Add to ORKGBuoyant plumes, evolving free of boundary constraints, may develop well-defined mushroom shaped heads. In normal plumes, overturning flow in the head entrains less buoyant fluid from the surroundings as the head rises, robbing the plume of its driving force. We consider here a new type of plume in which the source of buoyancy is an autocatalytic chemical reaction. The reaction occurs at a sharp front which separates reactants from less dense products. In this type of plume, entrainment assists the reaction, producing new buoyancy which fuels an accelerating plume head. When the head has grown to a critical size, it detaches from the upwelling conduit, forming an accelerating, buoyant vortex ring. This vortex is analogous to a rising smoke r...
Many inorganic precipitation reactions self-organize macroscopic tubes known as chemical gardens. We...
A qualitative mechanism for autowave pattern formation at the reaction front, observed in certain ch...
We use a detailed chemical kinetic mechanism to explore the effects of C/O ratio, temperature and pr...
Plumes are formed when a continuous buoyant forcing is supplied at a localized source. Buoyancy can ...
Turbulent plumes, which are seen in a wide number of industrial and natural flows, have been extensi...
Vortex ring formation in a starting axisymmetric buoyant plume is considered. A model describing the...
We investigate the behaviour of a reactive plume in the two limiting cases of slow and instantaneous...
We explore the dynamics of starting plumes by analysis of a series of new small-scale laboratory exp...
Spherical flame balls are studied using a model for the chemical kinetics which involves a non-exoth...
The autoignition of an axisymmetric nitrogen-diluted hydrogen plume in a turbulent coflowing stream ...
Effects of the buoyancy induced by chemical heat release in a diffusion flame were investigated usin...
A diffusion flame, supported by a one-step chemical reaction, is initiated along the horizontal axis...
Dynamics of buoyant reacting flows from rectangular, square and round sources were investigated usin...
The chemical reactions occurring in the exhaust systems of the deposition reactors can potentially l...
The bursting of bubbles at an air-liquid interface is an important physical process in many environm...
Many inorganic precipitation reactions self-organize macroscopic tubes known as chemical gardens. We...
A qualitative mechanism for autowave pattern formation at the reaction front, observed in certain ch...
We use a detailed chemical kinetic mechanism to explore the effects of C/O ratio, temperature and pr...
Plumes are formed when a continuous buoyant forcing is supplied at a localized source. Buoyancy can ...
Turbulent plumes, which are seen in a wide number of industrial and natural flows, have been extensi...
Vortex ring formation in a starting axisymmetric buoyant plume is considered. A model describing the...
We investigate the behaviour of a reactive plume in the two limiting cases of slow and instantaneous...
We explore the dynamics of starting plumes by analysis of a series of new small-scale laboratory exp...
Spherical flame balls are studied using a model for the chemical kinetics which involves a non-exoth...
The autoignition of an axisymmetric nitrogen-diluted hydrogen plume in a turbulent coflowing stream ...
Effects of the buoyancy induced by chemical heat release in a diffusion flame were investigated usin...
A diffusion flame, supported by a one-step chemical reaction, is initiated along the horizontal axis...
Dynamics of buoyant reacting flows from rectangular, square and round sources were investigated usin...
The chemical reactions occurring in the exhaust systems of the deposition reactors can potentially l...
The bursting of bubbles at an air-liquid interface is an important physical process in many environm...
Many inorganic precipitation reactions self-organize macroscopic tubes known as chemical gardens. We...
A qualitative mechanism for autowave pattern formation at the reaction front, observed in certain ch...
We use a detailed chemical kinetic mechanism to explore the effects of C/O ratio, temperature and pr...