[en] Turbulent axisymmetric lazy plumes produced by discharging saline fluid downwards into a less dense uniform environment from a round pipe are examined experimentally. The plume development is controlled by the source flow rate $Q_0$, momentum $M_0$ and buoyancy $F_0$. This study investigated plumes where the source flow rate, momentum and buoyancy are sinusoidal functions of time. The pulsing flow is generated by a programmable ISMATEC gear pump. The maximum frequency f of this pulsing plume is of $\mathcal{O}(U_0/D)$, where $D/U_0$ is the eddy turnover time scale at the source, D is the source diameter, and $U_0$ is the average velocity at the source. Experiments with pulsing plumes were carried out with a flow rate amplitude A of up to $80\mathrm{\%<!--\; \%\; -->}$ and with Strouhal number $St=fD/U_0$ ranging from 0.012 to 1.2. The bulk dilution and entrainment measurements were made using the experimental approach of Hunt and Kaye (J Fluid Mech 435:377–396, 2001). Average entrainment is obtained via the integral relationship for Q(z) and M(z) from the model established by Morton et al. (Proc R Soc Lond A 234(1196):1–23, 1956) for continuous sources. The influence of the amplitude and Strouhal number St on the entrainment coefficient $\mathrm{\alpha <!--\; ??\; -->}$ is examined, which was found to be very small over the entire range of source conditions considered. Graphic abstract:

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