Spin dynamics and relaxation in graphene nanoribbons: electron spin resonance probing.

Here we report the results of a multifrequency (~9, 20, 34, 239.2, and 336 GHz) variable-temperature continuous wave (cw) and X-band (~9 GHz) pulse electron spin resonance (ESR) measurement performed at cryogenic temperatures on potassium split graphene nanoribbons (GNRs). Important experimental findings include the following: (a) The multifrequency cw ESR data infer the presence of only carbon-related paramagnetic nonbonding states, at any measured temperature, with the g value independent of microwave frequency and temperature. (b) A linear broadening of the ESR signal as a function of microwave frequency is noticed. The observed linear frequency dependence of ESR signal width points to a distribution of g factors causing the non-Lorentzian line shape, and the g broadening contribution is found to be very small. (c) The ESR process is found to be characterized by slow and fast components, whose temperature dependences could be well described by a tunneling level state model. This work not only could help in advancing the present fundamental understanding on the edge spin (or magnetic)-based properties of GNRs but also pave the way to GNR-based spin devices.

[1]  A. Stesmans,et al.  Ferromagnetism in graphene nanoribbons: split versus oxidative unzipped ribbons. , 2012, Nano letters.

[2]  Ferenc Simon,et al.  Theory and model analysis of spin relaxation time in graphene — Could it be used for spintronics? , 2011 .

[3]  J. Goslar,et al.  Suppression of Raman electron spin relaxation of radicals in crystals. Comparison of Cu2+ and free radical relaxation in triglycine sulfate and Tutton salt single crystals , 2011, Journal of physics. Condensed matter : an Institute of Physics journal.

[4]  K. Novoselov,et al.  Spin splitting in graphene studied by means of tilted magnetic-field experiments , 2011, 1107.3925.

[5]  Andre Stesmans,et al.  Unzipped graphene nanoribbons as sensitive O2 sensors: Electron spin resonance probing and dissociation kinetics , 2011 .

[6]  W. Lu,et al.  Highly conductive graphene nanoribbons by longitudinal splitting of carbon nanotubes using potassium vapor. , 2011, ACS nano.

[7]  B. Beschoten,et al.  Observation of long spin-relaxation times in bilayer graphene at room temperature. , 2010, Physical review letters.

[8]  A. Stesmans,et al.  Paramagnetic centers in graphene nanoribbons prepared from longitudinal unzipping of carbon nanotubes , 2010, 1006.4942.

[9]  Yimin A. Wu,et al.  Electron paramagnetic resonance investigation of purified catalyst-free single-walled carbon nanotubes. , 2010, ACS nano.

[10]  P. Bobbert Organic semiconductors: What makes the spin relax? , 2010, Nature materials.

[11]  J. Palacios,et al.  Hydrogenated Graphene Nanoribbons for Spintronics , 2010, 1001.1263.

[12]  J. Fabian,et al.  Electron spin relaxation in graphene: The role of the substrate , 2009, 0905.0424.

[13]  J. Tour,et al.  Longitudinal unzipping of carbon nanotubes to form graphene nanoribbons , 2009, Nature.

[14]  Wei Han,et al.  Electron-hole asymmetry of spin injection and transport in single-layer graphene. , 2009, Physical review letters.

[15]  M. Wencka,et al.  Dynamics of CO2− radiation defects in natural calcite studied by ESR, electron spin echo and electron spin relaxation , 2008 .

[16]  B. V. van Wees,et al.  Electronic spin drift in graphene field-effect transistors. , 2008, Physical review letters.

[17]  O. Yazyev Magnetism in disordered graphene and irradiated graphite. , 2008, Physical review letters.

[18]  M. Śliwińska-Bartkowiak,et al.  Electron spin relaxation and quantum localization in carbon nanoparticle : Electron spin echo studies , 2008 .

[19]  B. Wees,et al.  Electronic spin transport and spin precession in single graphene layers at room temperature , 2007, Nature.

[20]  P. Li,et al.  Electron spin resonance studies of hydrogen adsorption on defect-induced carbon nanotubes , 2007 .

[21]  R. Blinc,et al.  13C NMR and EPR of carbon nanofoam , 2006 .

[22]  Barry Luther-Davies,et al.  Origin of magnetic moments in carbon nanofoam , 2006 .

[23]  L. Brunel,et al.  A quasioptical transient electron spin resonance spectrometer operating at 120 and 240 GHz , 2005 .

[24]  W. Lubitz,et al.  Electron spin-lattice relaxation of the S0 state of the oxygen-evolving complex in photosystem II and of dinuclear manganese model complexes. , 2005, Biochemistry.

[25]  Andre K. Geim,et al.  Electric Field Effect in Atomically Thin Carbon Films , 2004, Science.

[26]  Y. Ochiai,et al.  Conduction carriers in multi-walled carbon nanotubes , 2003 .

[27]  W. Hilczer,et al.  Electron Spin-Lattice Relaxation in Polymers and Crystals Related to Disorder and Structure Defects , 2003 .

[28]  W. Hilczer,et al.  Resonance-type effects in free radical electron spin–lattice relaxation and electron spin echo dephasing due to a dynamics of a homogeneous-chain oligomeric system , 2002 .

[29]  J. Salvetat,et al.  MODIFICATION OF MULTIWALL CARBON NANOTUBES BY ELECTRON IRRADIATION : AN ESR STUDY , 1999 .

[30]  R. Blinc,et al.  nuclear magnetic resonance and electron spin resonance of amorphous hydrogenated carbon , 1998 .

[31]  Stesmans Structural relaxation of Pb defects at the (111)Si/SiO2 interface as a function of oxidation temperature: The Pb-generation-stress relationship. , 1993, Physical review. B, Condensed matter.

[32]  Sugihara,et al.  Electron spin resonance in graphite. , 1991, Physical review. B, Condensed matter.

[33]  R. J. Elliott,et al.  Theory of the Effect of Spin-Orbit Coupling on Magnetic Resonance in Some Semiconductors , 1954 .