Magnetic properties of defective graphene
Komlev, Anton (2015)
Lataukset:
Diplomityö
2015
Julkaisun pysyvä osoite on
http://urn.fi/URN:NBN:fi-fe201506019778
http://urn.fi/URN:NBN:fi-fe201506019778
Tiivistelmä
In this thesis, the influence of the functionalization of graphene and graphite on their
magnetic properties was investigated. The functionalization was performed by covalent
attaching of a phenyl groups with three different radicals (4-bromoaniline, 4-chloroaniline
and 4-nitroaniline). Magnetic properties were measured by SQUID magnetometer. Both
pristine graphite and graphene showed strong diamagnetic behavior. For good quality
graphite, diamagnetism was found to be temperature-dependent. All samples demonstrated
noticeable paramagnetic contribution below 50 K. According to fitting experimental results
with Brillouin function and Curie law, it was shown that paramagnetism is provided by small
clusters of spins (superparamagnetic behavior). Moreover, the clusters size and spin
concentrations were calculated. For the samples functionalized with nitroaniline the
antiferromagnetic transition around 120 K was observed. To explain this behavior, a simple
model was proposed. Additional analysis of the graphene quality, structure and
composition of the samples was carried out by HRTEM, EDS mapping, Raman
spectroscopy and X-ray diffraction techniques.
magnetic properties was investigated. The functionalization was performed by covalent
attaching of a phenyl groups with three different radicals (4-bromoaniline, 4-chloroaniline
and 4-nitroaniline). Magnetic properties were measured by SQUID magnetometer. Both
pristine graphite and graphene showed strong diamagnetic behavior. For good quality
graphite, diamagnetism was found to be temperature-dependent. All samples demonstrated
noticeable paramagnetic contribution below 50 K. According to fitting experimental results
with Brillouin function and Curie law, it was shown that paramagnetism is provided by small
clusters of spins (superparamagnetic behavior). Moreover, the clusters size and spin
concentrations were calculated. For the samples functionalized with nitroaniline the
antiferromagnetic transition around 120 K was observed. To explain this behavior, a simple
model was proposed. Additional analysis of the graphene quality, structure and
composition of the samples was carried out by HRTEM, EDS mapping, Raman
spectroscopy and X-ray diffraction techniques.