Motivated by publicized cases in which high levels of heavy metals were found in drinking water in Flint, Mich., and Newark, N.J., a science team led by researchers at Rutgers University used intense X-rays at Lawrence Berkeley National Laboratory (Berkeley Lab) to probe the structure of the crystals they developed and learn how they bind to heavy metals.
The crystals function like miniature, reusable sensors and traps, and are known as luminescent metal-organic frameworks, or LMOFs.
A research team used Berkeley Lab’s Advanced Light Source to determine the structure, shown in this rendering, of a luminescent metal-organic framework known as LMOF-261. The chemical components and large channels in the LMOF allow it to trap heavy metals.
Credit: Rutgers University
Simon Teat, a Berkeley Lab staff scientist, studied individual LMOF crystals, each measuring about 100 microns (millionths of a meter), with X-rays at the lab’s Advanced Light Source (ALS). Using diffraction patterns produced as the X-ray light struck the LMOF samples, Teat applied software tools to map their three-dimensional structure with atomic resolution.
The ALS is one of just a few synchrotron X-ray light sources in the world that have dedicated experimental stations for chemical crystallography studies of crystallized chemical compounds such as MOFs.
It all starts with structure
What he found was a patterned, grid-like 3-D structure containing carbon, hydrogen, oxygen, nitrogen, and zinc atoms that framed large, open channels. These atomic-scale structural details are key to understanding how the LMOFs bind heavy metals, and can also aid in designing more highly specialized structures.
Researchers have developed a specialized type of glowing metal-organic framework, or LMOF (molecular structure at center), that is designed to detect and remove heavy-metal toxins from water. At upper left, mercury (HG2+) is taken in by the LMOF. The graph at lower left shows how the LMOF’s fluorescence is turned off as it binds up the mercury. Its properties make this LMOF useful for both detecting and trapping heavy-metal toxins.
“With MOFs, you’re typically interested in using the holes for something,” Teat explained. In this case, the structure allows heavy metals to enter these open channels and chemically bind to the MOFs.
Their very open framework gives the MOFs an abundant surface area relative to their size, which allows them to take in a large amount of contaminants.
The LMOF structure was engineered to glow by incorporating a fluorescent chemical component, or ligand. “When the metal binds to the fluorescent ligand, the resulting framework fluoresces,” Teat said. The fluorescence of the LMOFs switches off when they interact with the heavy metals.
According to Jing Li, a chemistry professor at Rutgers University who led the research, the technology could be a money-saving solution. “Others had developed MOFs for either the detection of heavy metals or for their removal, but nobody before had really investigated one that does both,” Li added.
Intense X-rays produced at synchrotrons are the best way to map the 3-D structure of the MOFs, Li said, adding, “Knowing the crystal structures is one of the most important aspects of our research. You need those in order to perform subsequent characterizations and to understand the properties of these materials.”
Tests show MOFs are chemically selective, recyclable
In their tests, researchers found that the LMOFs bind strongly to mercury and lead, but bind weakly to lighter metals such as magnesium and calcium that are also found in water supplies but do not pose the same hazards.
Another view of the structure of LMOF-261, a glowing crystal designed to detect and remove heavy metals from water.
The LMOFs can also be recycled. Researchers found that they could collect, clean, and then reuse the LMOFs for three cycles of toxic cleansing before their performance began to degrade.
The study notes that heavily industrialized areas, cities with antiquated water regulations, and agricultural communities can be particularly susceptible to groundwater contamination, which can lead to soil contamination if not addressed. This can cause the contaminants to be taken up by plants and animals in the surrounding environment, broadening the pathways of exposure.
Li said that further R&D could explore lower-cost and more durable LMOFs that could last for more cycles, and researchers could also pursue the development of water filters by blending the LMOFs with polymers to create a solid film. “These filters could be used for capture on a larger scale,” she said.
“We would like to continue with this research,” Li said, adding that her team would like to test the system’s performance on actual contaminated water sources if funding becomes available. “These are promising results, but we have a long way to go.”
Her team also has used Berkeley Lab’s ALS to determine the crystal structures of MOFs for a wide variety of other applications, including high-explosives detection; toxin detection in foods; and new types of light-emitting components for LEDs, known as phosphors, that incorporate cheaper, more abundant materials.
The Advanced Light Source is a DOE Office of Science User Facility.
Researchers from the University of Texas at Dallas and Rider University also participated in this research. The work was supported by the DOE Office of Science.
Contacts and sources:
Lawrence Berkeley National Laboratory