Swenson et al. [8] determined that

Swenson et al. [8] determined that HTC
peaked when film temperature was within the pseudo-critical
temperature range. This peak in HTC decreased with the increase
in pressure and heat flux. Yoshida and Mori [9] asserted that the
considerable variations in thermal physical properties with temperature
change across the flow enhanced heat transfer near the
pseudo-critical point at a low heat flux. Enhancement was
weakened with increasing heat flux. To explain this phenomenon,
Ackerman [10] presented two-phase pseudo-boiling theory. He
indicated that heat transfer enhancement at supercritical pressures
was similar to two-phase boiling at subcritical pressures. Two
types of heat transfer deterioration were observed by Vikhrev.
The first type occurred in the entrance region of the tube because
of the flow structure [11]. The second type occurred at any section
of the tube when the bulk fluid temperature was below and the
wall temperature was above the pseudo-critical temperature
[12]. Ackerman [10] believed that pseudo-film boiling, which was
similar to film boiling, led to the deteriorated heat transfer. However,
Jackson [13] indicated that buoyancy and thermally induced
flow acceleration contributed to abnormal heat transfer. He then
proposed an approach for describing their combined effects. On
the basis of the experiments, Chen and Fang [14], Zhang et al.
[15], and Wang et al. [16] presented various correlations to predict
heat transfer at supercritical pressures. A comparison of the correlations
for supercritical heat transfer was also performed by Pioro
et al. [17]. Their results indicated that only several correlations
could be used for preliminary estimation, and no correlation could
describe deteriorated or improved heat transfer in tubes. To
account for the new IAPWS-97 International Water Properties
Standard, Kurganov et al. [18] proposed several methods for curing
‘‘old” correlations to enable complete restoration of their former
capabilities.