Problem:The moderator temperature: Difference between revisions

The energy at a specific temperature is \( E = k_B T \) [meV] and the neutron velocity at a specific temperature is

\begin{equation*} v = \sqrt{\frac{2k_BT}{m_n}} \end{equation*}

with unit [m/s].

Use the constants \( m_n = 1.675 \times 10^{-27} \text{kg}\), \(1 \text{eV} = 1.602 \times 10^{-19} \text{J}\), \( k_B = 1.38 \times 10^{-23} \text{J/K} = 8.61 \times 10^{-5} \text{eV/K}\).

The de Broglie wavelength can be calculated from \(\lambda = h / (m_n v) \) [Å].

The calculated values can be found in the table of the solution of the next question.

Table 1: Specifics for neutrons moderated at 30 K and 300 K.

The values shown are shown in Table xx--CrossReference--tab:specs_moderated_neutrons--xx.

\begin{equation*} \frac{I(\lambda_1)}{I(\lambda_2)} = \left(\frac{\lambda_2}{\lambda_1}\right)^5 \exp\big( {-C(T)(\lambda_1^{-2} -\lambda_2^{-2} )} \big) \end{equation*} where \( C(T) = h^2 / (2 m_n k_B T) \), hence \(C(30\text{K}) = 3.17\times 10^{-19} \text{m}^2\) and \(C(300\text{K}) = 3.17\times 10^{-20}\text{m}^2\).

So for \(T=30 \text{K}\)

\begin{equation*} \frac{I(4\tt{Å})}{I(20\tt{Å})} = 5^5 \cdot \exp\big( -3.17\times 10^{-19}\cdot 6\times 10^{18} \big) = 466 \end{equation*}

since \((4 \times 10^{-10} \text{m})^{-2} - (20 \times 10^{-10} \text{m})^{-2} = 6 \times 10^{18} \text{m}^{-2}\).

For \(T=300 \text{K}\)

\begin{equation*} \frac{I(4\tt{Å})}{I(20\tt{Å})} = 5^5 \cdot \exp\big( {-3.17\times 10^{-20}\cdot 6\times 10^{18}} \big) = 2584 \end{equation*}

Figure 1: A sketch of a moderator spectrum and the intensity in a particular bandwidth at 4 Å and 20 Å respectively

According to the calculation above apparantly there is several orders of magnitude more intensity of the neutrons at 4 Å than at 20 Å. If we however take a look at a small window of energies around 4 Å and 20 Å, respectively and integrate over these the ratios are not so extreme: Consider the intensity constant within the small wavelength bands \(\lambda_1-\Delta \lambda_1; \lambda_1+\Delta \lambda_1\) and \(\lambda_2-\Delta \lambda_2; \lambda_2+\Delta \lambda_2\). The relative intensity between wavelength bands is

\begin{equation*} \frac{I(\lambda_1\pm\Delta\lambda_1)}{I(\lambda_2\pm\Delta\lambda_2)} = \frac{\displaystyle\int_{\lambda_1-\Delta \lambda_1}^{\lambda_1+\Delta \lambda_1} I(\lambda_1)d\lambda_1} {\displaystyle\int_{\lambda_2-\Delta \lambda_2}^{\lambda_2+\Delta \lambda_2} I(\lambda_2)d\lambda_2} \approx \frac{I_1\cdot 2\Delta \lambda_1}{I_2\cdot 2\Delta \lambda_2} \end{equation*}

The approximation is shown in Figure xx--CrossReference--fig:moderator_spectrum--xx. If \({\Delta \lambda}/{\lambda}=10\%\) and \(\lambda_1=4\) Å and \(\lambda_2=20\) Å then \(\Delta\lambda_1=0.4\) Å and \(\Delta\lambda_2=2\) Å so at 30 K where \(I_1 / I_2 = I(4Å) / I(20Å) = 466\)

\begin{equation*} \frac{I(4\pm0.4)}{I(20\pm2)} = 466\frac{0.8}{4} = 93.2 \end{equation*}

and at 300 K where \({I_1} / {I_2}={I(4Å)} / {I(20Å)} = 2584\)

\begin{equation*} \frac{I(4\pm0.4)}{I(20\pm2)} = 2584\frac{0.8}{4} = 517 \end{equation*}