Black Titanium Dioxide
Laser Marking
Why Laser Marking Fails in Light Colored Plastics Despite Using Absorbers
How Black TiO Converts NIR Laser Energy Into Localized Heat
Why Carbon Black Causes Electrical Conductivity in Laser Marked Parts
How Particle Dispersion Affects Laser Marking Contrast and Edge Definition
Why Laser Marking Performance Varies Across Polymer Types
What Limits Laser Marking Depth in Black TiO Systems
When Black TiO Fails to Produce Visible Laser Contrast
Why Black TiO Cannot Replace Conductive Fillers in Esd Applications
How Processing Temperature and Shear Affect Laser Marking Performance
Functional Black Pigments
Why Black TiO Causes Electrical Leakage in Plastic Housings
How Black TiO Achieves Black Coloration without Conductivity
Why Pigment Dispersion Determines Color Depth and Stability
What Causes Gloss and Color Drift in Black Plastic Parts
Why Black TiO Performs Better Than Organic Blacks at High Temperature
How Particle Size Influences Optical Density in Black Pigments
When Carbon Black Is Still Preferable to Black TiO
What Processing Conditions Cause Pigment Migration or Blooming
How Long Term Heat and UV Exposure Affect Black TiO Pigments
IR / NIR Absorbing Coatings
How Black TiO Absorbs Near Infrared Radiation
Why Black TiO IR Coatings Fail Under Prolonged Heat
What Determines IR Absorption Efficiency in Black TiO Coatings
How Coating Thickness Influences IR Absorption Performance
Why Black TiO Outperforms Dyes in High Temperature IR Coatings
What Limits IR Shielding Efficiency in Black TiO Polymer Coatings
When IR Absorption Does Not Translate Into Effective Thermal Blocking
Why Black TiO Cannot Replace Conductive Oxides in Electrothermal Coatings
Material Selection
How to Choose between Black TiO Carbon Black and Ti O
What Processing Windows Ensure Stable Performance of Black TiO
Material overview:
Black Titanium Dioxide