The melting curve of helium-3

New data for the melting curve of He 4 for temperatures between 4 and 25 K agree with earlier results by Mills and Grilly and by Crawford and Daniels, but disagree with the relationship given by Glassford and Smith [CRYOGENICS 6 (1966) 193] who carried out equation of state studies on fluid and soli

Uniy~r~iity of some melting indicators, in the cOntext of two successful models of the solid and the liquid, gives rise: to simple semi-empirical melting equations that describe uddirivlty of melting curves. Computer inverse power melting results are used to reproduce the melting characteristics of

## Abstract Exact algorithms for the calculation of melting curves of heterogeneous DNA with __N__ base pairs apparently require computer time proportional to __N__^2^. However, it is shown that a decomposition of the loop entropy factor into a sum of __I__ exponential functions (1) gives an extrem

V [4] (Hg salt: m.p. 128 to 129 "C.) with n-butyllithium [3]. Thus, it is easier to remove a bromine cation from compound 11 than a proton [5]: GHsLi I1 ---+ (%H&P=CHz + (CnHs)P=CHBr The desired bromomethylenation can be realized with lithium piperidide 161 which predominantly removes protons from

## Abstract Theoretical calculations predict that the differential melting curves for random polynucleotide sequences having lengths up to several tens of thousands of base pairs have a clear‐cut fine structure. This structure appears in the form of multiple narrow peaks 0.3–0.4°C wide on the bell