Innovation in Nanoporous Chemistry

The combination of adept chemistry and computational design made possible the synthesis of a new material, named MIL-101 by its originators, (where MIL stands for Matériaux de l’Institut Lavoisier), with very large internal pores (ø~3.4nm) and surface area (5,900 m2.g-1). The new, crystalline material is representative of a class of compounds, known as metal organic framework materials, (MOFs), with potential applications in many fields including chemical separation, heterogeneous catalysis and gas storage. Confirmation of the structure of the new material exploited the intense X-ray beams at the ESRF.

Porous materials with large, regular, accessible cages and tunnels are increasingly in demand for many applications including chemical separation or purification, catalysis, molecular sensors, electronics and gas storage. Depending on their structure and pore size, these materials allow molecules of only certain shapes and sizes to enter the pores, a property known as shape selectivity. The environment within the pores can be very different to that outside, thus promoting chemical reactions that do not occur in the bulk material. Another prospective use is as templates for forming calibrated, monodisperse nanomaterials. In this respect, the larger the pores, the wider the range of reactants that can be manipulated or stored.

Férey and co-workers’ strategy combined three main ideas. First, discrete multi-atom building units were designed and generated in solution (Fig. 1). Second, with the aim of producing a compound with large pores, the building units were combined to produce larger units. For MIL-101 the key building unit is a supercluster of four smaller clusters linked by difunctional organic components to make a large tetrahedral assembly. The third idea involves being sure of what you’ve actually made, i.e. how to determine the structure of the new material. It is well known that it becomes increasingly difficult to grow highly diffracting single crystals as structures grow larger. When single crystals are unavailable, powder diffraction can provide sufficient information for structure solution. Based on their understanding of the ways the building units might combine, possible structural models were predicted and assessed via a computational strategy that calculated their relative stability. Favourable solutions were then compared with the high quality powder diffraction data collected from MIL-101 at ESRF. Once a good match between the predicted and measured powder patterns was seen, the researchers could be sure of the nature of their new material.

This breakthrough opens up a new field for targeted chemistry, computational methods for structure prediction and most importantly novel materials with useful applications. Férey and co-workers describe the hydrid solid, MIL-101, as an excellent candidate for the storage of gas, creation of nano-objects in a regular and monodisperse mode with specific physical properties, or for drug delivery. Recent studies on smaller porous materials carried out by various research groups around the world leave open the possibility of successfully creating hydrid materials with even larger pores and more complex structures keeping always in mind that the most important goal should be to incorporate useful functions.

Source: European Synchrotron Radiation Facility (ESRF)

Scientists determine strength of 'liquid smoke' with 3D images
(PhysOrg.com) -- Researchers have created a 3D image of a material referred to as "liquid smoke." Aerogel, also known as liquid smoke or "San Francisco fog," is an open-cell polymer with pores smaller than 50 nanometers in diameter.
Researchers demonstrate a flexible, 1-step assembly of nanoscale structures
Scientists at the University of Pennsylvania have created a one-step, repeatable method for the production of functional nanoscale patterns or motifs with adjustable features, size and shape using a single master "plate."
Researchers form metal nanoparticles into porous structures
For 5,000 years or so, the only way to shape metal has been to "heat and beat." Even in modern nanotechnology, working with metals involves carving with electron beams or etching with acid.

In 'novel playground,' metals are formed into porous nanostructures
For 5,000 years or so, the only way to shape metal has been to "heat and beat." Even in modern nanotechnology, working with metals involves carving with electron beams or etching with acid.
Giant memory thanks to tiny capacitors
German-Korean research team produces a permanent memory using a new procedure and thereby sets a memory density record.

Super multi-use minerals unveiled
This material forms around a third of the average packet of washing powder and helps refine 99 per cent of the world's petrol. It is also used to clean up nuclear waste. This extremely useful material is a zeolite. In its natural form it originates from volcanoes but it is synthesised for commercial purposes.
Microspheres to carry hydrogen, deliver drugs, filter gases and detect nuclear development
What looks like a fertilized egg, flows like water, gets stuffed with catalysts and exotic nanostructures and may have the potential of making the current retail gasoline infrastructure compatible with hydrogen-based vehicles of the future – not to mention also contributing to arenas such as nuclear proliferation and global warming?
Researchers develop nanowire 'paper towel' for oil spills
A mat of nanowires with the touch and feel of paper could be an important new tool in the cleanup of oil and other organic pollutants, MIT researchers and colleagues report in the May 30 online issue of Nature Nanotechnology.

Innovation in Nanoporous Chemistry

Related stories:

News discussion: