JORDAN C. POLER, PH.D.
Jordan C. Poler, PH.D.
Education:
- B.S.: State University of NY at Brockport
- Ph.D.: University of NC at Chapel Hill
- Post-doc: Princeton University
Field of Interest:
Physical Chemistry
Research Focus:
Most of my research interests are materials related. My efforts are toward the fundamental studies of complex systems at the nanoscale with regard to applications of materials at the macroscale. Complex systems exist at surfaces, interfaces and thin films. The experimental techniques that I use to study these systems are both optically and electronically based. Scanning probe microscopies are the work-horses of my research. In particular, the scanning tunneling microscope (STM) and the newly developed scanning thermopower microscope (STPM) are central in my studies of surfaces and interfaces. The complex systems that are of most interest to me are in the areas of both; “hard” materials (e.g. nanotubes, nanoparticles, semiconductors and metals) and “soft” materials (e.g. self-assembled monolayers, biologically interesting molecules and Langmuir films).
The Poler Research Group consists of students from the Nanoscale Science Ph.D. Program, the Optical Science and Engineering Ph.D. program, the Master’s of Science program in Chemistry, undergraduates from various disciplines (Chemistry, Physics, Biology, Engineering, and Math), and high school students from around the state. We pursue fundamental studies of molecular and nanoscale systems to understand directed and self-assembly processes. We aim to understand directed and self-assembly processes. We aim to design new particles and materials with higher functionality and effectiveness. Our long-term interests are toward: novel mechanisms for mechanical transducers and sensors in NEMS, energy storage in supercapacitors, catalytic solar fuel production, water purification, and optical metamaterials.
We start by synthesizing novel coordination complexes that have useful and tunable spectral, electrochemical, and mechanical properties. We synthesize and purify single walled carbon nanotubes. We use various metal nanoparticles, quantum dots, and nanostructured carbons linked together by our coordination complexes to form higher order hybrid-nanomaterials. Some of these novel particles can be assembled into supraparticle assemblies with novel properties and function.