Effect of Inhomogeneous Broadening in Ultraviolet III-Nitride Light-Emitting Diodes

In the past years, light-emitting diodes (LED) made of GaN and its related ternary compounds with indium and aluminium have become an enabling technology in all areas of lighting. Visible LEDs have yet matured, but research on deep ultraviolet (UV) LEDs is still in progress. The polarisation in the anisotropic wurtzite lattice and the low free hole density in p-doped III-nitride compounds with high aluminium content make the design for high efficiency a critical step. The growth kinetics of the rather thin active quantum wells in III-nitride LEDs makes them prone to inhomogeneous broadening (IHB). Physical modelling of the active region of III-nitride LEDs supports the optimisation by revealing the opaque active region physics. In this work, we analyse the impact of the IHB on the luminescence and carrier transport III-nitride LEDs with multi-quantum well (MQW) active regions by numerical simulations comparing them to experimental results. The IHB is modelled with a statistical model that enables efficient and deterministic simulations. We analyse how the lumped electronic characteristics including the quantum efficiency and the diode ideality factor are related to the IHB and discuss how they can be used in the optimisation process.

Unity Yield of Deterministically Positioned Quantum Dot Single Photon Sources

We report on a platform for the production of single photon devices with a fabrication yield of 100%. The sources are based on InAsP quantum dots embedded within position-controlled bottom-up InP nanowires. Using optimized growth conditions, we produce large arrays of structures having highly uniform geometries. Collection efficiencies are as high as 83% and multiphoton emission probabilities as low as 0.6% with the distribution away from optimal values associated with the excitation of other charge complexes and re-excitation processes, respectively, inherent to the above-band excitation employed. Importantly, emission peak lines hapes have Lorentzian profiles indicating that linewidths are not limited by inhomogeneous broadening but rather pure dephasing, likely elastic carrier-phonon scattering due to a high phonon occupation. This work establishes nanowire-based devices as a viable route for the scalable fabrication of efficient single photon sources and provides a valuable resource for hybrid on-chip platforms currently being developed.

Fundamental Investigations into Single Molecule Surface Enhanced Raman Spectroscopy

<p>After the first claim of single molecule (SM) detection by surface enhanced Raman spectroscopy (SERS) was published in 1997 and years of debate and maturing, SM-SERS can now be considered as an established subfield of SERS. Besides the obvious promising advances in analytical spectroscopy that SM-SERS enables, some more fundamental studies are now also accessible. The main focus of this thesis is to understand certain aspects and tackle some outstanding issues in SM-SERS, both in methods and applications. In the first part of this thesis, we focus on the application of SM-SERS to the study of the homogeneous broadening of molecular vibrations. We show that the homogeneous linewidth of the dye Nile blue as measured on single molecule SERS spectra is much smaller than the inhomogeneous broadening obtained from the average signal. Individual molecules having the central Raman frequency occurring at slightly different positions is therefore the main cause of the inhomogeneous broadening in this system. Furthermore, we show that the homogeneous broadening of the mode of single molecules exhibits a strong temperature dependence from 80K to 300 K. This is suggestive of the vibrational energy exchange model which explicitly relates the temperature dependence of the linewidth of a vibrational mode to its interaction with other modes of the molecule or its environment. The average signal does not show this temperature dependence, this property is indeed washed out by ensemble averaging and its unravelling is made possible by SM-SERS. This study is the first example of direct measurement and study of the homogeneous broadening of a Raman peak. In the second part of this work, we focus on a particular method to prove single molecule sensitivity and demonstrate the single molecule detection of the iconic C₆₀ by SM-SERS using its peculiar spectral properties regarding isotopic substitution. A change in one unit mass in one of the carbon atoms is readily observed as a detectable frequency shift in the Ag(2) mode on the Raman spectrum of one C₆₀. This remarkable result is a direct consequence of the high symmetry of the molecule and is only accessible experimentally by measuring individual molecules. We perform SM-SERS detection of a isotopically enriched C₆₀ and show how the distribution of frequencies for the Ag(2) mode reflects the isotopic spread of the sample. Density Functional Theory (DFT) calculations support the experimental results. This provides the first ever evidence of single molecule detection of C₆₀ via SERS. Finally, we focus on the photostability of dyes excited resonantly in SERS conditions. Photobleaching of the molecule is an issue when doing SERS (and SM-SERS) at resonance. Nile blue is deposited on a highly ordered gold nanolithographic substrate and the time dependence of the SERS signal is monitored. Using a simple two-level system model to describe the mechanisms of photobleaching and express the photobleaching rate, we analyse the SERS intensity decay at different powers. This study is the first to be dedicated to the photobleaching decay rates of molecules on metallic surfaces and to highlight that the decay dynamics contains rates spanning four orders of magnitude. This work can potentially reveal information on the distribution of SERS enhancement factors on the surface.</p>

Fundamental Investigations into Single Molecule Surface Enhanced Raman Spectroscopy

<p>After the first claim of single molecule (SM) detection by surface enhanced Raman spectroscopy (SERS) was published in 1997 and years of debate and maturing, SM-SERS can now be considered as an established subfield of SERS. Besides the obvious promising advances in analytical spectroscopy that SM-SERS enables, some more fundamental studies are now also accessible. The main focus of this thesis is to understand certain aspects and tackle some outstanding issues in SM-SERS, both in methods and applications. In the first part of this thesis, we focus on the application of SM-SERS to the study of the homogeneous broadening of molecular vibrations. We show that the homogeneous linewidth of the dye Nile blue as measured on single molecule SERS spectra is much smaller than the inhomogeneous broadening obtained from the average signal. Individual molecules having the central Raman frequency occurring at slightly different positions is therefore the main cause of the inhomogeneous broadening in this system. Furthermore, we show that the homogeneous broadening of the mode of single molecules exhibits a strong temperature dependence from 80K to 300 K. This is suggestive of the vibrational energy exchange model which explicitly relates the temperature dependence of the linewidth of a vibrational mode to its interaction with other modes of the molecule or its environment. The average signal does not show this temperature dependence, this property is indeed washed out by ensemble averaging and its unravelling is made possible by SM-SERS. This study is the first example of direct measurement and study of the homogeneous broadening of a Raman peak. In the second part of this work, we focus on a particular method to prove single molecule sensitivity and demonstrate the single molecule detection of the iconic C₆₀ by SM-SERS using its peculiar spectral properties regarding isotopic substitution. A change in one unit mass in one of the carbon atoms is readily observed as a detectable frequency shift in the Ag(2) mode on the Raman spectrum of one C₆₀. This remarkable result is a direct consequence of the high symmetry of the molecule and is only accessible experimentally by measuring individual molecules. We perform SM-SERS detection of a isotopically enriched C₆₀ and show how the distribution of frequencies for the Ag(2) mode reflects the isotopic spread of the sample. Density Functional Theory (DFT) calculations support the experimental results. This provides the first ever evidence of single molecule detection of C₆₀ via SERS. Finally, we focus on the photostability of dyes excited resonantly in SERS conditions. Photobleaching of the molecule is an issue when doing SERS (and SM-SERS) at resonance. Nile blue is deposited on a highly ordered gold nanolithographic substrate and the time dependence of the SERS signal is monitored. Using a simple two-level system model to describe the mechanisms of photobleaching and express the photobleaching rate, we analyse the SERS intensity decay at different powers. This study is the first to be dedicated to the photobleaching decay rates of molecules on metallic surfaces and to highlight that the decay dynamics contains rates spanning four orders of magnitude. This work can potentially reveal information on the distribution of SERS enhancement factors on the surface.</p>

A new route for caesium lead halide perovskite deposition

Inorganic metal halide perovskites are relevant semiconductors for optoelectronic devices. The successful deposition of thin films of CsPbBr3 and CsPbCl3 has recently been obtained by Radio-Frequency magnetron sputtering. In this work we compare the morphological, structural and optical characteristics of the two materials obtained with this deposition technique. A detailed photoluminescence (PL) spectroscopy study of the as-grown samples was conducted at the macro and micro scale in a wide temperature range (10-300 K) to fully characterize the PL on sample areas of square centimeters, to assess the origin of the inhomogeneous broadening and to quantify the PL quantum yield quenching. Our results prove that this technique allows for the realization of high quality nanometric films with controlled thickness of relevance for optoelectronic applications.