Nanoporous silicon nitride membranes fabricated from porous nanocrystalline silicon templates

DesOrmeaux, Jon‐Paul; Winans, Joshua D.; Wayson, Sarah E.; Gaborski, Thomas R.; Khire, Tejas; Striemer, Christopher C.; McGrath, James L.

doi:10.1039/c4nr03070b

Cited by 75 publications

(96 citation statements)

References 24 publications

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“…Affinity encoded, surface-grafted peptides or other organic molecules could improve the specificity of membranes used in sensors of biological or hazardous molecules. We recently introduced ultrathin nanoporous silicon nitride (NPN) 10 as a more mechanically robust, more chemically stable, and lower-cost alternative to the original nanomembrane material made from pure silicon. 11 Our objective in this work is to develop a general strategy for the coating of NPN with stable organic molecules that add functionality without diminishing the benefits of high permeability and size selectivity of the nanomembranes.…”

Section: Introductionmentioning

confidence: 99%

Modification of Nanoporous Silicon Nitride with Stable and Functional Organic Monolayers

Johnson

et al. 2017

Chem. Mater.

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This study describes the formation of functional organic monolayers on thin, nanoporous silicon nitride membranes. We demonstrate that the vapor-phase carbene insertion into the surface C–H bonds can be used to form sub-5 nm molecular coatings on nanoporous materials, which can be further modified with monolayers of polyethylene glycol (PEG) molecules. We investigate composition, thickness, and stability of the functionalized monolayers and the changes in the membrane permeability and pore size distribution. We show that, due to the low coating thickness (~7 nm), the functionalized membrane retains 80% of the original gas permeance and 40% of the original hydraulic permeability. We also show that the carbene/PEG functionalization is hydrolytically stable for up to 48 h of exposure to water and that it can suppress nonspecific adsorption of the proteins BSA and IgG. Our results suggest that the vapor-phase carbenylation can be used as a complementary technology to the traditional self-assembly and polymer brush chemistries in chemical functionalization of nanoporous materials, which are limited in their ability to serve as stable coatings that do not occlude nanomembrane pores.

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Section: Introductionmentioning

confidence: 99%

Modification of Nanoporous Silicon Nitride with Stable and Functional Organic Monolayers

Johnson

et al. 2017

Chem. Mater.

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“…This essentially creates an architecture comprising two pores in series. NPN is a recently developed highly porous nanomembrane technology with tunable pore sizes (20 – 80 nm) and porosities (1–40%) 29 . The gap between the nanofilter and SiN membranes is achieved through the lithographic patterning of a hexagonal grid of 1 µm diameter holes in a 200-nm thick SiO 2 layer deposited on top of SiN.…”

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confidence: 99%

DNA Translocations through Nanopores under Nanoscale Preconfinement

et al. 2017

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To reduce unwanted variation in the passage speed of DNA through solid-state nanopores, we demonstrate nanoscale pre-confinement of translocating molecules using an ultra-thin nanoporous silicon nitride membrane separated from a single sensing nanopore by a nanoscale cavity. We present comprehensive experimental and simulation results demonstrating that the presence of an integrated nanofilter within nanoscale distances of the sensing pore eliminates the dependence of molecular passage time distributions on pore size, revealing a global minimum in the coefficient of variation of the passage time. These results provide experimental verification that the inter- and intra-molecular passage time variation depends on the conformational entropy of each molecule prior to translocation. Furthermore, we show that the observed consistently narrower passage time distributions enables a more reliable DNA length separation independent of pore size and stability. We also demonstrate that the composite nanofilter/nanopore devices can be configured to suppress the frequency of folded translocations, ensuring single-file passage of captured DNA molecules. By greatly increasing the rate at which usable data can be collected, these unique attributes will offer significant practical advantages to many solid-state nanopore-based sensing schemes, including sequencing, genomic mapping, and barcoded target detection.

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“…The ultrathin NPN membranes are fabricated in silicon chips via a transfer etch process [4]. The pore pattern is formed into a hard mask on the surface of a silicon wafer by rapid thermal annealing of a stack of materials whose properties, along with the anneal parameters, control the pore size and density [12].…”

Section: Membrane Formation and Characterizationmentioning

confidence: 99%

“…Our group has developed nanoporous silicon nitride (NPN) membranes for inclusion in a small format HD device. These membranes, which were first described by our group four years ago [4], are 100 to 1000 times thinner than conventional HD membranes and are therefore orders-of-magnitude more efficient for dialysis [5]. In fact, given the molecular thickness of these membranes (~15 nm to ~75 nm) and their appreciable porosity (~15%), NPN membranes operate near the maximum permeability that is achievable for a nanoporous membrane [5–10].…”

Section: Introductionmentioning

confidence: 99%

Protein Separation and Hemocompatibility of Nitride Membranes in Microfluidic Filtration Systems

Salminen

Hill

Chung

et al. 2018

2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Improving the health outcomes for end-stage renal Disease (ESRD) patients on hemodialysis (HD) requires new technologies for wearable HD such as a highly efficient membrane that can achieve standard toxic clearance rates in small device footprints. Our group has developed nanoporous silicon nitride (NPN) membranes which are 100 to 1000 times thinner than conventional membranes and are orders-of-magnitude more efficient for dialysis. Counter flow dialysis separation experiments were performed to measure urea clearance while microdialysis experiments were performed in a stirred beaker to measure the separation of cytochrome-c and albumin. Hemodialysis experiments testing for platelet activation as well as protein adhesion were performed. Devices for the counter flow experiments were constructed with polydimethylsiloxane (PDMS) and a NPN membrane chip. The counter flow devices reduced the urea by as much as 20%. The microdialysis experiments showed a diffusion of ~60% for the cytochrome-c while clearing ~20% of the Albumin. Initial hemocompatibility studies show that the NPN membrane surface is less prone to both protein adhesion and platelet activation when compared to positive control (glass).

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Nanoporous silicon nitride membranes fabricated from porous nanocrystalline silicon templates

Cited by 75 publications

References 24 publications

Modification of Nanoporous Silicon Nitride with Stable and Functional Organic Monolayers

Modification of Nanoporous Silicon Nitride with Stable and Functional Organic Monolayers

DNA Translocations through Nanopores under Nanoscale Preconfinement

Protein Separation and Hemocompatibility of Nitride Membranes in Microfluidic Filtration Systems

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