Lecture

Fabrication Extended: Bottom-Up Methods

Related lectures (31)

Carbon Nanostructures: Properties and Applications

Explores the properties and applications of carbon nanostructures, including graphene and carbon nanotubes, emphasizing their unique characteristics and diverse uses.

Colloidal Synthesis of Nanoparticles

Explores the synthesis, properties, and characterization of nanoparticles, including quantum confinement and catalytic applications.

Graphene Properties and Applications

Explores graphene properties, band structure, electronics, and nanoscale phenomena like the Quantum Hall effect and the Casimir effect.

Chemistry of Carbon Allotropes

Explores the chemistry of various carbon allotropes, discussing their unique properties and applications.

Nanoscale Phenomena: Introduction

Introduces nanoscale phenomena, covering quantum mechanics, atomic structures, and examples of nanoparticles' properties and optical behaviors.

Graphene: Quantum Properties and Nanoribbons

Explores graphene's quantum conductance, special electronic properties, nanoribbon fabrication, and edge effects.

Nanoscale MEMS or NEMS

Covers the transition to nanoscale devices, nanoscale imaging, capillary forces, AFM of graphene, and integrated sensors & actuators.

Plasmonic Nanostructures: Synthesis and Applications

Explores the fabrication of plasmonic nanostructures and a variety of plasmonic 'atoms' that can be synthesized for larger structures.

Polymers and Particles: Printing, Structures, and Applications

Explores polymers in 3D printing, nanoparticles, cellular uptake pathways, and drug release systems.

Engineering Carbon Nanostructures

Explores the engineering of intrinsic π-electron magnetism in carbon nanostructures, focusing on inducing magnetism in graphene and nanographenes through sublattice imbalance and topological frustration.

Ultrafast Carrier and Spin Dynamics in 2D Semiconductors

Reviews ultrafast carrier and spin dynamics in 2D semiconductors and their heterostructures, exploring unique optical responses and novel applications.

Nanotechnology to Enhance Electron Transfer

Explores the application of carbon nanotubes in enhancing electron transfer for biosensors, emphasizing their role in improving sensitivity and detection limits.

2D Electronic Devices and Materials

Explores 2D electronic devices and materials, including graphene, transition metal dichalcogenides, excitons, and valleytronics.

N-doped Graphene Membrane: Proton Exchange & Fuel Cells

Explores N-doped graphene membranes for proton exchange in fuel cells, focusing on performance and fabrication.

Magnetotheranostics: Nano-particle Tools for Cancer Detection and Treatment

Covers the development of superparamagnetic nanoparticles for cancer detection and treatment through MRI imaging and hyperthermia.

Machine learning in atomistic simulations: from reaction pathways to phase diagrams

Explores machine learning applications in atomistic simulations, focusing on water modeling, neural network potentials, and structure recognition.

Carbon-Based Nano-Electronics

Explores electrostatic doping in carbon-based nano-electronics, emphasizing the importance of low density of states for novel device concepts.

Nanoscale Properties: Surface Effects and Quantum Phenomena

Delves into nanoscale properties, emphasizing surface effects and quantum phenomena, exploring electronic, mechanical, magnetic, photonic, and chemical properties unique to the nanoscale.

Paper: Capillary Flow Progression

Explores capillary flow progression in paper microfluidics, lateral flow assays, gold nanoparticles in bioassays, automated LFA readers, and test results evaluation.

Spectroscopy: Electronic Properties and Techniques

Explores energy spectroscopy techniques like XPS and UPS, Auger spectroscopy, surface sensitivity, and graphene band structure.