test-typst/section/perfect/non-polar/default.typ

@@ -50,11 +50,10 @@ Further details are provided in the appendix.
 
 The Raman tensors and frequencies of the negligible-polar phonons were calculated using first-principles methods,
   and the results are compared with both experimental data and theoretical predictions (@table-nopol).
-The calculated phonon frequencies show good agreement with experimental data,
-  with a slight underestimation of 2-5%,
-  which may be attributed to the underestimation of forces by PBE functional (cite).
+The calculated phonon frequencies show good agreement with experimental data with a slight underestimation of 2-5%,
+  where the error may be attributed to the underestimation of interatomic forces by the PBE functional (cite).
 The calculated Raman tensors are also consistent with experimental and theoretical results.
-Among negligible-polar modes, the E#sub[2] mode observed experimentally at 776 cm#super[-1] (mode 8)
+Among negligible-polar modes, the E#sub[2] mode at 776 cm#super[-1] in experiment (mode 8)
     exhibits the highest Raman intensity,
   followed by four modes with lower intensities that are also experimentally visible,
   including the E#sub[2] modes at 195.5 cm#super[-1] (mode 1) and 203.3 cm#super[-1] (mode 2),
@@ -63,13 +62,14 @@ The E#sub[1] mode calculated at 746.91 cm#super[-1] (mode 7)
     and the E#sub[2] mode calculated at 756.25 cm#super[-1] (mode 9)
   are predicted to have much weaker Raman intensities and are located close to the most intense mode (mode 8),
   making them indistinguishable in experimental spectra.
-This explains their absence in experimental observations.
 Additionally, the A#sub[1] mode calculated at 812.87 cm#super[-1] (mode 10)
-  exhibits very weak Raman intensity in the scattering in basal plane (xx and yy, only 0.01)
-  but an observable intensity in the zz configuration (1.78).
-As most Raman experiments are back-scattering along the z-direction with photon energy much less than the band gap,
-  this mode is generally not observed in these experiments (cite),
-  but it may become detectable when the incident light does not propagate along the z-direction (as in our experiment)
+  exhibits very weak Raman intensity in the configuration polarized in the basal-plane (xx and yy, only 0.01)
+  but an observable intensity in the configuration polarized along z-axis (1.78).
+Since most Raman experiments are performed in a back-scattering configuration with light incident along the z-direction
+    (polarized in-plane)
+  with photon energies much lower than the band gap,
+  this mode is generally not observed (cite).
+However, it should become detectable when the incident light have z-direction polarization part (as in our experiment)
   or when the incident light wavelength is near resonance conditions (cite).
 
 Besides, there are other peeks in the experiment.