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Related Concept Videos

Temperature Dependent Deformation01:12

Temperature Dependent Deformation

In a nonhomogeneous rod made up of steel and brass, restrained at both ends and subjected to a temperature change, several steps are involved in calculating the stress and compressive load. Due to the problem's static indeterminacy, one end support is disconnected, allowing the rod to experience the temperature change freely. Next, an unknown force is applied at the free end, triggering deformations in the rod's steel and brass portions. These deformations are then calculated and added together...
Physical Methods for Controlling Microbial Growth: Temperature01:23

Physical Methods for Controlling Microbial Growth: Temperature

Heat is a widely used method to control microbial growth by targeting and denaturing cellular proteins, thereby killing or inactivating microbes. This method's effectiveness is quantified using parameters such as the thermal death point (TDP), thermal death time (TDT), and decimal reduction time (D value). TDP represents the lowest temperature at which all microorganisms in a liquid suspension are eliminated within 10 minutes, whereas TDT is the time necessary to achieve sterilization at a...

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Related Experiment Video

Updated: May 19, 2026

Fabrication of 3D Carbon Microelectromechanical Systems C-MEMS
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Room temperature 3D carbon microprinting.

Fernand E Torres-Davila1,2, Katerina L Chagoya3, Emma E Blanco4

  • 1NanoScience Technology Center, University of Central Florida, Orlando, FL, USA.

Nature Communications
|March 30, 2024
PubMed
Summary
This summary is machine-generated.

Researchers developed eco-friendly 3D carbon printing using visible light and a metal-free catalyst. This method rapidly creates high-aspect-ratio carbon microstructures for advanced applications.

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Area of Science:

  • Materials Science
  • Nanotechnology
  • Chemical Engineering

Background:

  • Conventional 3D carbon material synthesis is energy-intensive and substrate-limited.
  • Scalable, eco-friendly methods for complex 3D carbon structures are needed.
  • Achieving ultra-high aspect ratios in patterned carbon materials remains a challenge.

Purpose of the Study:

  • To demonstrate a facile, room-temperature 3D printing process for carbon functional materials.
  • To develop an eco-friendly and scalable method for fabricating 3D carbon structures.
  • To explore the potential of photocatalytic growth for microscale carbon patterning.

Main Methods:

  • Utilized low-power visible light and a metal-free catalyst for photocatalytic carbon growth.
  • Employed a one-step process enabling rapid fabrication of microstructures.
  • Demonstrated tunable control over microstructure dimensions and array patterning.

Main Results:

  • Achieved rapid (seconds to minutes) 3D printing of carbon rods with aspect ratios up to ~500 and diameters <10 μm.
  • Successfully patterned centimeter-size arrays of rods with tunable height and pitch.
  • Created custom complex 3D carbon structures with controlled geometry.

Conclusions:

  • The developed photocatalytic approach offers a sustainable and efficient route for 3D carbon material fabrication.
  • The resulting carbon microstructures exhibit promising luminescence and ohmic properties.
  • This technology holds significant potential for optoelectronics, sensing, and bio-interfacing applications.