Problem 6.187 — Radiocarbon: Production Rate

Problem Statement

$^{14}$C is produced in the atmosphere by neutrons from cosmic rays: $n + ^{14}N \to ^{14}C + p$. If the production rate equals the decay rate, find the steady-state $^{14}$C/$^{12}$C ratio. ($T_{1/2}(^{14}C) = 5730$ yr; atmospheric $n$ flux $= 2$ n/cm²·s; $\sigma = 1.8$ b)

Given Information

• All quantities, constants, and constraints stated in the problem above
• Physical constants used as needed (see Concepts section)

Physical Concepts & Formulas

This problem draws on fundamental physical principles. The key is to identify which conservation law or field equation governs the system, then apply it systematically. Dimensional analysis can always be used to verify that the final answer has the correct units. Working from first principles — rather than memorising formulas — builds deeper understanding and allows tackling novel problems.

• Identify the relevant physical law (Newton’s laws, conservation of energy/momentum, Maxwell’s equations, etc.)
• State the mathematical form of that law as it applies here
• Check dimensions at every step: both sides of an equation must have the same units

Step-by-Step Solution

Problem Statement

$^{14}$C is produced in the atmosphere by neutrons from cosmic rays: $n + ^{14}N \to ^{14}C + p$. If the production rate equals the decay rate, find the steady-state $^{14}$C/$^{12}$C ratio. ($T_{1/2}(^{14}C) = 5730$ yr; atmospheric $n$ flux $= 2$ n/cm²·s; $\sigma = 1.8$ b)

Given Information

• All quantities, constants, and constraints stated in the problem above
• Physical constants used as needed (see Concepts section)

Physical Concepts & Formulas

This problem draws on fundamental physical principles. The key is to identify which conservation law or field equation governs the system, then apply it systematically. Dimensional analysis can always be used to verify that the final answer has the correct units. Working from first principles — rather than memorising formulas — builds deeper understanding and allows tackling novel problems.

• Identify the relevant physical law (Newton’s laws, conservation of energy/momentum, Maxwell’s equations, etc.)
• State the mathematical form of that law as it applies here
• Check dimensions at every step: both sides of an equation must have the same units

Step-by-Step Solution

$^{14}$C is produced in the atmosphere by neutrons from cosmic rays: $n + ^{14}N \to ^{14}C + p$. If the production rate equals the decay rate, find the steady-state $^{14}$C/$^{12}$C ratio. ($T_{1/2}(^{14}C) = 5730$ yr; atmospheric $n$ flux $= 2$ n/cm²·s; $\sigma = 1.8$ b)

Solution

This problem illustrates how the atmosphere maintains a steady-state $^{14}$C concentration.

Production rate per cm²: $R = \Phi_{N}\sigma n_{flux}$

The steady-state $^{14}$C/$^{12}$C ratio in the atmosphere is $\approx 1.3\times10^{-12}$ (measured value).

This ratio is maintained by the balance between:

• Production: cosmic ray neutrons + $^{14}$N $\to$ $^{14}$C
• Decay: $^{14}$C $\to$ $^{14}$N + $e^-$ + $\bar{\nu}$, $T_{1/2} = 5730$ yr

Living organisms maintain the atmospheric ratio by metabolic exchange. After death, $^{14}$C decays without replenishment — the ratio decreases exponentially, enabling radiocarbon dating.

Worked Calculation

Substituting all given numerical values with their units into the derived formula:

$$\text{Numerical result} = \text{given expression substituted with values}$$

Answer

$$\boxed{^{14}}$$

Physical Interpretation

The answer should be checked for dimensional consistency and physical reasonableness: is the magnitude in the expected range for this type of problem? Does the answer change in the correct direction when parameters are varied (e.g., increasing mass should increase momentum, increasing distance should decrease field strength)? These sanity checks are as important as the calculation itself.

Worked Calculation

Substituting all given numerical values with their units into the derived formula:

$$\text{Numerical result} = \text{given expression substituted with values}$$

Answer

$$\boxed{\boxed{^{14}}}$$

Physical Interpretation

The answer should be checked for dimensional consistency and physical reasonableness: is the magnitude in the expected range for this type of problem? Does the answer change in the correct direction when parameters are varied (e.g., increasing mass should increase momentum, increasing distance should decrease field strength)? These sanity checks are as important as the calculation itself.