Study finds a way to predict when cracks would develop in paint, clay, milk and blood

Study finds a way to predict when cracks would develop in paint, clay, milk and blood

Sub : Sci

Sec : Miscellaneous

Why in NEWS

• A new study have shown clay’s drying process reveals a fascinating shift in elasticity, from liquid to pliable solid to brittle material.

Key highlights and context

• Crack Prevention Breakthrough: Researchers at the Raman Research Institute (RRI) in Bengaluru have discovered a method to delay cracking in paint coatings.
• Wider Applications: This technique has potential uses beyond paint, including disease diagnosis and food spoilage detection.
• Ubiquity of Cracks: Cracks are common in various settings, from old vases and buildings to lava flows, dry ground, and reptile skin.
• Crack Complexity: While seemingly simple, crack formation is a complex phenomenon.
• Crack Intersection Angles: Previous research showed cracks typically intersect at 90 degrees, except in drying paint where the angle is 120 degrees.

Elasticity

• Elasticity, ability of a deformed material body to return to its original shape and size when the forces causing the deformation are removed.

Elasticity and Cracking

• The changing elasticity of clay as it dries, transitioning from liquid to soft solid to brittle sheet.
• They discovered a relationship between clay’s elasticity and the speed at which cracks appear.
• They developed a method to predict crack formation based on initial sample thickness and elasticity.
• By manipulating elasticity, they could delay the onset of cracks. They altered elasticity by adding different substances to the clay.
• Common salt accelerated crack formation, while tetrasodium pyrophosphate (TSPP) significantly delayed it. TSPP, a food additive found in various products (e.g., chicken nuggets, marshmallows, toothpaste), proved highly effective in delaying cracks in clay.

Application of delayed cracking

• The research can be immediately applied to create crack-resistant paint coatings by adding clay with specific elasticity during manufacturing.
• The findings have potential applications beyond paint, wherever cracks occur. Milk and blood, like clay, are colloids (mixtures of particles in a liquid) and exhibit similar drying behavior.
• Crack patterns can reveal structural changes in materials like milk (protein networks) and blood (clot formation).
• The method could be used to identify adulterants in milk by analysing differences in drying patterns between pure and adulterated samples.
• Changes in red blood cell characteristics in diseases like anemia could alter blood drying patterns, offering a potential diagnostic tool.