Prof. Mircea Dinca

W M Keck Professor of Energy

Assistant

Lexy Wyne
ajwyne@mit.edu

Areas of Interest and Expertise

Inorganic Chemistry
Materials Chemistry
Metal-Organic Frameworks
MOFs
COFs
Porous Materials
Electronic and Ionic Conductors
Heterogeneous Catalysis
Gas Storage
Gas Separation
Thin Films and Membranes
Carbon Capture
Carbon Dioxide Capture and Separation
Water Purification and Desalination
Luminescent Sensors

Research Summary

The Dincă Lab is focused on addressing research challenges related to the storage and consumption of energy and global environmental concerns. Central to our efforts is the synthesis of novel organic-inorganic hybrid materials and the manipulation of their electrochemical and photophysical properties, with a current emphasis on microporous materials.

Inorganic and organic synthesis, as well as rigorous physical characterization are the cornerstones of our research. Students and post-doctoral researchers will gain synthetic skills spanning inorganic (Schlenk & Glove Box techniques), solid state, solvothermal, and organic chemistry (for ligand synthesis). We employ a range of characterization techniques: single-crystal and powder X-ray diffraction, gas-sorption analysis, electrochemistry, thermogravimetry and various spectroscopic techniques: NMR, UV-Vis, IR, EPR, etc. These allow us to delineate important structure-function relationships that guide us in the design of new materials with predesigned physical properties.

Recent Work

  • Video

    2023-Vienna-Dinca

    March 29, 2023Conference Video Duration: 22:40
    Searching for Materials that Collect and Store Energy

    2023-Vienna-Dinca-Day-2

    March 29, 2023Conference Video Duration: 93:35
    Distrubution Water Harvesting from Air in Water-Stressed and Remote Area Using Metal-Organic Frameworks -- Climate & Energy

    Mircea Dinca - 2016 Japan

    January 29, 2016Conference Video Duration: 44:34

    Porous Materials for Energy, Catalysis, and the Environment

    Traditional applications of metal-organic frameworks (MOFs) are focused on gas storage and separation, which take advantage of the inherent porosity and high surface area of these materials. The MOFs’ use in technologies that require charge transport have lagged behind, however, because MOFs are poor conductors of electricity. We show that design principles honed from decades of previous research in molecular conductors can be employed to produce MOFs with remarkable charge mobility and conductivity values that rival or surpass those of common organic semiconductors and even graphite. We further show that these, ordered, and crystalline conductors can be used for a variety of applications in energy storage, electrocatalysis, electrochromics, and selective chemiresistive sensing. Another virtually untapped area of MOF chemistry is related to their potential to mediate redox reactivity and heterogeneous catalysis through their metal nodes. We show that MOFs can be thought of as unique macromolecular ligands that give rise to unusual molecular clusters where small molecules can react in a matrix-like environment, akin to the metal binding pockets of metalloproteins. By employing a mild, highly modular synthetic method and a suite of spectroscopic techniques, we show that redox reactivity at MOF nodes can lead to the isolation and characterization of highly unstable intermediates relevant to biological and industrial catalysis, and to industrially relevant catalytic transformations that are currently performed only by homogeneous catalysts.