Browsing by Author "Keleştemur, Yusuf"

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    Colloidal heterostructures of semiconductor quantum wells : synthesis, characterization and applications
    (2017-06) Keleştemur, Yusuf
    Colloidal semiconductor quantum wells, also known as nanoplatelets (NPLs), have recently emerged as a new class of colloidal semiconductor nanocrystals enabling fascinating excitonic properties. With their quasi two-dimensional structure resembling epitaxially-grown quantum wells, these atomically- at nanoplatelets exhibit narrow emission linewidths, giant linear and nonlinear absorption cross-sections, and ultrafast uorescence lifetimes when compared to other classes of semiconductor nanocrystals. These appealing features have led to achievement of low lasing thresholds and high color purity by using simple heterostructures of these NPLs. To further exploit the benefits of these solutionprocessed NPLs and develop next-generation colloidal optoelectronic devices, novel heterostructures of NPLs with superior excitonic properties are in high demand. In this thesis, to address these needs, we proposed and demonstrated novel heterostructured NPLs. This thesis includes the rational design and systematic synthesis and characterization of these hetero-NPLs. To overcome the lower photoluminescence quantum yield (PL-QY) and stability issues of core/shell NPLs, we successfully synthesized CdSe/CdS/CdS core/crown/shell NPLs resembling platelet-in-a-box. With this advanced architecture, we accomplished substantially enhanced PL-QY and absorption crosssection as well as stability, allowing for the achievement of low-threshold optical gain. However, due to the pure vertical confinement observed in these NPLs, these exciting excitonic features of NPLs suffered from the limited spectral tunability. By developing homogenously alloyed CdSexS1 NPLs together with their alloyed core/crown and alloyed core/shell heterostructures, we succeeded in obtaining highly tunable excitonic features and further extending tunability of the optical gain from these NPLs. In addition to the NPLs having Type-I electronic structure, we demonstrated the highly uniform growth of CdSe/CdTe core/crown NPLs having Type-II electronic structure exhibiting unique excitonic properties Additionally, to realize the evolution of Type-II electronic structure, we synthesized CdSe/CdSe1-xTex core/crown NPLs by precisely tailoring the composition of the crown region. Without changing their vertical thicknesses, we achieved again highly tunable excitonic features and near-unity PL-QY from these hetero- NPLs. Based on the proposed architectures of these heteronanoplatelets, we believe the findings of this thesis provide important guidelines and inspiration for the synthesis of highly efficient and stable heterostructured NPLs to construct high-performance colloidal optoelectronic devices, possibly challenging their conventional epitaxially-grown counterparts.
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    Low-threshold optical gain and lasing of colloidal nanoplatelets
    (IEEE, 2014-10) Keleştemur, Yusuf; Güzeltürk, Burak; Olutaş, Murat; Delikanlı, Savaş; Demir, Hilmi Volkan
    Semiconductor nanocrystals, which are also known as colloidal quantum dots (CQDs), are highly attractive materials for high performance optoelectronic device applications such as lasers. With their size, shape and composition tunable electronic structure and optical properties, CQDs are highly desired for achieving full-color, temperature-insensitive, low-threshold and solution-processed lasers [1, 2]. However, due to their small size, they suffer from the nonradiative multiexciton Auger Recombination (AR), where energy of a bound electron-hole pair is transferred to a third particle of either an electron or a hole instead of radiative recombination. Therefore, CQDs having suppressed AR are strongly required for achieving high quality CQD-based lasers. To address this issue, CQDs having different size, shape and electronic structure have been synthesized and studied extensively [3-5]. Generally, suppression of AR and lower optical gain thresholds are achieved via reducing the wavefunction overlap of the electron and hole in a CQD. However, the separation of the electron and hole wavefunctions will dramatically decrease the oscillator strength and optical gain coefficient, which is highly critical for achieving high performance lasers. Therefore, colloidal materials with suppressed AR and high gain coefficients are highly welcomed. Here, we study optical gain performance of colloidal quantum wells [6] of CdSe-core and CdSe/CdS core/crown nanoplatelets (NPLs) that demonstrate remarkable optical properties with ultra-low threshold one- and two-photon optical pumping. As a result of their giant oscillator strength, superior optical gain and lasing performance are achieved from these colloidal NPLs with greatly enhanced gain coefficient [7]. © 2014 IEEE.
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    Synthesis and characterization of highly efficient CdSe/CdS core/shell nanocrystals with silar technique
    (2012) Keleştemur, Yusuf
    Owing to their size tunable electronic structure and optical properties, semiconductor nanocrystal quantum dots (NQDs) have become attractive for a wide range of device applications ranging from life sciences to electronics in the last two decades. However, highly efficient and stable NQDs are essential to reaching high performance with these devices utilizing NQDs. In this thesis, to meet these requirements, a new class of CdSe/CdS core/shell NQDs are studied including their colloidal synthesis and nanocharacterization. In this work, CdSe/CdS core/shell NQDs were synthesized with successive ion layer adsorption and reaction (SILAR) technique, which enabled highly precise shell thickness control and uniform coating of the shell material. When compared to the most commonly used CdSe/ZnS core/shell NQDs, CdSe/CdS core/shell NQDs were found to provide important advantages. First, the lattice mismatch within CdSe and CdS (3.9%) is lower than that within CdSe and ZnS (12%), which was very critical for obtaining highly efficient NQDs. Second, as a result of having lower bandgap in CdS, great enhancement in absorption cross section was achieved with more red-shifted emission, which is not possible with CdSe/ZnS core/shell NQDs. Moreover, suppression of Auger recombination was successfully observed with the partial separation of electron and hole wavefunctions in the synthesized CdSe/CdS core/shell NQDs. With all these attractive properties that were experimentally measured, CdSe/CdS core/shell NQDs were found to make better alternatives to CdSe/ZnS core/shell for numerous applications.