Full publication list, Dr. Prashant Nagpal2020
56. “
Gold nanoclusters cause selective light-driven biochemical catalysis in living nano-biohybrid organisms”Bertram J.R., Ding Y., Nagpal P.*, Nanoscale Advances, DOI: 10.1039/D0NA00017E (2020). (
Link)55. “
Analysis of Identification Method for Bacterial Species and Antibiotic Resistance Genes Using Optical Data From DNA Oligomers”Wood R.L., Jensen T., Wadsworth C., Clement M., Nagpal P., Pitt W.G.*, Frontiers in Microbiology, 11:257 (2020). (
Link)
201954. “
Co-doping metal oxide nanotubes: Superlinear photoresponse and multianalyte sensing”Saleh I.K., Ding Y., Nagpal P.*, Materials Research Express, 6, 1150b1 (2019). (
Link)
53. “
Diagnostic optical sequencing”Korshoj L.E., Nagpal P.*, ACS Applied Materials and Interfaces, 11, 35587 (2019). (
Link)
52. “
Isolating the Escherichia coli transcriptomic response to superoxide generation from cadmium chalcogenide quantum dots”Aunins T.R., Eller K.A., Courtney C.M., Levy M., Goodman S.M., Nagpal P., Chatterjee A.*, ACS Biomaterials Science and Engineering, 5, 4206 (2019). (
Link)
51. “
Photophysical color tuning for photon upconverting nanoparticles”Sun Q.-C., Ding Y., Nagpal P.*, ACS Applied Materials and Interfaces, 11, 27011 (2019). (
Link)
50. “
Near-infrared light triggered antimicrobial indium phosphide quantum dots”Levy M., Bertram J.R., Eller, K.A., Chatterjee A., Nagpal P.*, Angewandte Chemie International Edition, 58, 11414 (2019). (
Link)
49. “
Nanorg microbial factories: Light-driven renewable biochemical synthesis using quantum dot-bacteria nano-biohybrids”Ding Y., Bertram J.R., Eckert C., Bommareddy R.R., Patel R., Conradie A., Bryan S., Nagpal P.*, Journal of the American Chemical Society, 141, 10272 (2019). (
Link)
48. “
BOCS: DNA k-mer content and scoring for rapid genetic biomarker identification at low coverage”Korshoj L.E., Nagpal P.*, Computers in Biology and Medicine, 110, 196 (2019). (
Link)
47. “
Tuning ternary Zn1-xCdxTe quantum dot composition: Engineering electronic states for light-activated superoxide generation as a therapeutic against multidrug-resistant bacteria.”Levy M., Chowdhury P.P., Eller, K.A., Chatterjee A., Nagpal P.*, ACS Biomaterials Science and Engineering, 5, 3111 (2019). (
Link)
46. “
Quantum dot therapeutics: a new class of radical therapies”Levy M., Chowdhury P.P., Nagpal P.*, Journal of Biological Engineering, 13:48 (2019). (
Link)Invited Review as "
Emerging Leader in Biological Engineering"
45. “
Nucleotide and structural label identification in single RNA molecules with quantum tunneling spectroscopy”Abel G.A., Korshoj L.E., Otoupal P.B., Khan S.K., Chatterjee A., Nagpal P.*, Chemical Science , 10, 1052 (2019). (
Link)
201844. “
Assessing different reactive oxygen species as potential antibiotics: Selectivity of intracellular superoxide generation using quantum dots”Levy M.,Courtney C.M., Chowdhury P.P.,Ding Y.,Grey E.L., Goodman S.M., Chatterjee A., Nagpal P.*, ACS Applied BioMaterials , 1, 529 (2018). (
Link)
43. “
Designing superoxide-generating quantum dots for selective light-activated nanotherapy”Goodman S.M., Levy M., Li F.F., Ding Y., Courtney C.M., Chowdhury P.P., Erbse A.,Chatterjee A., Nagpal P.*, Frontiers in Chemistry , 6, 46 (2018). (
Link)
42. “
High-throughput block optical DNA sequence identification”,Sagar D.M., Korshoj L.E., Hanson K., Chowdhury P.P., Otoupal P.,Chatterjee A., Nagpal P.*, Small , 14, 1703165 (2018).(
Link)
201741. “
Conformational smear characterization and binning of single-molecule conductance measurements for enhanced molecular recognition”,Korshoj L.E., Afsari S.,Chatterjee A., Nagpal P.*, Journal of the American Chemical Society , 139, 15420 (2017).
(Link)
40. “
Quantum point contact single-nucleotide conductance for DNA and RNA sequence identification”,Afsari S., Korshoj L.E., Abel G.A., Khan S.K., Chatterjee A., Nagpal P.*, ACS Nano , 11, 11169 (2017).
(Link)
39. “
Potentiating antibiotics in drug-resistant clinical isolates via stimuli-activated superoxide generation”,Courtney C.M., Goodman S.M., Nagy T.A., Levy M., Bhusal P., Madinger N.E., Detweiler C.S., Nagpal P.*, Chatterjee A.*, Science Advances,3, e1701776(2017).
(Link)
38. “
Photon upconversion towards applications in energy conversion and bioimaging”,Sun Q.C., Ding Y., Sagar D.M., Nagpal P.*, Progress in Surface Science, 92, 281 (2017).
(Link)
37. “
ROS mediated selection for increased NADPH availability in Escherichia coli”,Reynolds T.S., Courtney C.M., Erickson K.E., Wolfe L.M., Chatterjee A., Nagpal P., Gill R.T. Biotechnology and Bioengineering , 114, 2685 (2017).
(Link)
36. “
Titanium dioxide nanotube membranes for solar energy conversion: effect of deep and shallow dopants”,Ding Y., Nagpal P.*, Physical Chemistry Chemical Physics, 19, 10042 (2017).
(Link)
35. “
Single nucleobase identification using biophysical signatures from nanoelectronic quantum tunneling”,Korshoj L.E., Afsari S., Khan S., Chatterjee A.*, Nagpal P.*, Small, 13, 1603033 (2017).
(Link)
201634. “
Split-Wedge Antennas with Sub-5 nm Gaps for Plasmonic Nanofocusing”,Chen X., Lindquist N.C., Klemme D.J., Nagpal P., Norris D.J., Oh S.H., Nano Letters, 16, 7849 (2016).
(Link)
33. “
Standalone anion- and co-doped titanium dioxide nanotubes for photocatalytic and photoelectrochemical solar-to-fuel conversion”,Ding Y., Nagpal P.*, Nanoscale, 8, 17496 (2016). (
Link)
32. “
Observation of thermal beaming from tungsten and molybdenum bull's eyes”,Park J., Han S., Nagpal P., Norris D.*, ACS Photonics, 3, 494 (2016). (
Link)
31.
"Photoexcited quantum dots for killing multidrug-resistant bacteria"Courtney C.M., Goodman S.M., McDaniel J.A., Madinger N.E., Chatterjee A.*, Nagpal P.*, Nature Materials,15, 529 (2016). (
Link)
201530. “
Long-range energy transfer in self-assembled quantum dot-DNA cascades”,Goodman S.M., Siu A., Singh V., Nagpal P.*, Nanoscale, 7, 18435 (2015). (
Link)
29.
“Air-gating and chemical-gating in transistors and sensing devices made from hollow TiO2 semiconductor nanotubes”,Alivov Y., Funke H., Nagpal P.*, Nanotechnology, 26, 295203 (2015). (
Link)
28. “
Measurements of Single Nucleotide Electronic States as Nanoelectronic Fingerprints for Identification of DNA Nucleobases, their Protonated and Unprotonated States, Isomers, and Tautomers”,Ribot J.C., Chatterjee A.*, Nagpal P.*, The Journal of Physical Chemistry B, 119, 4968 (2015). (
Link)
27. “
Charge transport through exciton shelves in cadmium chalcogenide quantum dot-DNA nano-bioelectronic thin films”,Goodman S.M., Noh H., Singh V., Cha J.N., Nagpal P.*, Applied Physics Letters,106, 083109 (2015). (
Link)
26. “
Air-pressure tunable depletion width, rectification behavior, and charge conduction in oxide nanotubes”,Alivov Y., Funke H., Singh V., Nagpal P.*, ACS Applied Materials and Interfaces, 7, 2153 (2015). (
Link)
201425. “
Titanium-dioxide homojunction p-n diode”,Alivov Y., Ding Y., Singh V., Nagpal P.*, Applied Physics Letters, 105, 263501 (2014). (
Link)
24. “
Low Exciton-Phonon Coupling, High Charge Carrier Mobilities, and Multiexciton Properties in Two-Dimensional (2D) Lead, Silver, Cadmium, and Copper Chalcogenide Nanostructures”,Ding Y., Singh V., Goodman S.M., Nagpal P.*, The Journal of Physical Chemistry Letters, 5, 4291 (2014). (
Link)
23. “
Multiple Energy Exciton Shelves in Quantum Dot-DNA Nano-Bioelectronics”,Goodman S.M., Singh V., Ribot J.C., Chatterjee A., Nagpal P.*, The Journal of Physical Chemistry Letters, 5,3909 (2014). (
Link)
22. “
Pseudo-direct bandgap transitions in silicon nanocrystals: Effect on optoelectronics and thermoelectrics”,Singh V., Yu Y., Sun Q., Korgel B., Nagpal P.*, Nanoscale, 6,14643 (2014). (
Link)
21. “
Copper plasmonics and catalysis: Role of electron-phonon interactions in dephasing localized surface plasmons”,Sun Q., Ding Y., Goodman S., Funke H., Nagpal P.*, Nanoscale, 6,12450 (2014). (
Link)
20. “
Transparent conducting oxide nanotubes”Alivov Y., Singh V., Ding Y., Nagpal P.*, Nanotechnology, 25, 385202 (2014).(
Link)
19. “
Doping of wide-bandgap titanium-dioxide nanotubes: Optical, electronic and magnetic dopants”,Alivov Y., Singh V., Ding Y., Cerkovnik L.J., Nagpal P.*, Nanoscale, 6, 10839 (2014). (
Link)
18. “
Effect of plasmon-enhancement on photophysics in upconverting nanoparticles”Sun Q.-C., Ribot J.C., Singh V., Mundoor H., Smalyukh I.I., Nagpal P.*, Optics Express, 22, 11516 (2014). (
Link)
17. “
Photocatalysis deconstructed: design of a new catalyst for artificial photosynthesis”Singh V., Beltran I.J.C., Ribot, J.C., Nagpal P.*, Nano Letters, 14, 597 (2014). (
Link)
16. “
Direct conjugation of DNA to quantum dots for scalable assembly of photoactive thin films”Noh H., Goodman S.M., Mohan P., Goodwin A.P., Nagpal P., Cha J.N.*, RSC Advances, 4, 8064 (2014). (
Link)
15. “
Plasmon-Enhanced Energy Transfer for Improved Upconversion of Infrared Radiation in Doped-Lanthanide Nanocrystals”Sun Q.-C., Mundoor H., Ribot J.C., Singh V., Smalyukh I.I., Nagpal P.*, Nano Letters, 14, 101 (2014). (
Link)
201314. “
Fabrication of Smooth Patterned Structures of Refractory Metals, Semiconductors, and Oxides via Template Stripping”Hyuk J., Nagpal P., McPeak K.M., Lindquist N., Oh S.H., Norris D.J., ACS Applied Materials & Interfaces, 5, 9701, (2013). (
Link)
13. “
Plasmonic nanofocusing with a metallic pyramid and an integrated C-shaped aperture”Lindquist N., Johnson T.W., Nagpal P., Norris D.J., Oh S.H., Scientific Reports, 3, 1857, (2013). (
Link)
12. “
Measurement of electronic states of PbS nanocrystal quantum dots using scanning tunneling spectroscopy: The role of parity selection rules in optical absorption”Diaconescu B., Padilha L.A., Nagpal P., Swartzentruber B.S., Klimov V.I, Physical Review Letters, 110, 127406, (2013). (
Link)
201211. “
Single-Crystalline silver films for plasmonics”Hyuk J., Ambwani P., Manno M., Lindquist N., Nagpal P., Oh S.H., Leighton C.,Norris D.J., Advanced Materials, 24, 3988, (2012). (
Link)
10. “
Improved dielectric function in metallic films obtained via template stripping”Hyuk J., Nagpal P., Oh S.H., Norris D.J., Applied Physics Letters, 100, 081105, (2012). (
Link)
9. “
Engineering metallic nanostructures for plasmonic and nanophotonics"Lindquist N., Nagpal P., McPeak K., Norris D.J., Oh S.H., Reports on Progress in Physics, 75, 036501, (2012). (
Link)
2011
8. “
Role of mid-gap states in charge transport and photoconductivity in semiconductor nanocrystal films” Nagpal P., Klimov V.I., Nature Communications, 2:486 , (2011). (
Link)
Press:
MRS Bulletin and
NanotechWeb from Institute of Physics7. “
Spectral dependence of nanocrystal photoionization probability: The role of hot-carrier transfer”Padilha L.A., Robel I., Lee D.C., Nagpal P., Pietryga J.M., Klimov V.I., ACS Nano, 5, 5045, (2011). (
Link)
6. “
Template-stripped smooth Ag nanohole arrays with silica shells for surface plasmon resonance biosensing”Im H., Lee S.H., Wittenberg, N.J., Johnson T.W., Lindquist N., Nagpal P., Norris D.J., Oh S.H., ACS Nano, 5, 6244, (2011). (
Link)
5. “
Fabrication of carbon/refractory metal nanocomposites as thermally stable metallic photonic crystals”Nagpal P., Josephson D.P., Denny N.R., DeWilde J., Norris D.J., Stein A., Journal of Materials Chemistry, 21, 10836, (2011). (
Link)
20104. “
Three-dimensional Plasmonic Nanofocusing”Lindquist N., Nagpal P., Norris D.J., Oh S.H., Nano Letters, 10, 1369, (2010). (
Link)
2009
3. “
Ultra-smooth patterned metals for Plasmonics and Metamaterials”Nagpal P., Lindquist N., Oh S.H., Norris D.J., Science, 325, 594, (2009). (
Link)
20082. “
Efficient low temperature thermophotovoltaic emitters from metallic photonic crystals”Nagpal P., Han S.E., Stein A., Norris D.J., Nano Letters, 8, 3238, (2008). (
Link)
1. “
Thermally stable organic-inorganic hybrid photoresists for fabrication of photonic band gap structures using direct laser writing”Jun Y., Nagpal P., Norris D.J., Advanced Materials, 20, 606, (2008). (
Link)
