In vitro studies on potential mechanisms of absorption enhancement by Hydroxybenzoates

Huson, A. J.

January 1988

No description available.

615.1

Drug absorption enhancement

Synergistic photon absorption enhancement in nanostructured molecular assemblies

Gao, Ting-fong

30 July 2012

Molecular photoabsorption enhancement under ambient solar radiations can improve efficiency substantially in renewable energy production. Here, we explore the theoretical basis and experimental evidences that nanostructured molecular assemblies exhibit an unprecedented property of synergistic photon absorption enhancement. The molecular mechanism of this enhancement phenomenon originates from the combined effect of the photon-molecule interaction and the electronic energy transfer between two adjacent molecular assemblies. For a natural system, the synergistic photon absorption enhancement factor of green algae (Chlorella vulgaris) in vivo at 632.8 nm was determined to be 103. This enhanced photon absorption process in nanostructured molecular assemblies opens a doorway to create entangled double excitons by incoherent solar radiations.

electronic energy transfer

molecular assemblies

double exciton

nanostructure

renewable energy

quantum entanglement

Design and evaluation of chitosan and N-trimethyl chitosan chloride microspheres for intestinal drug delivery / Johannes Petrus Venter

Venter, Johannes Petrus

January 2005

The absorption enhancing ability of chitosan, a linear polysaccharide, is mediated by protonated amino groups on the C-2 position of the molecules that induce interaction with the anionic sites on the cell membranes to subsequently alter tight junction integrity. In neutral and basic environments, such as those found in the small and large intestines, most chitosan molecules will lose their charge and precipitate from solution rendering it ineffective as an absorption enhancer. To increase the solubility of this polymer, methylation of the amino groups on the C- 2 position was proposed. A partially quaternised and water soluble derivative of chitosan, N-trimethyl chitosan chloride (TMC), which exhibits superior solubility in a basic environment compared with other chitosan salts was synthesised and included in a chitosan microbead solid drug delivery system. Two TMC derivatives were synthesised by reductive methylation from high and medium molecular weight Chitoclear™ chitosan respectively. The degree of quaternisation calculated from the 1H-NMR spectra for the medium molecular weight TMC (TMC-M) and the high molecular weight TMC (TMC-H) polymers were 74.7 % and 48.5 % respectively. The mean molecular weights of the synthesised TMC-M and TMC-H polymers were 64 100 g/mole and 233 700 g/mole respectively. The effect of different concentrations TMC-M and TMC-H on chitosan microbeads was studied with results obtained from scanning electron microscopy (SEM), TMC loading capacity and microbead swelling behaviour. After selection of the most suitable TMC concentration, the effect of varying concentration (0.1, 0.2 and 0.5 %) additives on TMC and ibuprofen release was studied. Commonly used modified cellulose gum (Ac-di-sol®(ADS)), sodium starch glycolate (Explotab®(EXP)) and ascorbic acid (AA) were added as disintegrants to different microbead formulations to promote release of both the ibuprofen as model drug and TMC from the beads. It was noticed that the loading (% drug loading capacity) of TMC-M was much lower than that obtained with TMC-H while the inclusion of different additives in varying concentrations did not seem to have a profound influence on the loading of either TMC-M or TMC-H. It was further noticed from the fit factors (f1 and f2) for dissolution profiles of eighteen chitosan microbead variations that the formulation containing TMC-H and 0.5% (w/v) ascorbic acid was the only formulation with a significantly higher ibuprofen and TMC-H release profile compared to all other formulations tested. The chitosan microbead formulation containing 2%(w/v) TMC-H and 0.5 % (w/v) ascorbic acid (H-AA-0.5) was used for in vitro absorption studies through rat intestine in Sweetana-Grass diffusion chambers. Chitosan containing TMC-H (no ascorbic acid) (CHIT-H) only and a plain chitosan microbead (CHIT) formulation was used as control formulations during the in vitro studies. Although the H-AA-0.5 formulation exhibited the highest transport rate for ibuprofen, the mean rate of transport (P app) obtained from the two formulations containing TMCH (CHIT-H and H-AA-0.5) showed no significant difference in the transport rate of ibuprofen. Compared to the CHlT formulation as control, both formulations containing TMC-H exhibited increased ibuprofen transport across in vitro rat jejunum. However, a statistical significant increase in transport was obtained only from the H-AA-0.5 formulation in comparison with the CHlT formulation. It can be concluded that the combination of high molecular weight TMC with a low degree of quaternisation and ascorbic acid (0.5% w/v) in a chitosan microbead lead to a statistical significant increase in the in vitro transport rate of ibuprofen through rat jejunum. / Thesis (Ph.D. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2006.

Absorption enhancement

Quaternised chitosan

Mucoadhesion

Microbeads

Ibuprofen

Sweetana-Grass diffusion chambers

Design and evaluation of chitosan and N-trimethyl chitosan chloride microspheres for intestinal drug delivery / Johannes Petrus Venter

Venter, Johannes Petrus

January 2005

The absorption enhancing ability of chitosan, a linear polysaccharide, is mediated by protonated amino groups on the C-2 position of the molecules that induce interaction with the anionic sites on the cell membranes to subsequently alter tight junction integrity. In neutral and basic environments, such as those found in the small and large intestines, most chitosan molecules will lose their charge and precipitate from solution rendering it ineffective as an absorption enhancer. To increase the solubility of this polymer, methylation of the amino groups on the C- 2 position was proposed. A partially quaternised and water soluble derivative of chitosan, N-trimethyl chitosan chloride (TMC), which exhibits superior solubility in a basic environment compared with other chitosan salts was synthesised and included in a chitosan microbead solid drug delivery system. Two TMC derivatives were synthesised by reductive methylation from high and medium molecular weight Chitoclear™ chitosan respectively. The degree of quaternisation calculated from the 1H-NMR spectra for the medium molecular weight TMC (TMC-M) and the high molecular weight TMC (TMC-H) polymers were 74.7 % and 48.5 % respectively. The mean molecular weights of the synthesised TMC-M and TMC-H polymers were 64 100 g/mole and 233 700 g/mole respectively. The effect of different concentrations TMC-M and TMC-H on chitosan microbeads was studied with results obtained from scanning electron microscopy (SEM), TMC loading capacity and microbead swelling behaviour. After selection of the most suitable TMC concentration, the effect of varying concentration (0.1, 0.2 and 0.5 %) additives on TMC and ibuprofen release was studied. Commonly used modified cellulose gum (Ac-di-sol®(ADS)), sodium starch glycolate (Explotab®(EXP)) and ascorbic acid (AA) were added as disintegrants to different microbead formulations to promote release of both the ibuprofen as model drug and TMC from the beads. It was noticed that the loading (% drug loading capacity) of TMC-M was much lower than that obtained with TMC-H while the inclusion of different additives in varying concentrations did not seem to have a profound influence on the loading of either TMC-M or TMC-H. It was further noticed from the fit factors (f1 and f2) for dissolution profiles of eighteen chitosan microbead variations that the formulation containing TMC-H and 0.5% (w/v) ascorbic acid was the only formulation with a significantly higher ibuprofen and TMC-H release profile compared to all other formulations tested. The chitosan microbead formulation containing 2%(w/v) TMC-H and 0.5 % (w/v) ascorbic acid (H-AA-0.5) was used for in vitro absorption studies through rat intestine in Sweetana-Grass diffusion chambers. Chitosan containing TMC-H (no ascorbic acid) (CHIT-H) only and a plain chitosan microbead (CHIT) formulation was used as control formulations during the in vitro studies. Although the H-AA-0.5 formulation exhibited the highest transport rate for ibuprofen, the mean rate of transport (P app) obtained from the two formulations containing TMCH (CHIT-H and H-AA-0.5) showed no significant difference in the transport rate of ibuprofen. Compared to the CHlT formulation as control, both formulations containing TMC-H exhibited increased ibuprofen transport across in vitro rat jejunum. However, a statistical significant increase in transport was obtained only from the H-AA-0.5 formulation in comparison with the CHlT formulation. It can be concluded that the combination of high molecular weight TMC with a low degree of quaternisation and ascorbic acid (0.5% w/v) in a chitosan microbead lead to a statistical significant increase in the in vitro transport rate of ibuprofen through rat jejunum. / Thesis (Ph.D. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2006.

Absorption enhancement

Quaternised chitosan

Mucoadhesion

Microbeads

Ibuprofen

Sweetana-Grass diffusion chambers

SYNTHESIS AND OPTICAL PROPERTIES OF ULTRAFINE METAL NANOPARTICLES ON DIELECTRIC ANTENNA PARTICLES

Wei, Qilin, 0000-0003-1729-1951

January 2022

Effective light energy conversion into other forms of energy in metal and metal compound nanoparticles has been of great interest in past decades. Being illuminated by incident light, electrons in the nanoparticles can be excited to higher energy states followed by deposition of energy into other molecules around their surface and the lattices in the following relaxation process. Ultrafine nanoparticles are thus preferred in these processes due to their high specific surface areas. Moreover, the portion of excited electrons with higher energies is higher in smaller nanoparticles than in larger ones. However, the overall light power absorbed by nanoparticles is proportional to the square of particle size, which causes the ultrafine nanoparticles not to efficiently absorb the incident light, or to drive further chemical or physical processes.Light antennae materials are usually employed to enhance the light absorption of these ultrafine nanoparticles. Plasmonic nanoparticles, e.g., Ag, Au, Cu, and Al nanoparticles, enhance the light absorption of loaded nanoparticles mainly through strong electromagnetic fields generated near their surfaces and have been proven to be effective light antennae to benefit the light energy conversion of ultrafine nanoparticles. On the other hand, spherical dielectric particles, e.g., silicon dioxide nanospheres, represent a different type of light antennae with the advantages of low cost, simple synthesis, and negligible Ohmic loss when being illuminated. When the sizes of high geometric symmetry dielectric nanospheres are comparable with the wavelength of the incident light, Mie scattering can happen based on the difference in refractive index between the sphere and the surrounding medium, generating size-dependent scattering resonances at various wavelengths. At these wavelengths, strong electric fields can be created on the surface of dielectric spheres to enhance the light absorption of the nanoparticles loaded on the surface. Previous works have shown that silica nanospheres with a diameter of several hundreds of nanometers can effectively enhance the light absorption of ultrafine Pt nanoparticles and benefit photocatalytic reactions, e.g., selective oxidation of benzyl alcohol. Over the past few years, this concept has been broadened to other ultrafine nanoparticles to study their novel photo-to-chemical/physical properties. However, the availability and comprehensive understanding of the optical properties of this class of composite particles still need to be improved. These challenges limit the further development of these composite materials in new light energy conversion processes. This dissertation aims at studying this class of novel ultrafine nanoparticles/dielectric sphere composite particles synthesis and optical properties. In Chapter 2, a synthesis protocol of ultrafine ruthenium oxyhydroxide nanoparticles on the surface of silica nanospheres’ surfaces is introduced. Unlike the traditional synthesis of nanoparticles in solution followed by a loading process, the method developed in this chapter only requires the injection of aqueous ruthenium salt solution into a silica nanosphere dispersion. The obtained ultrafine nanoparticles with sizes of 2-3 nm are characterized to be ruthenium oxyhydroxide (RuOOH) nanoparticles. The silica nanospheres are crucial in stabilizing these ultrafine RuOOH nanoparticles and enhancing their light absorption. Due to the presence of ruthenium-oxygen bonds in the nanoparticles, the absorbed photons are converted to heat and transferred to the surrounding media with a photo-to-thermal conversion efficiency close to the unity. Experimental results have shown that heat can be effectively used in accelerating the reaction rate of selective oxidation of benzyl alcohol by molecular oxygen. Kinetics data also have shown that these ultrafine RuOOH nanoparticles are able to activate molecular oxygen adsorbed on their surfaces, which represents a novel property of these ultrafine RuOOH nanoparticles that is not observed in other traditional ruthenium catalysts. In Chapter 3, a more general synthesis method of ultrafine metal and metal oxyhydroxide nanoparticles on silica nanospheres is developed, inspired by the synthetic route in Chapter 2. Instead of functionalizing silica surfaces with silane agents with amino groups, the silica surfaces are selectively etched by an aqueous base to create a high density of surface hydroxyl groups. These hydroxyl groups can provide basic sites to stabilize metal ions in aqueous dispersion, which are nuclei for the further growth of larger metal oxyhydroxide nanoparticles. In this chapter, more than ten kinds of metal ions are loaded onto silica spheres, forming oxyhydroxide nanoparticles with average sizes below 5 nm. Some oxyhydroxide nanoparticles can be reduced by 5% H2/N2 to form metal nanoparticles with their ultrafine sizes maintained. The synthesis protocol is promising in preparation of bimetallic samples. The composition and optical absorption of all obtained composite particles are analyzed, demonstrating the practicability of utilizing the reported method to prepare high-quality light-absorbing composite particles. In Chapter 4, the optical absorption property of the composite particle is systematically studied. Using ultrafine Pt nanoparticles as the light absorbing material, the light absorptions of composite particles consisting of silica spheres with diameters from 100 to 1100 nm loaded with these Pt nanoparticles are studied. Through the combination of theoretical calculation based on Mie theory and the measured optical absorption spectra, the scattering resonance peaks are successfully located in each sample. It is also found that the photonic crystal effect and the general absorption of Pt nanoparticles can contribute to the light absorption spectra, especially at higher wavelengths. The relationship between the general absorption of Pt nanoparticles and the packing density of the powder is further studied. The successful deconvolution of several components in the absorption spectra can guide the further rational design of composite particles in optical-related applications. In Chapter 5, the composite particle system is further broadened to using high refractive index zinc sulfide nanospheres as a light antenna. The use of a higher refractive index light antenna is promising for obtaining higher light absorption enhancement in loaded ultrafine nanoparticles, even though the sample is dispersed in organic media with a high refractive index as well. After the successful loading of Pt nanoparticles to the surface of silica-coated zinc sulfide nanospheres, a protocol for analyzing their light absorption spectra in organic media is proposed. Size-dependent scattering resonance peaks are observed in bare zinc sulfide nanospheres and can be utilized to enhance the light absorption of Pt nanoparticles, even when the sample is sealed in high refractive index polymeric matrices. The composite particles are further employed in photothermal tests, the results prove that the better light absorption enhancement using zinc sulfide than silica nanospheres. The results introduced in this dissertation represent the first systematic and comprehensive study of ultrafine metal and metal oxyhydroxide nanoparticles loaded on the surface of dielectric light antenna particles. The conclusions open an avenue to further rational design of high-performance light-absorbing composite particles to be used in photo-to-thermal/chemical processes. / Chemistry

Chemistry

Absorption enhancement

Dielectric antenna

Light absorption

Metal nanoparticle synthesis

Optical properties

Silica spheres

Investigation of Optical Properties of Size-Selected Black Carbon Under Controlled Laboratory Conditions

Lei, Ziying

January 2016

No description available.

Environmental Engineering

Environmental Science

Environmental Studies

Plasmonic properties of subwavelength structures and their applications in optical devices

Wang, Wei, 1983 July 24-

09 February 2011

A metallic hole array of a rectangular converging-diverging channel (RCDC) shape exhibits extraordinary transmission for wavelengths larger than the periodicity of the holes. We use a three-dimensional (3D) finite element method to analyze the transmission characteristics of two-dimensional metallic hole arrays (2D-MHA) with RCDC. For a straight channel MHA, when the aperture size is reduced, the transmission peaks have a blue-shift. The same result is observed for a smaller gap throat for the RCDC structure. For the rectangular holes with a high length-width ratio, a similar blue-shift in the transmission peaks as well as a narrower full width at half maximum (FWHM) are observed. The asymmetry from the rectangular shape gives this structure high selectivity for light with different polarizations. Furthermore, the RCDC shape gives extra degrees of geometrical variables to 2D-MHA for tuning the location of the transmission peak and the FWHM. Tunable extraordinary transmission via changing temperature of a porous metallic layer on top of a thin layer of dielectric strontium titanate (STO) is then studied. The metallic layer has a through-hole array and each hole has a circular converging-diverging channel (CDC) shape, which induces the excitation of surface plasmon polaritons (SPPs) and then results in a controllable extraordinary optical transmission in the terahertz (THz) frequency range. We use a three-dimensional (3D) finite element method to analyze the transmission characteristics of the structure. Location and magnitude of the transmission peaks can be adjusted by the hole size, converging angle, and thicknesses of metal and STO layers. Remarkably, the suggested structure presents a strong transmission dependency on temperature, which offers a new approach to actively and externally tune the transmission. Currently, the performances of thin film solar cells are limited by poor light absorption and carrier collection. In this research, large, broadband, and polarization-insensitive light absorption enhancement is realized via integrating with unique metallic nanogratings. Through simulation, three possible mechanisms are identified to be responsible for such an enormous enhancement. A test for totaling the absorption over the solar spectrum shows an up to ~30% broadband absorption enhancement when comparing to bare thin film cells. Overall performance of a thin film solar cell is determined by the efficiency of conversing photons to electrons that include light absorption, carrier generation and carrier collection processes. Photon management via hybrid designing has been emerging as a powerful means to further boost the conversion efficiency. Here a new nanograting solar cell design, which can be universal and a new solar cell platform technology, is proposed with goals to achieve large enhancement on broadband light absorption and carrier generation, most importantly, under the much reduced usage of active and non-earth-abundant materials. A test for the short circuit current density in CuIn[subscript x]Ga([subscript 1-x])Se₂ (CIGS) thin film solar cells shows an up to ~250% enhancement when comparing to the corresponding bare thin film cells. Besides that, by placing metal strips on top of the nanograting, which act as the top electrode, this design is able to reduce the use of non-earth-abundant materials such as indium that is normally used in both active and transparent conducting materials. / text

Plasmonic

Subwavelength structures

Optical devices

Extraordinary optical transmission

Thin film solar cell

Absorption enhancement

Extraordinary transmission

Metallic hole arrays

Nano-optics

The behaviour of rollover protective structures subjected to static and dynamic loading conditions

Clark, Brian

January 2005

The Rollover of heavy vehicles operating in the construction, mining and agricultural sectors is a common occurrence that may result in death or severe injury for the vehicle occupants. Safety frames called ROPS (Rollover Protective Structures) that enclose the vehicle cabin, have been used by heavy vehicle manufacturers to provide protection to vehicle occupants during rollover accidents. The design of a ROPS requires that a dual criteria be fulfilled that ensures that the ROPS has sufficient stiffness to offer protection, whilst possessing an appropriate level of flexibility to absorb some or most of the impact energy during a roll. Over the last four decades significant research has been performed on these types of safety devices which has resulted in the generation of performance standards that may be used to assess the adequacy of a ROPS design for a particular vehicle type. At present these performance standards require that destructive full scale testing methods be used to assess the adequacy of a ROPS. This method of ROPS certification can be extremely expensive given the size and weight of many vehicles that operate in these sectors. The use of analytical methods to assess the performance of a ROPS is currently prohibited by these standards. Reasons for this are attributed to a lack of available fundamental research information on the nonlinear inelastic response of safety frame structures such as this. The main aim of this project was to therefore generate fundamental research information on the nonlinear response behaviour of ROPS subjected to both static and dynamic loading conditions that could be used to contribute towards the development of an efficient analytical design procedure that may lessen the need for destructive full scale testing. In addition to this, the project also aspired to develop methods for promoting increased levels of operator safety during vehicle rollover through enhancing the level of energy absorbed by the ROPS. The methods used to fulfil these aims involved the implementation of an extensive analytical modelling program using Finite Element Analysis (FEA) in association with a detailed experimental testing program. From these studies comprehensive research information was developed on both the dynamic impact response and energy absorption capabilities of these types of structures. The established finite element models were then used to extend the investigation further and to carry out parametric studies. Important parameters such as ROPS post stiffness, rollslope inclination and impact duration were identified and their effects quantified. The final stage of the project examined the enhancement of the energy absorption capabilities of a ROPS through the incorporation of a supplementary energy absorbing device within the frame work of the ROPS. The device that was chosen for numerical evaluation was a thin walled tapered tube known as frusta that was designed to crush under a sidewards rollover and hence lessen the energy absorption demand placed upon the ROPS. The inclusion of this device was found to be beneficial in absorbing energy and enhancing the level of safety afforded to the vehicle occupants.

Rollover Protective Structures

ROPS

Safety

Occupant protection

Impact

Energy absorption

Destructive testing

Dynamic loading

Impulse loads

Finite Element Analysis (FEA)

Energy Absorption Enhancement

Estimation multi-annuelle des sources d’aérosols organiques et de leurs propriétés d’absorption de la lumière en région Parisienne / Multi-year source apportionment of organic aerosols and their impacts on aerosol light absorption in the Paris region, France

Zhang, Yunjiang

01 February 2019

Les aérosols carbonés, qui incluent les aérosols organiques (AO) et le carbone suie (BC), jouent un rôle majeur sur la qualité de l’air et sur le climat. Il est donc primordial de pouvoir quantifier leurs sources, ainsi que celles de leurs précurseurs gazeux, pour la mise en œuvre de plans d’action appropriés. Les études de tendance sur la composition chimique de l’atmosphère sont également nécessaires afin d’améliorer les connaissances de l’impact des particules sur le réchauffement climatique, actuel et à venir. Ce travail de thèse a permis d’exploiter les mesures automatiques et in situ des aérosols carbonés réalisées au SIRTA (Site de Recherche par Télédétection Atmosphérique) depuis plus de 6 ans. Cet observatoire appartient au programme européen ACTRIS (infrastructure de recherche européenne sur les aérosols, nuages, et espèces gazeuses réactives). Il est situé à 25 km au sud-ouest de Paris et est représentatif de la pollution de fond en région Ile de France. Les principales sources d’AO ont été discriminées à l’aide de l’outil Positive Matrix Factorization appliqué aux données issus d’un Aerosol Chemical Speciation Monitor (ACSM). Les propriétés d’absorption de la lumière de BC et du brown carbon (BrC) ont été mesurées à l’aide d’un aethalomètre multi-longueurs d’onde. L’ensemble des résultats obtenus indiquent des cycles saisonniers, hebdomadaires et journaliers spécifiques aux différentes fractions des aérosols primaires et secondaires. Ils ont confirmé que l’AO primaire (AOP), provenant essentiellement de la combustion de biomasse et du transport routier, est prépondérant sur la période froide (de novembre à février), alors que le reste de l’année est dominé par des aérosols organiques oxygénés. Parmi ces derniers, une fraction moins oxydée, provenant probablement de façon majeure de précurseurs biogéniques, est prépondérante en été (60% de l’AO en moyenne estivale). Les études de tendance ont montré une légère diminution des concentrations (de l’ordre de 0.05-0.20 µg/m3 par an) de toutes les fractions d’AO identifiées au cours de la période étudiée, hormis pour cette fraction d’AO moins oxydée qui ne présente pas de tendance significative. Concernant les propriétés optiques, une contribution moyenne globalement équivalente à celle de BC a été observée pour le BrC dans le proche ultraviolet en hiver. Par ailleurs, il a été mis en évidence une augmentation significative des propriétés d’absorption du BC liée à des interactions avec les aérosols secondaires en mélange interne, en particulier en été (avec une valeur moyenne de 1.6 pour le paramètre Eabs). La fraction organique la plus oxydée a pu être identifiée comme principale responsable de ce phénomène, faisant des aérosols organiques secondaires l’une des fractions des particules les plus importants à considérer par les modèles climatiques. / Carbonaceous aerosols, including organic aerosols (OA) and black carbon (BC), are playing important roles on air quality and climate change. Therefore, quantifying contribution of their emission sources, as well as the sources of their gaseous precursors, is needed to implement efficient mitigation measures. Investigating trends in atmospheric composition is also essential to a better knowledge of present and future impacts of airborne particles on global warming. This work aimed at investigating on-line and in situ carbonaceous aerosol measurements performed for more than 6 years at the SIRTA facility (Site Instrumental de Recherche par Télédétection Atmosphérique). This observatory platform is part of the ACTRIS (Aerosols, Clouds, Trace gases Research InfraStructure). It is located 25 km southwest of Paris city center and is representative of background air quality in the Ile de France region. The main sources of submicron OA were discriminated through Positive Matrix Factorization applied to Aerosol Chemical Speciation Monitor (ACSM) data. Light absorption properties of BC and brown carbon (BrC) were obtained from multi-wavelength Aethalometer measurements. Converging results illustrated well-marked seasonal, weekly, and diel cycles of the various primary and secondary carbonaceous aerosol fractions. Primary OA (POA), mainly from wood burning and traffic emissions, were confirmed to dominate submicron OA concentrations during the coldest months (November to February), while Oxygenated OA (OOA) were shown as the major contributors during the rest of the year. Less Oxidized OOA (LO-OOA), possibly with predominant biogenic origins, were found to contribute up to about 60% of total submicron OA on average in summer. Trend analyses indicated slight decreasing features (in the range of 0.05-0.20 µg m-3 yr-1) for every OA fractions over the 6+-year investigated period, except for this LO-OOA factor which showed no significant trend. Regarding absorption properties, BrC - with overwhelming biomass burning origin - was found to have equivalent light absorption impact than BC at near-ultraviolet wavelengths during the winter season. In summer, a mean value of 1.6 was obtained for BC absorption enhancement (Eabs) due to secondary aerosol lensing effect, supporting possible higher BC-related radiative impact than currently expected. Last but not least, More Oxidized OOA (MO-OOA) were shown as the main agent for this Eabs and then appeared as one of the most critical aerosol fraction to be considered within near-future climate models.

Qualité de l’air

Aérosols organiques

Carbone suie

Sources

Tendances

Absorption de la lumière

Air quality

Organic aerosols

Black carbon

Sources

Trends

Absorption enhancement

551.51