textjournal article
Pore Size Control of Ultrathin Silicon Membranes by Rapid Thermal Carbonization
Abstract
Rapid thermal carbonization in a dilute acetylene (C2H2) atmosphere has been used to chemically modify and precisely tune the pore size of ultrathin porous nanocrystalline silicon (pnc-Si). The magnitude of size reduction was controlled by varying the process temperature and time. Under certain conditions, the carbon coating displayed atomic ordering indicative of graphene layer formation conformal to the pore walls. Initial experiments show that carbonized membranes follow theoretical predictions for hydraulic permeability and retain the precise separation capabilities of untreated membranes- Text
- Journal contribution
- Biophysics
- Biochemistry
- Ecology
- Inorganic Chemistry
- Environmental Sciences not elsewhere classified
- Biological Sciences not elsewhere classified
- Chemical Sciences not elsewhere classified
- Physical Sciences not elsewhere classified
- Rapid
- CarbonizationRapid
- carbon coating
- acetylene
- pore size
- permeability
- capability
- carbonized membranes
- ultrathin
- carbonization
- separation capabilities
- nanocrystalline silicon
- C 2H atmosphere
- Initial experiments show
- Ultrathin Silicon Membranes
- prediction
- process temperature
- pore walls
- Pore Size Control
- graphene layer formation conformal
- magnitude
- size reduction
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Last time updated on 16/03/2018
This paper was published in The Francis Crick Institute.
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