Influence of the impact energy on the pattern of blood drip stains

Smith, Fiona; Nicloux, Céline; Brutin, David

doi:10.1103/physrevfluids.3.013601

Cited by 20 publications

(12 citation statements)

References 23 publications

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“…It describes how a bullet atomizes blood; how the impact of a fist on a moving face squeezes and splashes blood; how airborne droplets move along trajectories curved by gravity and slowed by drag; and how drops spread, wick, and dry onto materials as complex as fabrics. Only recently, peer-reviewed fluid dynamic studies have started to uncover the complex physics underlying BPA [54][55][56][57][58][59][60][61][62][63][64][65][66][67][68][69][70][71][72]. The governing equations of fluid dynamics are called the Navier-Stokes equations; they are the expression of Newton's second law for fluids.…”

Section: Proposed Direction 1: Better Understand the Physics Associated With Bpamentioning

confidence: 99%

Using the likelihood ratio in bloodstain pattern analysis

Attinger

Brabanter

Champod

2021

Journal of Forensic Sciences

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Section: Proposed Direction 1: Better Understand the Physics Associated With Bpamentioning

confidence: 99%

Using the likelihood ratio in bloodstain pattern analysis

Attinger

Brabanter

Champod

2021

Journal of Forensic Sciences

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“…Brutin et al have demonstrated that red blood cells will affect the dried bloodstain pattern [39]. Besides, Smith et al found a correlation between dried bloodstain pattern and droplet impact energy [40]. These studies indicate that particles that simulate red blood cells need to be added to the BS used for bloodstain pattern analysis.…”

Section: Introductionmentioning

confidence: 99%

Droplet impact of blood and blood simulants on a solid surface: Effect of the deformability of red blood cells and the elasticity of plasma

Yokoyama,

Tanaka,

Tagawa

2022

Preprint

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The impact of blood droplets onto a solid wall is of great importance for bloodstain pattern analysis in forensic science. Previous studies suggest that the behaviour of impacting blood is similar to that of a Newtonian fluid, which has a shear viscosity equivalent to that of blood at high shear rates. To understand this important fact, we conducted comparative experiments of droplet impact on a glass surface using whole blood and three solutions with a shear viscosity similar to that of blood. Specifically, we used dog's whole blood (deformable red blood cells dispersed in plasma, WB), plasma with non-deformable resin particles (PwP), glycerol and water with resin particles (GWwP), and a commercial blood simulant (hard particles dispersed in a water-based Newtonian solution, BS). Ranges of Reynolds and Weber numbers in our experiments were 550 < Re < 1700 and 120 < W e < 860, respectively. Side and bottom views of droplet impact were simultaneously recorded by two high-speed cameras. The spreading radius of the impacting WB droplet in our experiments agreed well with that of Newtonian fluids with viscosity similar to that of WB at high shear rates. Splashing droplets of WB and Newtonian fluids form finger structures (finger-splashing). Although PwP has a viscosity similar to that of WB at high shear rates, an impacting PwP droplet exhibited typical characteristics of impacting suspension droplets, that is, a reduced spreading radius and splashing with ejection of particles. Such significant differences between impacting droplets of PwP and WB indicates that the high deformability of red blood cells in WB plays a crucial role in the Newtonian-like behaviour of blood droplets on impact. The finger-splashing of PwP and GWwP exhibited no significant difference, indicating that the effect of plasma elasticity on finger-splashing is negligible. Importantly, the impacting BS droplet behaved quite differently from WB in both spreading and splashing. Our results imply that the use of deformable particles rather than hard particles in a BS is essential for mimicking blood droplet impact.

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“…The DOD process was modeled and analyzed via the drying of droplets. , Until now, DOD studies were investigated concerning the geometric properties of the droplet (volume, diameter, etc. ), viscosity, surface tension, density, and surface energy and roughness. − Also, the impacts of pH and surfactant on the drying pattern were analyzed by using the various droplet and substrate characteristics. − Another example is the blood/surrogate blood droplet evaporation in biological applications with the assumption of the blood droplets as the suspension-laden ones that were modeled with respect to the humidity effect, crack formation, , surface roughness and wettability, relation between the number of cracks and droplet diameter, evaporation rate, and impact energy . Besides the aforementioned cases, we have been working with droplet evaporation with nanoparticle-laden droplets by investigating the flow regime and deposition patterns of binary mixtures, , disk-to-dual ring deposition, , and impacts of (i) surfactants on the droplet deposition and (ii) multisized nanoparticles .…”

Section: Introductionmentioning

confidence: 99%

Transient Prediction of Nanoparticle-Laden Droplet Drying Patterns through Dynamic Mode Decomposition

et al. 2021

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Nanoparticle-laden sessile droplet drying has a wide impact on applications. However, the complexity affected by the droplet evaporation dynamics and particle self-assembly behavior leads to challenges in the accurate prediction of the drying patterns. We initiate a data-driven machine learning algorithm by using a single data collection point via a top-view camera to predict the transient drying patterns of aluminum oxide (Al2O3) nanoparticle-laden sessile droplets with three cases according to particle sizes of 5 and 40 nm and Al2O3 concentrations of 0.1 and 0.2 wt %. Dynamic mode decomposition is used as the data-driven learning model to recognize each nanoparticle-laden droplet as an individual system and then apply the transfer learning procedure. Along 270 s of droplet drying experiments, the training period of the first 100 s is selected, and then the rest of the 170 s is predicted with less than a 10% error between the predicted and the actual droplet images. The developed data-driven approach has also achieved the acceptable prediction for the droplet diameter with less than 0.13% error and a coffee-ring thickness over a range of 2.0 to 6.7 μm. Moreover, the proposed machine learning algorithm can recognize the volume of the droplet liquid and the transition of the drying regime from one to another according to the predicted contact line and the droplet height.

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Influence of the impact energy on the pattern of blood drip stains

Cited by 20 publications

References 23 publications

Using the likelihood ratio in bloodstain pattern analysis

Using the likelihood ratio in bloodstain pattern analysis

Droplet impact of blood and blood simulants on a solid surface: Effect of the deformability of red blood cells and the elasticity of plasma

Transient Prediction of Nanoparticle-Laden Droplet Drying Patterns through Dynamic Mode Decomposition

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