Peter J Pauzauskie
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Explore the profile of Peter J Pauzauskie including associated specialties, affiliations and a list of published articles.
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34
Citations
407
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Recent Articles
1.
Felsted R, Chun J, Schenter G, Bard A, Xia X, Pauzauskie P
Phys Rev Lett
. 2025 Mar;
134(8):088201.
PMID: 40085888
Rigorous understanding of assembly in colloidal systems is crucial to the development of tailored nanostructured materials. Despite extensive studies, a mechanistic understanding of the dynamics governing encounters of colloidal particles...
2.
Baum F, Forberger L, Bard A, Gariepy R, Pauzauskie P, Pozzo L
Ultrason Sonochem
. 2025 Feb;
114:107275.
PMID: 39999594
The potential of rare earth-doped sodium yttrium fluoride (NaYF) as upconverting nanoparticles extends to various applications, from electronics to biology. The hexagonal (β) phase of NaYF nanoparticles is known to...
3.
Effect of Solvent Composition on Non-DLVO Forces and Oriented Attachment of Zinc Oxide Nanoparticles
Liu L, Schmid S, Feng Z, Li D, Droubay T, Pauzauskie P, et al.
ACS Nano
. 2024 Jun;
18(26):16743-16751.
PMID: 38888092
Oriented attachment (OA) occurs when nanoparticles in solution align their crystallographic axes prior to colliding and subsequently fuse into single crystals. Traditional colloidal theories such as DLVO provide a framework...
4.
Felsted R, Graham T, Zhao Y, Bazak J, Nienhuis E, Pauzauskie P, et al.
J Phys Chem Lett
. 2024 May;
15(19):5076-5087.
PMID: 38708887
The dynamics, orientational anisotropy, diffusivity, viscosity, and density were measured for concentrated lithium salt solutions, including lithium chloride (LiCl), lithium bromide (LiBr), lithium nitrite (LiNO), and lithium nitrate (LiNO), with...
5.
Beck R, Huang Y, Petrone A, Abbott J, Pauzauskie P, Li X
ACS Phys Chem Au
. 2023 May;
3(3):299-310.
PMID: 37249932
Fluorescent nanodiamonds, that is, those containing optically active defects, have attracted interest for their ability to be used as qubits; for imaging; and as sensors for spin, stress, and temperature....
6.
Optical Trapping of High-Aspect-Ratio NaYF Hexagonal Prisms for kHz-MHz Gravitational Wave Detectors
Winstone G, Wang Z, Klomp S, Felsted G, Laeuger A, Gupta C, et al.
Phys Rev Lett
. 2022 Aug;
129(5):053604.
PMID: 35960566
We present experimental results on optical trapping of Yb-doped β-NaYF subwavelength-thickness high-aspect-ratio hexagonal prisms with a micron-scale radius. The prisms are trapped in vacuum using an optical standing wave, with...
7.
Luntz-Martin D, Felsted R, Dadras S, Pauzauskie P, Nick Vamivakas A
Opt Lett
. 2021 Jul;
46(15):3797-3800.
PMID: 34329284
Solid state laser refrigeration can cool optically levitated nanocrystals in an optical dipole trap, allowing for internal temperature control by mitigating photothermal heating. This work demonstrates cooling of ytterbium-doped cubic...
8.
Pandres E, Crane M, Davis E, Pauzauskie P, Holmberg V
ACS Nano
. 2021 May;
15(5):8653-8662.
PMID: 33950682
Semiconductor nanowire production through vapor- and solution-based processes has propelled nanowire systems toward a wide range of technological applications. Although vapor-based nanowire syntheses enable precise control over nanowire composition and...
9.
Xia X, Pant A, Ganas A, Jelezko F, Pauzauskie P
Adv Mater
. 2020 Jul;
33(23):e1905406.
PMID: 32666603
Herein, the role that point defects have played over the last two decades in realizing solid-state laser refrigeration is discussed. A brief introduction to the field of solid-state laser refrigeration...
10.
Pant A, Xia X, Davis E, Pauzauskie P
Nat Commun
. 2020 Jun;
11(1):3235.
PMID: 32576820
Photothermal heating represents a major constraint that limits the performance of many nanoscale optoelectronic and optomechanical devices including nanolasers, quantum optomechanical resonators, and integrated photonic circuits. Here, we demonstrate the...