@phdthesis{Kim2023, author = {Kim, Jiyong}, title = {Synthesis of InP quantum dots and their applications}, doi = {10.25932/publishup-58535}, url = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-585351}, school = {Universit{\"a}t Potsdam}, pages = {XIX, 142}, year = {2023}, abstract = {Technologically important, environmentally friendly InP quantum dots (QDs) typically used as green and red emitters in display devices can achieve exceptional photoluminescence quantum yields (PL QYs) of near-unity (95-100\%) when the-state-of-the-art core/shell heterostructure of the ZnSe inner/ZnS outer shell is elaborately applied. Nevertheless, it has only led to a few industrial applications as QD liquid crystal display (QD-LCD) which is applied to blue backlight units, even though QDs has a lot of possibilities that able to realize industrially feasible applications, such as QD light-emitting diodes (QD‒LEDs) and luminescence solar concentrator (LSC), due to their functionalizable characteristics. Before introducing the main research, the theoretical basis and fundamentals of QDs are described in detail on the basis of the quantum mechanics and experimental synthetic results, where a concept of QD and colloidal QD, a type-I core/shell structure, a transition metal doped semiconductor QDs, the surface chemistry of QD, and their applications (LSC, QD‒LEDs, and EHD jet printing) are sequentially elucidated for better understanding. This doctoral thesis mainly focused on the connectivity between QD materials and QD devices, based on the synthesis of InP QDs that are composed of inorganic core (core/shell heterostructure) and organic shell (surface ligands on the QD surface). In particular, as for the former one (core/shell heterostructure), the ZnCuInS mid-shell as an intermediate layer is newly introduced between a Cu-doped InP core and a ZnS shell for LSC devices. As for the latter one (surface ligands), the ligand effect by 1-octanethiol and chloride ion are investigated for the device stability in QD‒LEDs and the printability of electro-hydrodynamic (EHD) jet printing system, in which this research explores the behavior of surface ligands, based on proton transfer mechanism on the QD surface. Chapter 3 demonstrates the synthesis of strain-engineered highly emissive Cu:InP/Zn-Cu-In-S (ZCIS)/ZnS core/shell/shell heterostructure QDs via a one-pot approach. When this unconventional combination of a ZCIS/ZnS double shelling scheme is introduced to a series of Cu:InP cores with different sizes, the resulting Cu:InP/ZCIS/ZnS QDs with a tunable near-IR PL range of 694-850 nm yield the highest-ever PL QYs of 71.5-82.4\%. These outcomes strongly point to the efficacy of the ZCIS interlayer, which makes the core/shell interfacial strain effectively alleviated, toward high emissivity. The presence of such an intermediate ZCIS layer is further examined by comparative size, structural, and compositional analyses. The end of this chapter briefly introduces the research related to the LSC devices, fabricated from Cu:InP/ZCIS/ZnS QDs, currently in progress. Chapter 4 mainly deals with ligand effect in 1-octanethiol passivation of InP/ZnSe/ZnS QDs in terms of incomplete surface passivation during synthesis. This chapter demonstrates the lack of anionic carboxylate ligands on the surface of InP/ZnSe/ZnS quantum dots (QDs), where zinc carboxylate ligands can be converted to carboxylic acid or carboxylate ligands via proton transfer by 1-octanethiol. The as-synthesized QDs initially have an under-coordinated vacancy surface, which is passivated by solvent ligands such as ethanol and acetone. Upon exposure of 1-octanethiol to the QD surface, 1-octanthiol effectively induces the surface binding of anionic carboxylate ligands (derived from zinc carboxylate ligands) by proton transfer, which consequently exchanges ethanol and acetone ligands that bound on the incomplete QD surface. The systematic chemical analyses, such as thermogravimetric analysis‒mass spectrometry and proton nuclear magnetic resonance spectroscopy, directly show the interplay of surface ligands, and it associates with QD light-emitting diodes (QD‒LEDs). Chapter 5 shows the relation between material stability of QDs and device stability of QD‒LEDs through the investigation of surface chemistry and shell thickness. In typical III-V colloidal InP quantum dots (QDs), an inorganic ZnS outermost shell is used to provide stability when overcoated onto the InP core. However, this work presents a faster photo-degradation of InP/ZnSe/ZnS QDs with a thicker ZnS shell than that with a thin ZnS shell when 1-octanethiol was applied as a sulfur source to form ZnS outmost shell. Herein, 1-octanethiol induces the form of weakly-bound carboxylate ligand via proton transfer on the QD surface, resulting in a faster degradation at UV light even though a thicker ZnS shell was formed onto InP/ZnSe QDs. Detailed insight into surface chemistry was obtained from proton nuclear magnetic resonance spectroscopy and thermogravimetric analysis-mass spectrometry. However, the lifetimes of the electroluminescence devices fabricated from InP/ZnSe/ZnS QDs with a thick or a thin ZnS shell show surprisingly the opposite result to the material stability of QDs, where the QD light-emitting diodes (QD‒LEDs) with a thick ZnS shelled QDs maintained its luminance more stable than that with a thin ZnS shelled QDs. This study elucidates the degradation mechanism of the QDs and the QD light-emitting diodes based on the results and discuss why the material stability of QDs is different from the lifetime of QD‒LEDs. Chapter 6 suggests a method how to improve a printability of EHD jet printing when QD materials are applied to QD ink formulation, where this work introduces the application of GaP mid-shelled InP QDs as a role of surface charge in EHD jet printing technique. In general, GaP intermediate shell has been introduced in III-V colloidal InP quantum dots (QDs) to enhance their thermal stability and quantum efficiency in the case of type-I core/shell/shell heterostructure InP/GaP/ZnSeS QDs. Herein, these highly luminescent InP/GaP/ZnSeS QDs were synthesized and applied to EHD jet printing, by which this study demonstrates that unreacted Ga and Cl ions on the QD surface induce the operating voltage of cone jet and cone jet formation to be reduced and stabilized, respectively. This result indicates GaP intermediate shell not only improves PL QY and thermal stability of InP QDs but also adjusts the critical flow rate required for cone-jet formation. In other words, surface charges of quantum dots can have a significant role in forming cone apex in the EHD capillary nozzle. For an industrially convenient validation of surface charges on the QD surface, Zeta potential analyses of QD solutions as a simple method were performed, as well as inductively coupled plasma optical emission spectrometry (ICP-OES) for a composition of elements. Beyond the generation of highly emissive InP QDs with narrow FWHM, these studies talk about the connection between QD material and QD devices not only to make it a vital jumping-off point for industrially feasible applications but also to reveal from chemical and physical standpoints the origin that obstructs the improvement of device performance experimentally and theoretically.}, language = {en} } @phdthesis{Breitenstein2012, author = {Breitenstein, Michael}, title = {Ortsaufgel{\"o}ster Aufbau von DNA-Nanostrukturen auf Glasoberfl{\"a}chen}, url = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-61857}, school = {Universit{\"a}t Potsdam}, year = {2012}, abstract = {Im Fokus dieser Arbeit stand der Aufbau einer auf DNA basierenden Nanostruktur. Der universelle Vier-Buchstaben-Code der DNA erm{\"o}glicht es, Bindungen auf molekularer Ebene zu adressieren. Die chemischen und physikalischen Eigenschaften der DNA pr{\"a}destinieren dieses Makromolek{\"u}l f{\"u}r den Einsatz und die Verwendung als Konstruktionselement zum Aufbau von Nanostrukturen. Das Ziel dieser Arbeit war das Aufspannen eines DNA-Stranges zwischen zwei Fixpunkten. Hierf{\"u}r war es notwendig, eine Methode zu entwickeln, welche es erm{\"o}glicht, Funktionsmolek{\"u}le als Ankerelemente ortsaufgel{\"o}st auf eine Oberfl{\"a}che zu deponieren. Das Deponieren dieser Molek{\"u}le sollte dabei im unteren Mikrometermaßstab erfolgen, um den Abmaßen der DNA und der angestrebten Nanostruktur gerecht zu werden. Das eigens f{\"u}r diese Aufgabe entwickelte Verfahren zum ortsaufgel{\"o}sten Deponieren von Funktionsmolek{\"u}len nutzt das Bindungspaar Biotin-Neutravidin. Mit Hilfe eines Rasterkraftmikroskops (AFM) wurde eine zu einem „Stift" umfunktionierte Rasterkraftmikroskopspitze so mit der zu deponierenden „Tinte" beladen, dass das Absetzen von Neutravidin im unteren Mikrometermaßstab m{\"o}glich war. Dieses Neutravidinmolek{\"u}l {\"u}bernahm die Funktion als Bindeglied zwischen der biotinylierten Glasoberfl{\"a}che und dem eigentlichen Adressmolek{\"u}l. Das somit generierte Neutravidin-Feld konnte dann mit einem biotinylierten Adressmolek{\"u}l durch Inkubation funktionalisiert werden. Namensgebend f{\"u}r dieses Verfahren war die M{\"o}glichkeit, Neutravidin mehrmals zu deponieren und zu adressieren. Somit ließ sich sequenziell ein Mehrkomponenten-Feld aufbauen. Die Einschr{\"a}nkung, mit einem AFM nur eine Substanz deponieren zu k{\"o}nnen, wurde so umgangen. Ferner mußten Ankerelemente geschaffen werden, um die DNA an definierten Punkten immobilisieren zu k{\"o}nnen. Die Bearbeitung der DNA erfolgte mit molekularbiologischen Methoden und zielte darauf ab, einen DNA-Strang zu generieren, welcher an seinen beiden Enden komplement{\"a}re Adressequenzen enth{\"a}lt, um gezielt mit den oberfl{\"a}chenst{\"a}ndigen Ankerelementen binden zu k{\"o}nnen. Entsprechend der Geometrie der mit dem AFM erzeugten Fixpunkte und den oligonukleotidvermittelten Adressen kommt es zur Ausbildung einer definierten DNA-Struktur. Mit Hilfe von fluoreszenzmikroskopischen Methoden wurde die aufgebaute DNA-Nanostruktur nachgewiesen. Der Nachweis der nanoskaligen Interaktion von DNA-bindenden Molek{\"u}len mit der generierten DNA-Struktur wurde durch die Bindung von PNA (peptide nucleic acid) an den DNA-Doppelstrang erbracht. Diese PNA-Bindung stellt ihrerseits ein funktionales Strukturelement im Nanometermaßstab dar und wird als Nanostrukturbaustein verstanden.}, language = {de} }