Extended Data Table 1 |. Range of required interfacial tension reduction needed for spontaneous shape transitions of NLCO drops with “physical” saddle-splay modulus.
This table summarizes parameter values that permit shape transitions (with reasonable saddle-splay elastic constants) based on our model free energy calculations. The calculations fix the interfacial tension (γmeasured;mm-drop) at 30 °C measured by the pendant drop technique. A fairly wide range of estimated elastic constants (K) and anchoring energy coefficients (Wa) are employed in the calculations too. Per criteria for a spontaneous shape transition, we demand that the required saddle-splay elastic constant (K24) be of order ∼6 times the splay modulus (or less). The calculations show that a smaller “true” interfacial tension, γtrue;micro-emulsion (expressed as reduction factor of γmeasured;mm-drop in the Table), will significantly relax the saddle-splay requirement. This reduction of γ can be realized through oligomer polydispersity and resultant oligomer spatial segregation in the elastic stress field. Note, a reasonable range for K is 5×10−11 N to 10−10 N; a value of K =10−11 N is probably too small, since it is the same order of magnitude as small molecule LCs such as 5CB.
| γmeasured; mm-drop (mN/m) | K (N) | Wa (J/m2) | Required K24 for shape transition | Reduction factor of γmeasured; mm-drop gives γtrue; micro-emulsion | Required K24 for shape transition with reduced γ |
|---|---|---|---|---|---|
| 2.36 | 5 × 10−11 | 5 × 10−5 ∼5 × 10−4 | 60.2 × K11 | 20x | 5.7 × K11 |
| 2.36 | 10−10 | 5 × 10−5 ∼5 × 10−4 | 31.6 × K11 | 10x | 5.7 × K11 |
| 2.36 | 5 × 10−10 | 5 × 10−4 | 8.6 × K11 | 2x | 5.7 × K11 |