甜心视频app

Contact Information

Education

Diplome d'Ingenieur - Ecole Superieure de Chimie Industrielle de Lyon, France (Chemistry and Chemical Engineering)
Ph.D. - Wayne State University (Physical Inorganic Chemistry)
Postdoctoral Research Fellow, Colorado State University

Research/Areas of Interest

Biosynthetic pathways for silver metal nanoparticles
Silver nanoparticles are amongst the most abundantly produced nanomaterials, in large part due to their wide-spectrum antimicrobial properties and their incorporation in everyday household products. The use of plant extracts to prepare silver nanoparticles from the bioreduction of silver ions is well reported in the literature; however, a molecular understanding of the formation and stabilization of these metal nanoparticles, needed to attain nanoparticle size control and nanoparticle synthesis reproducibility, is mostly lacking, and is a focus of our research.

Experimental probes of noble metal nanoparticle formation
We are investigating experimental probes of the kinetics of noble metal nanoparticle formation via surface plasmon resonance versus other, more direct, methods.

Plasmonic metal nanoparticles as biosensors
We are probing the strong optical sensitivity of noble metal nanoparticles via their surface plasmon resonance towards the detection of analytes and their application as biosensors.

Link to Google Scholar page:

Publications/Creative Works

Recent Publications

• H.E. Sandoe, M.A.  Watzky*, S.A. Diaz 鈥淓xperimental Probes of Silver Metal Nanoparticle Formation Kinetics: Comparing Indirect Versus More Direct Methods鈥� International Journal of Chemical Kinetics 2019, 51, 861-871. 
• M.A. Watzky* and R.G. Finke* 鈥淕old nanoparticle formation kinetics and mechanism: A critical analysis of the 鈥淩edox Crystallization鈥� mechanism鈥� ACS Omega 2018, 3, 1555-1563.
• Bentea, M.A. Watzky^*, and R.G. Finke^* 鈥淪igmoidal nucleation and growth curves across nature fit by the Finke鈭扺atzky model of slow continuous nucleation and autocatalytic growth: Explicit formulas for the lag and growth times plus other key insights鈥� Journal of Physical Chemistry C 2017, 121, 5302鈭�5312.

Selected Publications Prior to 甜心视频app

• A.M. Morris, M.A. Watzky^* and R.G. Finke^* 鈥淧rotein aggregation kinetics, mechanism and curve-fitting: A review of the literature鈥� Biochimica et Biophysica Acta2009, 1794, 375-397. Top 10 Most Downloaded Articles on BBA Proteins and Proteomics; 鈥淗ighly Cited Paper鈥� (Web of Science); >300 citations (SciFinder)
• M.A. Watzky, E.E Finney and R.G. Finke^* 鈥淭ransition-metal nanocluster size vs. formation time and the catalytically effective nucleus number: A mechanism-based treatment鈥� Journal of the American Chemical Society2008, 130, 11959-11969.
• A.M. Morris, M.A. Watzky, J.N. Agar, R.G. Finke^* 鈥淔itting neurological protein aggregation kinetic data via a 2-step, minimal/Ockham鈥檚 razor model: The Finke-Watzky mechanism of nucleation followed by autocatalytic growth鈥� Biochemistry2008, 47, 2413-2427
• M.A. Watzky, A.M. Morris, E.D. Ross^* and R.G. Finke^* 鈥淔itting yeast and mammalian prion aggregation kinetic data with the Finke-Watzky 2-step model of nucleation and autocatalytic growth鈥� Biochemistry2008, 47, 10790-10800.
• M.A. Watzky and R.G. Finke^* 鈥淭ransition metal nanocluster formation kinetic and mechanistic studies.  A new mechanism when hydrogen is the reductant: Slow, continuous nucleation and fast autocatalytic surface growth鈥� Journal of the American Chemical Society1997, 119, 10382-10400. >500 citations (SciFinder)
• M.A. Watzky and R.G. Finke^* 鈥淣anocluster size-control and 鈥渕agic number鈥� investigations.  Experimental tests of the 鈥渓iving metal polymer鈥� concept and of mechanism-based size-control predictions leading to the syntheses of Iridium(0) nanoclusters centering about four sequential magic numbers鈥� Chemistry of Materials1997, 9, 3083-3095.