Thesis on-line

Thesis on-line

For anyone interested my humble thesis in now available online on Tesis Doctorals en Xarxa

I am not particularly proud of it, I'm sure there are various things that could have been done better, but i hope this may help some of you. At least to know which mistakes to avoid! :)

Why 1D expands on cooling?

Why 1D expands on cooling?

If we heat or cool an object we observe a change in its volume. This is due to the thermal expansion, and is described by the thermal expansion coefficient. It describes how the volume changes with temperature.

In the typical 3D solids if we heat up the size of the object will increase (easy!). That behavior is due to increasing of the energy. If we add energy to the system, the vibrations of the lattice atoms become more significant and the average distance between the atoms increases, which in the end contributes to the bigger volume/length of the system. As an easy example think of railway tracks getting deformed during hot, summer days.

Now the situation in 1D and 2D systems is totally different. Measurements were first done on graphene with SEM microscopy and Raman spectroscopy, both of them showing a negative thermal expansion coefficient. That means, that unlike the typical materials graphene contracts with increasing temperature. The negative thermal expansion coefficient was estimated to be rather large 8x 10^-6 1/K.

Then in our work we extracted the thermal expansion coefficient for single-walled carbon nanotubes. Because the nanotubes are so small, and the thermal expansion even smaller, we couldn't measure it directly. Instead we measured the shifts in resonance frequency of a nanotube resonator, which we then related to the change in tension of the nanotube. Taking into account the elongation imposed by contracting gold electrodes and substrate, we could determine the expansion coefficient of a nanotube. This is also negative and relatively large.

What is the reason behind negative thermal expansion of 1 and 2D objects?

This is a simple explanation offered by my ex-boss Adrian Bachtold. At 0 K temperature (so called absolute zero) there are no phonon modes in the sample, so you can imagine it laying completely flat on the surface, with a given length L0. Then if you increase the temperature there are more and more phononic modes, especially the flexural modes which are responsible for deforming the sample. If you then project the length on the sample LT on the surface it will appear shorter.

Autumn art

Autumn art

We had a few rainy days here last week, clear sign that autumn is coming.

This is one of the autumn-style images, shades of grey and some golden leaves. It respresents a membrane partially destroyed during processing, but if you didn't know it looks like one of the images that can score a high price in Sotheby's!

Holes and bubbles

Holes and bubbles

Many things have changed recently, I've defended the thesis, went on long holidays, started a new job (http://www.icn.cat/~p2n/) and, well, here I am, back to the lab.
I am mainly working on nano/micro fabrication again, this time trying to develop some suspended SOI structures. There should be no trick in that, but of course something went wrong and the sample seems to be suffering from chicken pox :) We are wishing it a fast recovery!

Almost a month being a doctor

Almost a month being a doctor

I'm coming a bit late with updating my status: PhD in Physics (wish it was an option to put it as my status on facebook!), since 29th of June. Below I post some images taken by my Mom.

Panic, panic on the train

With the tribunal.

In a way it's a great relief to manage to defend your thesis, after all the efforts, last-minute corrections and a few panic attacks.My thesis is in general about different electro-mechanical systems made of carbon nanotubes. Electro-mechanical means that the nanotube is set in motion by some kind of electrical stimulation. It can either vibrate like a guitar string (a mechanical resonator) or the electrical force can be used to transport a cargo along the nanotube (a motor). Both types of systems are very interesting, mainly because they behave different than they macro-scale counterparts.

Big day coming..

Big day coming..

The thesis is done!
After months of writing, deleting, re-writing and re-deleting.... I finally managed to complete my PhD thesis. It's quite a relief to have it done, today the plan is to print it out, put the covers and deliver to the tribunal. The last step is preparing the power point for the defence and by the end of the month I should be a proud doctor in Physics (cross your fingers!!!).

happy st. valentine!

happy st. valentine!

how to clean graphene?

how to clean graphene?

Graphene is a single layer of carbon atoms. However the problem is that many things like to stick to graphene (polymers, glue from scotch tape, thermal tape, amorphous carbon and all the other kind of  'dirt'). This can be quite dramatic, especially when you realize that sometimes thickness of the dirt accumulated is bigger that the thickness of graphene itself! In that case you have to think, what are you actually measuring? Is it really graphene or graphene + contamination?

To clean graphene a few methods were invented

1. Thermal annealing - annealing in an oven, in high temperature (around 300-350C) and Ar/H2 ambient. All the organic contamination is removed.

2. Current annealing - passing high current through graphene in vacuum. Due to high temperature some of the contamination evaporates and some is moved to the electrodes due to electromigration.

3. Mechanical cleaning - with AFM tip in contact mode. The tip sweeps graphene surface mechanically removing the contamination.

4. Cleaning with carbon nanotubes -  recently I realized that I can use CNTs  to sweep the dirt away from the graphene. If you pass a nanotube on top of graphene surface, it will become very clean and you can easily see it with AFM image. In a way it is similar to AFM contact mode, but it´s much faster: you can sweep 1x1 um in a few seconds.

Below an image of nanotube (MWNT) cleaning graphene:

70s are back!

70s are back!

Recently I've been really busy with my new devices and hardly getting out of the lab! (everyone now cross their fingers!)

But today I got quite in the party mood with the new image I got with the optical microscope! Shame it's only Wednesday!!