Synthesis, Characterization And Functionalization Of Silicon Nanoparticle Based Hybrid Nanomaterials For Photovoltaic And Biological Applications

January 2014

Silicon nanoparticles are attractive candidates for biological, photovoltaic and energy storage applications due to their size dependent optoelectronic properties. These include tunable light emission, high brightness, and stability against photo-bleaching relative to organic dyes (see Chapter 1). The preparation and characterization of silicon nanoparticle based hybrid nanomaterials and their relevance to photovoltaic and biological applications are described. The surface-passivated silicon nanoparticles were produced in one step from the reactive high-energy ball milling (RHEBM) of silicon wafers with various organic ligands. The surface structure and optical properties of the passivated silicon nanoparticles were systematically characterized. Fast approaches for purifying and at the same time size separating the silicon nanoparticles using a gravity GPC column were developed. The hydrodynamic diameter and size distribution of these size-separated silicon nanoparticles were determined using GPC and Diffusion Ordered NMR Spectroscopy (DOSY) as fast, reliable alternative approaches to TEM. Water soluble silicon nanoparticles were synthesized by grafting PEG polymers onto functionalized silicon nanoparticles with distal alkyne or azide moieties. The surface-functionalized silicon nanoparticles were produced from the reactive high-energy ball milling (RHEBM) of silicon wafers with a mixture of either 5-chloro-1-pentyne in 1-pentyne or 1,7 octadiyne in 1-hexyne to afford air and water stable chloroalkyl or alkynyl terminated nanoparticles, respectively. Nanoparticles with the ω-chloroalkyl substituents were easily converted to ω-azidoalkyl groups through the reaction of the silicon nanoparticles with sodium azide in DMF. The azido terminated nanoparticles were then grafted with monoalkynyl-PEG polymers using a copper catalyzed alkyne-azide cycloaddition (CuAAC) reaction to afford core-shell silicon nanoparticles with a covalently attached PEG shell. Covalently linked silicon nanoparticle clusters were synthesized via the CuAAC “click” reaction of functional silicon nanoparticles with α,ω-functional PEG polymers of various lengths. Dynamic light scattering studies show that the flexible globular nanoparticle arrays undergo a solvent dependent change in volume (ethanol> dichloromethane> toluene) similar in behavior to hydrogel nanocomposites. A novel light-harvesting complex and artificial photosynthetic material based on silicon nanoparticles was designed and synthesized. Silicon nanoparticles were used as nanoscaffolds for organizing the porphyrins to form light-harvesting complexes thereby enhancing the light absorption of the system. The energy transfer from silicon nanoparticles to porphyrin acceptors was investigated by both steady-state and time-resolved fluorescence spectroscopy. The energy transfer efficiency depended on the donor-acceptor ratio and the distance between the nanoparticle and the porphyrin ring. The addition of C60 resulted in the formation of silicon nanoparticle-porphyrin-fullerene nanoclusters which led to charge separation upon irradiation of the porphyrin ring. The electron-transfer process between the porphyrin and fullerene was investigated by femto-second transient absorption spectroscopy. Finally, the water soluble silicon nanoparticles were used as nanocarriers in photodynamic therapeutic application, in which can selectively deliver porphyrins into human embryonic kidney 293T (HEK293T) cells. In particular, the PEGylated alkynyl-porphyrins were conjugated onto the azido-terminated silicon nanoparticles via a CuAAC “click” reaction. The resultant PEGylated porphyrin grafted silicon nanoparticles have diameters around 13.5 ± 3.8 nm. The cryo-TEM and conventional TEM analysis proved that the PEGylated porphyrin grafted silicon nanoparticle could form the micelle-like structures at higher concentration in water via self-assembly. The UV-Vis absorption analysis demonstrated that the silicon nanoparticle could reduce the porphyrin aggregation in water which can reduce the photophysical activity of porphyrin. In addition, the nanoparticle complex was capable of producing singlet oxygen when the porphyrin units were excited by light. The cell studies demonstrated that the silicon nanoparticle could deliver the porphyrin drugs into HEK293T cells and accumulate in the mitochondria where the porphyrin could serve as an efficient photosensitizer to kill the cells via mitochondrial apoptotic pathway. / acase@tulane.edu

Silicon Nanoparticles

Light Harvesting

Photodynamic Therapy

School of Science & Engineering

Chemistry

Ph.D

Spectroscopic Investigations of the Photophysics of Cryptophyte Light-harvesting

Dinshaw, Rayomond

21 November 2012

The biological significance of photosynthesis is indisputable as it is necessary for nearly all life on earth. Photosynthesis provides chemical energy for plants, algae, and bacteria, while heterotrophic organisms rely on these species as their ultimate food source. The initial step in photosynthesis requires the absorption of sunlight to create electronic excitations. Light-harvesting proteins play the functional role of capturing solar radiation and transferring the resulting excitation to the reaction centers where it is used to carry out the chemical reactions of photosynthesis. Despite the wide variety of light-harvesting protein structures and arrangements, most light-harvesting proteins are able to utilize the captured solar energy for charge separation with near perfect quantum efficiency. This thesis will focus on understanding the energy transfer dynamics and photophysics of a specific subset of light-harvesting antennae known as phycobiliproteins. These proteins are extracted from cryptophyte algae and are investigated using steady-state and ultrafast spectroscopic techniques.

Ultrafast Spectroscopy

Light-Harvesting

Cryptophytes

Coherence

Photosynthesis

Phycobiliproteins

Biophysics

Electronic Spectroscopy

2D ES

0494

0752

0786

Spectroscopic Investigations of the Photophysics of Cryptophyte Light-harvesting

Dinshaw, Rayomond

21 November 2012

The biological significance of photosynthesis is indisputable as it is necessary for nearly all life on earth. Photosynthesis provides chemical energy for plants, algae, and bacteria, while heterotrophic organisms rely on these species as their ultimate food source. The initial step in photosynthesis requires the absorption of sunlight to create electronic excitations. Light-harvesting proteins play the functional role of capturing solar radiation and transferring the resulting excitation to the reaction centers where it is used to carry out the chemical reactions of photosynthesis. Despite the wide variety of light-harvesting protein structures and arrangements, most light-harvesting proteins are able to utilize the captured solar energy for charge separation with near perfect quantum efficiency. This thesis will focus on understanding the energy transfer dynamics and photophysics of a specific subset of light-harvesting antennae known as phycobiliproteins. These proteins are extracted from cryptophyte algae and are investigated using steady-state and ultrafast spectroscopic techniques.

Ultrafast Spectroscopy

Light-Harvesting

Cryptophytes

Coherence

Photosynthesis

Phycobiliproteins

Biophysics

Electronic Spectroscopy

2D ES

0494

0752

0786

Light Harvesting And Efficient Energy Transfer In Boron Dipyrrin (bodipy) Functionalized Perylene Diimide Dyads

Yilmaz, Mahmut Deniz

01 July 2006

An antenna for light harvesting is an organized multicomponent system in which several chromophoric molecular species absorb the incident light and channel the excitation energy to a common acceptor component. In this study, Click chemistry has been successfully applied in the synthesis of a bay region tetraboron dipyrrin (BODIPY) appended perylenediimide (PDI). This light-harvesting molecule presents a large cross section for the absorption of light in the visible region. Excitation energy is efficiently channeled to the perylenediimide core. This novel antenna system is the first demonstration of the efficiency of energy transfer in a BODIPY- PDI bichromophoric system and appears to be highly promising for the design and synthesis of similar dendritic structures.

QD Organic Chemistry 241-441

Bioinformatics applied to chlorophyll a/b binding proteins in Avena sativa (oat)

Szekeres, Ferenc

January 2003

<p>The chlorophyll a/b binding (CAB) genes play a very central role in all photosynthetic systems and are for Avena sativa (oat) totally unexplored. This dissertation investigates a large number of EST sequences and this investigation characterises the CAB genes in oat, with help from the evolutionary background of oat and the comparison to a reference organism and similar species.</p>

Chlorophyll

Photosynthesis

Chlorophyll a/b binding proteins

Light-harvesting complex

Computer science

Datavetenskap

Decoherence-assisted transport in pigment protein complexes

Sonet Ventosa, Adrià

January 2014

Two chlorophylls of the FMO complex, the light-harvesting complex of the green sulfur bacteria, are modeled as two coupled qubits, each surrounded by one spin-bath simulating the environment. The dynamics of the system at a non-zero temperature provide exact analytical expressions for the transition probability and the coherence. It is shown that the decoherence-inducing interaction with the environment enhances the electronic energy transfer. Also the correlations in terms of entanglement and nonlocality are quantitatively studied, sensitively differing when introducing a decay term to resemble both chlorophylls being in their ground states. It is proved that nonlocality is a stronger form of correlation than entanglement.

Entanglement

concurrence

nonlocality

electronic energy transfer

FMO complex

light-harvesting complex.

Mechanism of photoprotection in photosynthetic proteins / Mechanism of photoprotection in photosynthetic proteins

TRSKOVÁ, Eliška

January 2015

Nonphotochemical quenching is an important protective mechanism of photosynthetic proteins against excessive irradiation. In this work, isolation of native light harvesting antennae from alga Chromera velia was optimized using methods of sucrose density centrifugation, isoelectric focusing, ion exchange chromatography and gel electrophoresis. Moreover, the ability of light harvesting antennae to trigger nonphotochemical quenching was studied in vivo and in vitro.

Role časových škál interakce systém-lázeň ve fotosyntetickém přenosu excitační energie / Role of system-bath interaction time-scales in photosynthetic excitation energy transfer

Malý, Pavel

January 2018

ROLE ASOVÉ 'KÁLY INTERAKCE SYSTÉM-LÁZE VE FOTOSYNTETICKÉM P ENOSU EXCITANÍ ENERGIE Tato práce se věnuje vlivu rychlého a pomalého molekulárno pohybu na přenos excitační energie ve fotosyntetick- ých světlosběrných komplexech. Vyvinuli jsme nový teoretický popis vnitromolekulárních vibračních mod· a zjistili jsme, že jejich resonance s energetickými rozdíly mezi fotosyntetickými pigmenty m·že vést ke zrychlení přenosu energie. Použitím jednomolekulární spektroskopie jsme pozorovali jak pomalé změny bílkovinné konformace mohou zcela změnit stav světlosběrného komplexu LHCII vyšších rostlin. Také jsme vyvinuli novou experimentální techniku, dvoupulzní ultrarychlou jednomolekulární spektroskopii. S její pomocí m·žeme pozorovat jak pomalý pohyb bílkoviny bakteriální antény LH2 ovlivňuje ultrarychlou relaxaci energie uvnitř komplexu. Konstrukcí jednotného modelu pro ultrarychlé objemové a jednomolekulární experimenty se nám podařilo zakomponovat rychlou a pomalou časovou škálu molekulárního pohybu do jednoho pohledu na fotosyntetický sběr světla.

Bioinformatics applied to chlorophyll a/b binding proteins in Avena sativa (oat)

Szekeres, Ferenc

January 2003

The chlorophyll a/b binding (CAB) genes play a very central role in all photosynthetic systems and are for Avena sativa (oat) totally unexplored. This dissertation investigates a large number of EST sequences and this investigation characterises the CAB genes in oat, with help from the evolutionary background of oat and the comparison to a reference organism and similar species.

Chlorophyll

Photosynthesis

Chlorophyll a/b binding proteins

Light-harvesting complex

Computer Sciences

Datavetenskap (datalogi)

Illuminating the ultrafast excited state dynamics of protein-bound carotenoids in plants

Singh, Asmita

January 2017

Global energy demands have escalated over the past few decades, creating a necessity for alternative energy sources. Solar technologies inspired by the primary solar energy storing process known on earth, photosynthesis, have subsequently gained popularity. The natural photosynthetic apparatus comprises a network of membrane-bound pigment-protein complexes, with the main plant light-harvesting complex (LHCII) consisting of chlorophyll (Chl) and carotenoid (Car) pigments. Electronic excitation energy transfer (ET) of the harvested energy takes place amongst these pigments on ultrafast timescales. This energy is funnelled towards a photosynthetic reaction centre where charge separation is achieved, creating a Biobattery, which powers the subsequent manufacture of energy-rich chemical compounds for photosynthetic activity. Transient absorption pump-probe spectroscopy has proven to be a useful technique for monitoring the evolution of the excited state dynamics, such as electronic transitions and excitation ET amongst Car and Chl pigments of LHCII trimers isolated from spinach leaves. This method was utilized to probe samples excited under four different conditions: at pump excitation wavelengths (𝜆𝑒𝑥) of 489 nm (preferentially exciting Cars Lutein1 and Neoxanthin) and 506 nm (targeting Cars Lutein2 and Violaxanthin), each with an intensity of either 800 nJ/pulse (relatively high) or 500 nJ/pulse (comparatively low). A global analysis was applied to each dataset using the robust, open-source Glotaran software, from which three kinetic decay lifetimes for the various processes were extracted. General spectral observations encompassed a negative pump ground state bleach (GSB) at each 𝜆𝑒𝑥; negative Chl b and Chl a GSBs, superimposed with negative stimulated emission (SE) signals; and a positive excited state absorption (ESA) band. The first lifetime of a few picoseconds corresponded mainly to Car-S2 depopulation, resulting either from energy relaxation towards Car-S1, or ET to Chls. Small, but distinct Chl b signals of less than 3 mOD were also detected on this timescale. The second lifetime, which is between 10 and 12 ps, was characteristic to the Lutein Car-S1 lifetime, mainly depicting Car-S1 ET to Chl a. The third lifetime, which extended from ~200 ps to the nanosecond timescale, was attributed to Chl a fluorescence. The 𝜆𝑒𝑥 of 489 nm directly excites the Chl Soret region, whilst excitation at 506 nm shows a pump intensity-dependence. Laser pulse photon density values were ~1014 photons·cm-2·pulse-1 for these datasets. Singlet-singlet annihilation calculations performed on the samples excited at 506 nm provided low annihilation probabilities of 9.0% and 11.5% for a low and high pump intensity, respectively, limiting the possibility of sample photobleaching. Optimization and redevelopment of the experimental setup significantly improved both the data quality and various recorded parameters, concluding that pump-probe spectroscopy was successful on the prepared LHCII trimers. Results acquired and calculations performed correlated with literature, where minimal changes were noticed in the timescales and ET pathways. The robustness of plant systems was confirmed through both excitation-wavelength and intensity dependence. This work paves the way for advanced studies on the role Cars play in non-photochemical quenching (NPQ), a self-protection mechanism of plants against over-illumination; and for the tailoring of artificial light-harvesting antennas based on research conducted on their natural counterparts. / Globale energievereistes het oor die afgelope paar dekades toegeneem, wat die ontwikkeling van alternatiewe energiebronne noodsaaklik maak. Sontegnologieë, geïnspireer deur die primêre sonenergiebergingsproses op aarde, fotosintese, het daarom gewild geword. Die natuurlike fotosintetiese apparaat bestaan uit 'n netwerk van membraangebonde pigment-proteïenkomplekse, met die hoof ligversamelingskompleks in plante (LHCII) wat bestaan uit chlorofil- (Chl) en karotenoïed- (Car) pigmente. Die energie wat deur die pigmente geabsorbeer word, word tussen elektroniese opgewekte toestande op verskillende pigmente op ultravinnige tydskale oorgedra. Hierdie energie word na ʼn fotosintetiese reaksiesentrum gekanaliseer, waar 'n ladingskeiding geïnduseer word en 'n Biobattery sodoende geskep word. Die energie wat in dié battery gestoor is, word gebruik om energieryke chemiese verbindings te vervaardig — wat as brandstof vir die plant dien om sy lewensfunksies te verrig. Tydopgeloste-absorpsie-pomp-tasting-spektroskopie is 'n nuttige tegniek om die dinamika tussen opgewekte toestande te volg. ‘n Voorbeeld van sulke dinamika is die elektroniese opwekking en energie-oordrag tussen die Car- en Chl-pigmente van geïsoleerde LHCII-trimere in spinasieblare. Hierdie metode is gebruik om monsters onder vier verskillende toestande te ondersoek by pompgolflengtes (𝜆𝑒𝑥) van 489 nm (waar hoofsaaklik die Cars Luteïne1 en Neoksantine opgewek word) en 506 nm (vir Cars Luteïne2 en Violaksantine), en pompenergieë van ‘n relatief hoë 800 nJ/puls, of 500 nJ/puls vir elke golflengte. / Dissertation (MSc)--University of Pretoria, 2017. / National Research Foundation (NRF) / Physics / MSc / Unrestricted

Photosynthetic Light-Harvesting

LHCII trimers

Pump-Probe Spectroscopy

Transient Absorption Spectroscopy

Carotenoids

UCTD