fundamental process in nuclear physics where unstable atomic nuclei lose energy by emitting radiation. The half-life of a radioactive substance is the time required for half of the radioactive atoms in a sample to undergo decay.

Radioactive Decay Formula

N = N₀ × (1/2)^t/t½

N = Quantity remaining after time t

N₀ = Initial quantity

t = Elapsed time

t½ = Half-life

Key Concepts in Radioactive Decay

Exponential Nature of Decay

Radioactive decay follows an exponential pattern, meaning the rate of decay is proportional to the number of remaining radioactive atoms. This results in a characteristic curve where the quantity decreases rapidly at first, then more slowly over time.

Decay Constant

The decay constant (λ) represents the probability that a nucleus will decay per unit time. It’s related to half-life by the formula:

λ = ln(2) / t½

Types of Radioactive Decay

Alpha decay: Emission of alpha particles (helium nuclei)
Beta decay: Conversion of neutrons to protons or vice versa
Gamma decay: Emission of high-energy photons
Electron capture: Absorption of an orbital electron by the nucleus

Practical Example: Carbon-14 Dating

Carbon-14 dating uses the known half-life of Carbon-14 (5730 years) to determine the age of organic materials. By measuring the ratio of Carbon-14 to Carbon-12 in a sample, scientists can calculate how long ago the organism died.

For example, if a sample contains 25% of its original Carbon-14, it has undergone two half-lives (50% → 25%), making it approximately 11,460 years old.

Applications of Half-Life Calculations

Archaeology and Geology

Radioactive dating techniques using isotopes like Carbon-14, Potassium-40, and Uranium-238 allow scientists to determine the age of artifacts, fossils, and geological formations with remarkable accuracy.

Medical Applications

Radioactive isotopes are used in medical diagnostics and treatment. Understanding their half-lives is crucial for:

Determining appropriate dosages for radiation therapy
Planning imaging procedures using radioactive tracers
Ensuring patient safety by managing radiation exposure

Nuclear Energy and Safety

Half-life calculations are essential in nuclear power generation for:

Predicting fuel consumption rates
Managing radioactive waste storage and disposal
Assessing environmental impact and safety protocols

Environmental Science

Radioactive tracers help scientists study environmental processes, including:

Ocean current patterns
Groundwater movement
Atmospheric circulation
Pollution tracking

Factors Affecting Radioactive Decay

Nuclear Stability

The half-life of a radioactive isotope is determined by the stability of its nucleus. Elements with unstable proton-neutron ratios tend to have shorter half-lives as they seek more stable configurations.

Environmental Conditions

Unlike chemical reactions, radioactive decay rates are generally unaffected by:

Temperature changes
Pressure variations
Chemical bonding
Physical state (solid, liquid, gas)

Quantum Tunneling

Radioactive decay involves quantum mechanical phenomena where particles “tunnel” through energy barriers that would be insurmountable according to classical physics. This probabilistic nature is what gives decay its random character while maintaining predictable statistical behavior for large numbers of atoms.

Frequently Asked Questions

Can half-life be changed or controlled?

Under normal conditions, the half-life of a radioactive substance is constant and cannot be altered by external factors like temperature, pressure, or chemical environment. However, in extreme conditions such as inside stars or particle accelerators, nuclear reactions can change decay rates.

What happens after one half-life?

After one half-life, approximately 50% of the original radioactive atoms remain. After two half-lives, about 25% remain, after three half-lives 12.5%, and so on. Theoretically, a radioactive substance never completely decays to zero.

Why do different elements have different half-lives?

Half-life depends on the specific nuclear structure of each isotope. Factors include:

Proton-to-neutron ratio
Nuclear binding energy
Quantum mechanical properties
Type of decay process

How is half-life measured experimentally?

Scientists measure half-life by:

Monitoring radiation intensity over time
Counting decay events using Geiger counters or scintillation detectors
Using mass spectrometry to measure isotope ratios
Applying statistical analysis to decay data

Half-Life Calculator