The Effect of Wedge Angle on the Evolution of a Stagnation Layer in a Colliding Plasma Experiment

“…Accretion and compression of the material within the SL leads to a local increase in density and temperature. The degree of stagnation can be described by a collisionality parameter ξ = d/λ ii , where d is the distance between the two plasmas and λ ii is the ion-other ion mean free path, given by, [65,66]…”

“…Accretion and compression of the material within the SL leads to a local increase in density and temperature. The degree of stagnation can be described by a collisionality parameter ξ = d / λ ii , where d is the distance between the two plasmas and λ ii is the ion-other ion mean free path, given by, [ 65 , 66 ] where ε 0 is the permittivity of free space, m i is the ion mass, is the relative ion flow velocity (prior to impact), q is the elementary charge, Z is the average ionisation state, n i is the plasma density at the collision plane and ln (Λ 1–2 ) is the Coulomb Logarithm, a slowly varying function, with a value O (10–20) [ 67 ]. The parameter ξ is very sensitive to the relative plasma velocity term 4 while only linearly dependent on separation d. If used in ambient air, this description is more complex than in vacuum due to the presence of shock waves and rapid plasma deceleration due to collisions with the air.…”

Backward Flux Re-Deposition Patterns during Multi-Spot Laser Ablation of Stainless Steel with Picosecond and Femtosecond Pulses in Air

“…Accretion and compression of the material within the SL leads to a local increase in density and temperature. The degree of stagnation can be described by a collisionality parameter ξ = d/λ ii , where d is the distance between the two plasmas and λ ii is the ion-other ion mean free path, given by, [65,66]…”

“…Accretion and compression of the material within the SL leads to a local increase in density and temperature. The degree of stagnation can be described by a collisionality parameter ξ = d / λ ii , where d is the distance between the two plasmas and λ ii is the ion-other ion mean free path, given by, [ 65 , 66 ] where ε 0 is the permittivity of free space, m i is the ion mass, is the relative ion flow velocity (prior to impact), q is the elementary charge, Z is the average ionisation state, n i is the plasma density at the collision plane and ln (Λ 1–2 ) is the Coulomb Logarithm, a slowly varying function, with a value O (10–20) [ 67 ]. The parameter ξ is very sensitive to the relative plasma velocity term 4 while only linearly dependent on separation d. If used in ambient air, this description is more complex than in vacuum due to the presence of shock waves and rapid plasma deceleration due to collisions with the air.…”

Backward Flux Re-Deposition Patterns during Multi-Spot Laser Ablation of Stainless Steel with Picosecond and Femtosecond Pulses in Air

“…of different target geometries ( lateral collision, orthogonal collision etc.) and also different laser pulse durations (femtosecond to nanosecond) [11][12][13][14][15]. Stagnation layer and its properties attract the curiosity of many researchers and it still requires further investigation to understand the complex physical processes underlying in it.…”

Study of stagnation layer of laterally colliding laser produced aluminium plasmas

Tuning of stagnation layer properties in colliding laser-produced plasmas