Dr. Pham Van Nhat

Qualifications 

• 2008: Bachelor in Physical Engineering, University of Engineering and Technology, Vietnam National University of Hanoi.
• 2010: Master in Nanotechnology Applications, University of Paris 11
• 2016: Doctorate in Process Engineering and Environment, University of Toulouse, Paul Sabatier.

Teaching Interests 

Introduction of Micro/Nanotechnology, Smart Hybrid Materials, BioMEMS, Bionanotechnology and BioMems 

Research Interests 

Application of microfluidics to:

•   Organ-on-Chip or Drug Screening
•  Nanomaterials synthesis
•  Capillary Electrophoresis Microchip
• Detection of charged molecules using Optical tools

Selected Publications 

1. Van N P, Villemejane J, Hamdi F, Mottet G, Dalmay C, Woytasik M, Martincic E, Dufour-Gergam E, Franşais O and Mir L M 2010 A high density microfluidic device for cell pairing and electrofusion Procedia Engineering 5 49–52
2. Pernot P, Bonneté F, Teychené S, Pham N, Radajewski D, Biscans B, Guillet P, Brennich M and Round A 2015 Crystallisation in situ – and much more – at the ESRF BioSAXS BM29 beamline Acta Crystallographica Section A Foundations and Advances 71 s143–4
3. Pham N, Radajewski D, Round A, Brennich M, Pernot P, Biscans B, Bonneté F and Teychené S 2017 Coupling high throughput microfluidics and small-angle X-ray scattering to study protein crystallization from solution Analytical chemistry 89 2282–7
4. Rodríguez-Ruiz I, Teychené S, Van Pham N, Radajewski D, Lamadie F, Llobera A and Charton S 2017 Broadcasting photonic lab on a chip concept through a low cost manufacturing approach Talanta 170 180–4
5. Rodríguez-Ruiz I, Radajewski D, Charton S, Phamvan N, Brennich M, Pernot P, Bonneté F and Teychené S 2017 Innovative High-Throughput SAXS Methodologies Based on Photonic Lab-on-a-Chip Sensors: Application to Macromolecular Studies Sensors 17 1266
6. Teychené S, Radajewski D, Pham N, Rodríguez-Ruiz I, Pernot P, Brennich M, Bizien T, Biscans B and Bonneté F 2017 Coupling microfluidics and SAXS to study the whole crystallization process Acta Crystallographica Section A Foundations and Advances 73 C611–C611
7. Nguyen T V, Pham N V, Mai H H, Duong D C, Le H H, Sapienza R and Ta V-D 2019 Protein-based microsphere biolasers fabricated by dehydration Soft Matter 15 9721–6
8. Nguyen L-L, Le Q-H, Pham V-N, Bastide M, Gam-Derouich S, Nguyen V-Q and Lacroix J-C 2021 Confinement Effect of Plasmon for the Fabrication of Interconnected AuNPs through the Reduction of Diazonium Salts Nanomaterials 11 1957
9. Anh N N, Chuc N V, Thang B H, Nhat P V, Hao N, Phuong D D, Minh P N, Subramani T, Fukata N and Trinh P V 2020 Solar Cell Based on Hybrid Structural SiNW/Poly(3,4 ethylenedioxythiophene): Poly(styrenesulfonate)/Graphene Global Challenges 4 2000010
10. Nguyen N A, Nguyen V H, Pham V N, Le T T, Nguyen V T and Pham V T 2021 Effect of graphene oxide concentration on the properties of silicon nanoholes/poly(3,4-ethylene dioxythiophene): poly(styrene sulfonate)/graphene oxide hybrid solar cell Adv. Nat. Sci: Nanosci. Nanotechnol. 12 035009
11. Pham V N, Radajewski D, Rodríguez-Ruiz I and Teychene S 2021 Microfluidics: A Novel Approach for Dehydration Protein Droplets Biosensors 11 460
12. Toan N V, Nhat P V and Duong T V 2021 Fabricating Microsphere Lasers by Protein Dehydration: A Fast Fabrication Method and Excellent Lasing Properties VNU Journal of Science: Mathematics – Physics 37
13. Editor A 2021 Effect of graphene oxide concentration on the properties of silicon nanoholes/poly(3,4-ethylene dioxythiophene): poly(styrene sulfonate)/graphene oxide hybrid solar cell Advances in Natural Sciences: Nanoscience and Nanotechnology 035009–035009
14. Van Duong T, Chung N X, Phan H N, Nguyen H T, Nguyen D D, Le L T and Van Pham N 2022 A facile way to optimize thermoelectric properties of SnSe thin films via sonication-assisted liquid-phase exfoliation J Mater Sci: Mater Electron