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Preparation and characterization of freely-suspended graphene nanomechanical membrane devices with quantum dots for point-of-care applications

العنوان	Preparation and characterization of freely-suspended graphene nanomechanical membrane devices with quantum dots for point-of-care applications
المؤلف	Memisoglu, G., Gülbahar, Burhan, Fernandez Bello, R.
تاريخ النشر:	2020-01-01
مكان النشر	- MDPI
الموضوع	Graphene oxide, Graphene, Quantum dot, Nanomechanical membrane, Acoustic sensing, VFRET, Point-of-care
النوع	دورية
اللغة	الإنجليزية
رقمي	نعم
مخطوط	لا
المكتبة:	جامعة اوزيجين
معرف أصل المكتبة	2072-666X
رقم السجل	64eefb20-e0b1-43cb-b606-6c21edab7aa1
موقع المكتبة	Electrical & Electronics Engineering
التاريخ	2020-01-01
ملاحظات	European Union (EU)
نص عينة	We demonstrate freely suspended graphene-based nanomechanical membranes (NMMs) as acoustic sensors in the audible frequency range. Simple and low-cost procedures are used to fabricate NMMs with various thicknesses based on graphene layers grown by graphite exfoliation and solution processed graphene oxide. In addition, NMMs are grafted with quantum dots (QDs) for characterizing mass sensitive vibrational properties. Thickness, roughness, deformation, deflection and emissions of NMMs with attached QDs are experimented and analyzed by utilizing atomic force microscopy, Raman spectroscopy, laser induced deflection analyzer and spectrophotometers. Forster resonance energy transfer (FRET) is experimentally achieved between the QDs attached on NMMs and nearby glass surfaces for illustrating acousto-optic utilization in future experimental implementations combining vibrational properties of NMMs with optical emission properties of QDs. This property denoted as vibrating FRET (VFRET) is previously introduced in theoretical studies while important experimental steps are for the first time achieved in this study for future VFRET implementations. The proposed modeling and experimental methodology are promising for future novel applications such as NMM based biosensing, photonics and VFRET based point-of-care (PoC) devices.
DOI	10.3390/mi11010104
Cilt	11

عرض في المصدر جامعة اوزيجين Özyeğin Üniversitesi

جامعة اوزيجين

Preparation and characterization of freely-suspended graphene nanomechanical membrane devices with quantum dots for point-of-care applications

المؤلف Memisoglu, G., Gülbahar, Burhan, Fernandez Bello, R.

تاريخ النشر 2020-01-01

مكان النشر - MDPI

الموضوع Graphene oxide, Graphene, Quantum dot, Nanomechanical membrane, Acoustic sensing, VFRET, Point-of-care

النوع دورية

اللغة الإنجليزية

رقمي نعم

مخطوط لا

المكتبة جامعة اوزيجين

معرف أصل المكتبة 2072-666X

رقم السجل 64eefb20-e0b1-43cb-b606-6c21edab7aa1

موقع المكتبة Electrical & Electronics Engineering

التاريخ 2020-01-01

ملاحظات European Union (EU)

نص عينة We demonstrate freely suspended graphene-based nanomechanical membranes (NMMs) as acoustic sensors in the audible frequency range. Simple and low-cost procedures are used to fabricate NMMs with various thicknesses based on graphene layers grown by graphite exfoliation and solution processed graphene oxide. In addition, NMMs are grafted with quantum dots (QDs) for characterizing mass sensitive vibrational properties. Thickness, roughness, deformation, deflection and emissions of NMMs with attached QDs are experimented and analyzed by utilizing atomic force microscopy, Raman spectroscopy, laser induced deflection analyzer and spectrophotometers. Forster resonance energy transfer (FRET) is experimentally achieved between the QDs attached on NMMs and nearby glass surfaces for illustrating acousto-optic utilization in future experimental implementations combining vibrational properties of NMMs with optical emission properties of QDs. This property denoted as vibrating FRET (VFRET) is previously introduced in theoretical studies while important experimental steps are for the first time achieved in this study for future VFRET implementations. The proposed modeling and experimental methodology are promising for future novel applications such as NMM based biosensing, photonics and VFRET based point-of-care (PoC) devices.

DOI 10.3390/mi11010104

Cilt 11