This paper investigates the flame size ( i.e. envelop surface area and flame volume) and the volumetric heat release rate of turbulent jet diffusion flames, in both normal and in a sub-atmospheric pressure. Experiments on turbulent jet diffusion flames, produced with nozzles of 4, 5, 6 and 8 mm in diameter and using propane as fuel, have been carried out at two different altitudes: Hefei, 50 m and 100 kPa and Lhasa, 3650 m and 64 kPa. Results have shown both the flame envelope surface area, A(f), and the flame volume, V-f, to be much larger in the sub-atmospheric pressure than in the normal pressure (i.e. A(f) similar to p (4/5); V-f similar to p (7/5)). The flame envelope surface area has been found to scale with the heat release rate, Q, by the power of 4/5, A(f) similar to Q(4/5). The flame volume, Vf, has also been found to scale with the heat release rate by the power of 9/10, V-f similar to Q(9/10). The volumetric heat release rate, Q ''', has been found to be a function of both the heat release rate, Q, and the ambient pressure, p (Q ''' similar to Q(0.1); Q ''' similar to p(7/5)). General non-dimensional correlations for all the present data, obtained for the different nozzle diameters and the two ambient pressures, have also been proposed for the flame envelope surface area and the flame volume, respectively. (C) 2015 Elsevier Ltd. All rights reserved.