ADDITIVE MANUFACTURING METHOD FOR FABRICATING MICRO-NANO STRUCTURES

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ADDITIVE MANUFACTURING METHOD FOR FABRICATING MICRO-NANO STRUCTURES - A simplified explanation of the abstract

This abstract first appeared for US patent application 20240217168 titled 'ADDITIVE MANUFACTURING METHOD FOR FABRICATING MICRO-NANO STRUCTURES

Simplified Explanation:

This patent application describes a method for creating 3D nanostructures using additive manufacturing. Charged species are arranged in a fluid using an electric field to print nanostructures on a substrate.

Key Features and Innovation:

   * Additive manufacturing method for fabricating 3D nanostructures
   * Precise arrangement of charged species at nanoscale using configured electric field
   * Room temperature and atmospheric pressure operation without chemical reactions or specialized equipment
   * Enables low-cost, ultra-fast printing with high resolution and multi-material capabilities

Potential Applications: The technology can be used in various fields such as electronics, biomedicine, photonics, and materials science for creating custom nanostructures with high precision.

Problems Solved: The method addresses limitations of other nanofabrication techniques by offering a wider range of printing materials, faster printing speeds, and higher resolution for creating 3D nanostructures.

Benefits: The technology offers cost-effective, high-speed, and high-resolution fabrication of complex 3D nanostructures with multi-material capabilities.

Commercial Applications: Title: Advanced Additive Manufacturing for 3D Nanostructures This technology can be applied in industries such as semiconductor manufacturing, biomedical device fabrication, and optical component production, leading to improved product performance and efficiency.

Prior Art: Readers can explore prior research on additive manufacturing, nanofabrication techniques, and 3D printing methods to understand the evolution of this technology.

Frequently Updated Research: Researchers are constantly exploring new materials and configurations to enhance the capabilities and applications of this additive manufacturing method for 3D nanostructures.

Questions about Additive Manufacturing for 3D Nanostructures: 1. How does this additive manufacturing method compare to traditional lithography techniques for creating nanostructures?

   - Answer: This method offers advantages such as faster printing speeds, multi-material capabilities, and higher resolution compared to traditional lithography techniques.

2. What are the potential challenges in scaling up this additive manufacturing method for industrial production?

   - Answer: Challenges may include optimizing printing parameters for large-scale production, ensuring uniformity across a large area, and integrating the technology into existing manufacturing processes.

Original Abstract Submitted

an additive manufacturing method for fabricating 3d nanostructures is provided, charged species dispersed in a fluid are precisely arranged at nanoscale in each dimension with a configured electric field, so that the charged species are printed on a substrate to form an array of 3d nanostructures as desired. the additive manufacturing method of the present disclosure can be carried out at room temperature and atmospheric pressure without the aid of chemical reaction, laser sources, ion/electron beams, or photosensitive materials, and enables low-cost, ultra-fast printing speed, large-area, high-purity, multi-material, ultra-high-resolution and solves problems encountered in other nanofabrication techniques in making 3d nanostructures, such as a limited range of available printing materials, low resolution, slow printing speed, and one by one serial printing.