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Related Concept Videos

Steel Manufacturing01:26

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Steel manufacturing is a multi-stage process that begins by smelting iron ore into cast iron in a blast furnace. This initial stage involves layering iron ore with coke, a type of fuel, and crushed limestone within the furnace. The coke is ignited with a high volume of air, leading to the creation of carbon monoxide, which acts to reduce the iron ore to pure iron.
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Upstream processing represents a critical phase in biomanufacturing, wherein biological systems such as microorganisms, mammalian cells, or insect cells are cultivated to produce therapeutic proteins, vaccines, enzymes, or other biologically derived products. This phase encompasses all steps from the selection and genetic manipulation of the production organism to the cultivation of cells in bioreactors under tightly controlled environmental conditions.Host Selection and Genetic OptimizationThe...
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Manufacturing of Three-dimensionally Microstructured Nanocomposites through Microfluidic Infiltration
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Nanomanufacturing: A Perspective.

J Alexander Liddle1, Gregg M Gallatin1

  • 1Center for Nanoscale Science and Technology, National Institute of Standards and Technology , 100 Bureau Drive, Gaithersburg, Maryland 20899, United States.

ACS Nano
|February 11, 2016
PubMed
Summary
This summary is machine-generated.

Nanomanufacturing enables mass production of nanoscale devices, balancing cost and time-to-market. It examines top-down and bottom-up processes for scalable, high-volume production of functional nanomaterials.

Keywords:
lithographynanofabricationnanomanufacturingself-assembly

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Area of Science:

  • Materials Science
  • Engineering
  • Nanotechnology

Background:

  • Nanotechnology has led to nanomanufacturing, the scalable production of nanoscale materials and devices.
  • Unlike research-focused nanofabrication, nanomanufacturing demands cost-effectiveness, high throughput, and rapid market entry.

Purpose of the Study:

  • To analyze the factors influencing the selection of nanomanufacturing processes for commercial viability.
  • To evaluate the potential of top-down, bottom-up, and hybrid approaches in nanomanufacturing.
  • To explore how form-function relationships drive the high-volume production of advanced nanomaterials.

Main Methods:

  • Comparative analysis of top-down and bottom-up manufacturing techniques.
  • Evaluation of process characteristics against commercial constraints (cost, throughput, time-to-market).
  • Case study approach using silicon integrated circuit manufacturing as a baseline.

Main Results:

  • Identified key considerations for matching nanomanufacturing processes with specific products.
  • Assessed the strengths and limitations of different process strategies for scalability.
  • Highlighted the importance of design for manufacturability in achieving desired nanoscale properties.

Conclusions:

  • Successful nanomanufacturing requires careful process selection and optimization.
  • Integrating top-down and bottom-up methods can offer synergistic advantages.
  • Strategic design of nanoscale structures is crucial for enabling high-volume, functional product realization.