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Bibliography

Our instruments are used by top reserchers world wide, including recent nobel prize winners, such as W.E. Moerner and S.W. Hell. Our bibliography is a collection of papers that mention explicitly PicoQuant or at least one of our product's name. Searching or browsing through the bibliography allows to find out which laboratories use PicoQuant devices and what type of applications have been reported so far.

The bibliography contains articles mentioning explicitly PicoQuant or at least one of our product's name (e.g. MicroTime). Most of the references can be found easily by full-text searches on the internet. However, some papers cite us only indirectly, sometimes not at all. Such publications are included only if the use of a PicoQuant product is known, for example, based on communication with the author(s). There are certainly many more articles reporting results obtained using PicoQuant devices. Unfortunately, such papers are often hidden for us. Please help completing this list.
Do you miss your publication? If yes, we will be happy to include it in our bibliography. Please send an e-mail to info@picoquant.com containing the appropriate citation. Thank you very much in advance for your kind co-operation.

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Searching for MicroTime 200

1302 results found.


Enhancing performance and stability of perovskite solar cells using hole transport layer of small molecule and conjugated polymer blend

Hwang H., Park S., Heo J.H., Kim W., Ahn H., Kim T.-S., Im S.H., Son H.J.
Journal of Power Sources, Vol.418, p.167-175 (2019)

Reference to: MicroTime 200
Related to: TRPL

Amino acid salt-driven planar hybrid perovskite solar cells with enhanced humidity stability

Yun S.-C., Ma S., Kwon H.-C., Kim K., Jang G., Yang H., Moon J.
Nano Energy, Vol.059, p.481-491 (2019)

Reference to: MicroTime 200

The nuclear structural protein NuMA is a negative regulator of 53BP1 in DNA double-strand break repair

Moreno N.S., Liu J., Haas K.M., Parker L.L., Chakraborty C., Kron S.J., Hodges K., Miller L.D., Langefeld C., Robinson P.J., Lelièvre S.A.
Nucleic Acids Research, Vol.047, p.2703-2715 (2019)

Reference to: MicroTime 200

Stacking of colloidal CdSe nanoplatelets into twisted ribbon superstructures: origin of twisting and its implication in optical properties

Kim W.D., Yoon D.-E., Kim D., Koh S., Bae W.K., Chae W.-S., Lee D.C.
The Journal of Physical Chemistry C, Vol.123, p.9445-9453 (2019)

Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), SymPhoTime

Tailoring photoluminescence from MoS2 monolayers by Mie-resonant metasurfaces

Bucher T., Vaskin A., Mupparapu R., Löchner F.J.F., George A., Chong K.E., Fasold S., Neumann C., Choi D.-Y., Eilenberger F., Setzpfandt F., Kivshar Y.S., Pertsch T., Turchanin A., Staude I.
ACS Photonics, Vol.006, p.1002-1009 (2019)

Reference to: MicroTime 200

Open atmosphere-processed stable perovskite solar cells using molecular engineered, dopant-free, highly hydrophobic polymeric hole-transporting materials: influence of thiophene and alkyl chain on power conversion efficiency

Rana P.J.S., Gunasekaran R.K., Park S.H., Tamilavan V., Karuppanan S., Kim H.-J., Prabakar K.
The Journal of Physical Chemistry C, Vol.123, p.8560-8568 (2019)

Reference to: MicroTime 200
Related to: TRPL

Chiral microneedles from an achiral Bis(boron dipyrromethene): spontaneous mirror symmetry breaking leading to a promising photoluminescent organic material

Gartzia-Rivero L., Leiva C.R., Sánchez-Carnerero E.M., Bañuelos J., Moreno F., Maroto B.L., García-Moreno I., Infantes L., Mendez B., López-Arbeloa I., de la Moya S.
Langmuir, Vol.035, p.5021-5028 (2019)

Reference to: MicroTime 200

Influence of apple phytochemicals in ZnO nanoparticles formation, photoluminescence and biocompatibility for biomedical applications

Alves M.M., Andrade S.M., Grenho L., Fernandes M.H., Santos C., Montemor M.F.
Materials Science and Engineering: Cv Vol.101, p.76-87 (2019)

Reference to: MicroTime 200, SPADs

Portable proportional-integral-derivative controlled chambers for giant unilamellar vesicles electroformation

dos Santos J.L., Mendanha S.A., Vieira S.L., Gonçalves C.
Biomedical Physics & Engineering Express, Vol.005, 047002 (2019)

Reference to: MicroTime 200

Single-stranded regions modulate conformational dynamics and ATPase activity of eIF4A to optimize 5′-UTR unwinding

Andreou A.Z., Harms U., Klostermeier D.
Nucleic Acids Research, Vol.047, p.5260-5275 (2019)

Reference to: MicroTime 200
Related to: FRET

Position and conjugation-dependent aggregation-induced emission enhancement properties of naphthalimide-tetraphenylethylene conjugates

Reddy T.S., Lee S., Choi M.-S.
Dyes and Pigments, Vol.168, p.49-58 (2019)

Reference to: MicroTime 200

Open atmospheric processed perovskite solar cells using dopant-free, highly hydrophobic hole-transporting materials: Influence of thiophene and selenophene π-spacers on charge transport and recombination properties

Gunasekaran R.K., Rana P.J.S., Park S.H., Tamilavan V., Karuppanan S., Kim H.-J., Prabakar K.
Solar Energy Materials and Solar Cells, Vol.199, p.66-74 (2019)

Reference to: MicroTime 200, SymPhoTime

Resveratrol-delivery vehicle with anti-VEGF activity carried to human retinal pigmented epithelial cells exposed to high-glucose induced conditions

Ruginǎ D., Ghiman R., Focşan M., Tăbăran F., Copaciu F., Suciu M., Pintea A., Aștilean S.
Colloids and Surfaces B: Biointerfaces, Vol.181, p.66-75 (2019)

Reference to: MicroTime 200

In situ observation of NiS nanoparticles depositing on single TiO2 mesocrystal for enhanced photocatalytic hydrogen evolution activity

Shi X., Kim S., Fujitsuka M., Majima T.
Applied Catalysis B: Environmental, Vol.254, p.594-600 (2019)

Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series), PicoHarp 300

Organic solar cells of enhanced efficiency and stability using zinc oxide:zinc tungstate nanocomposite as electron extraction layer

Soultati A., Verykios A., Speliotis T., Fakis M., Sakellis I., Jaouani H., Davazoglou D., Argitis P., Vasilopoulou M.
Organic Electronics, Vol.071, p.227-237 (2019)

Reference to: MicroTime 200, PicoHarp 300, SPADs

Radiative characteristics of nanopatch antennas based on plasmonic nanoparticles of various geometry and tris (2, 2'-bipyridine) ruthenium (II) hexafluorophosphate

Gritsienko A.V., Kurochkin N.S., Vitukhnovsky A.G., Selyukov A.S., Taydakov I.V., Eliseev S.P.
Journal of Physics D: Applied Physics, Vol.052, 325107 (2019)

Reference to: MicroTime 200, PicoHarp 300, SPADs

CdIn2S4 chalcogenide/TiO2 nanorod heterostructured photoanode: An advanced material for photoelectrochemical applications

Dhandole L.K., Mahadik M.A., Chung H.-S., Chae W.-S., Chae W.-S., Cho M., Jang J.S.
Applied Surface Science, Vol.490, p.18-29 (2019)

Reference to: MicroTime 200

Hydrophobic perovskites based on an alkylamine compound for high efficiency solar cells with improved environmental stability

Jung M.-H.
Journal of Materials Chemistry A, Vol.007, p.14689-14704 (2019)

Reference to: MicroTime 200

Single-molecule insights into the temperature and pressure dependent conformational dynamics of nucleic acids in the presence of crowders and osmolytes

Arns L., Knop J.-M., Patra S., Anders C., Winter R.
Biophysical Chemistry, Vol.251, 106190 (2019)

Reference to: MicroTime 200, Pulsed Diode Lasers (PDL Series, LDH-Series, LDH-FA Series)

Microcavity-supported lipid bilayers; evaluation of drug–lipid membrane interactions by electrochemical impedance and fluorescence correlation spectroscopy

Ramadurai S., Sarangi N.K., Maher S., NacConnell N., Bond A.M., McDaid D., Flynn D., Keyes T.E.
Langmuir, Vol.035, p.8095-8109 (2019)

Reference to: MicroTime 200, SymPhoTime
Related to: FCS

ABCA1 transporter reduces amphotericin B cytotoxicity in mammalian cells

Wu, A., Grela, E., Wójtowicz, K., Filipczak, N., Hamon, Y., Luchowski, R., Grudziński, W., Raducka-Jaszul, O.1, Gagoś, M., Szczepaniak, A., Chimini, G., Gruszecki, W.I., Trombik, T.
Cellular and Molecular Life Sciences, Vol.076, p.4979-4994 (2019)

Reference to: MicroTime 200, SPADs, SymPhoTime

Quasiepitaxy strategy for efficient full‐inorganic Sb2S3 solar cells

Deng H., Zeng Y., Ishaq M., Yuan S., Zhang H., Yang X., Hou M., Farooq U., Huang J., Sun K., Webster R., Wu H., Chen Z., Yi F., Song H., Hao X., Tang J.
Advanced Functional Materials, Vol.029, 1901720 (2019)

Reference to: MicroTime 200

Coalescence-driven simultaneous enhancement and quenching of the excited states of silver nanoclusters

Abbas M.A., Yoon S.J., Khan R., Lee J., Bang J.H.
The Journal of Physical Chemistry C, Vol.123, p.14921-14927 (2019)

Reference to: MicroTime 200

Energy band edge alignment of anisotropic BiVO4 to drive photoelectrochemical hydrogen evolution

Kim C.W., Ji S., Myung JongKang M.J., Park H., Li F., Cheng H.-M., Kang Y.S.
Materials Today Energy, Vol.013, p.205-213 (2019)

Reference to: MicroTime 200

Density gradient selection of colloidal silver nanotriangles for assembling dye-particle plasmophores

Oliveira-Silva R., Sousa-Jerónimo M., Botequim D., Silva N.J.O., Prazeres D.M.F., Paulo P.M.R.
Nanomaterials, Vol.009, 893 (2019)

Reference to: MicroTime 200, TimeHarp 100/200, SymPhoTime