143 research outputs found
Lactation Persistency in Bulgarian Murrah Buffalo Cows
With the objective to establish the lactation persistency and its variability as affected by different factors, the study assigned 953 lactations of 310 Bulgarian Murrah buffalo cows bred on the farm of Agricultural Institute â Shumen within the period 1967-2009. The main method of measurement was the mean post-peak milk yield reduction. The data were processed by the conventional statistical procedure, as well as by the software products LSMLMW and MIXMDL. The persistency of milk yield after reaching peak was established to be relatively high (89.22%). Its variance is to a great extent explained by the factors days in milk (P<0.001) and parity (P<0.001), defining favorable effect of increased lactation length, and adverse effect of advancement in lactation order. The significant effect of season of calving (P<0.001) is expressed in higher lactation persistency in the autumn and winter calvers. The other environmental factor, period, and the genetic factor (individual) are significant at P<0.01, while the effect of productivity level is not. The portion of the peak yield was estimated to be 15.75% of the lactation productivity, the percentage of the greatest yield drop â 11.38%, the persistency ratio between the first and second lactation half â 73.60%
Eicosapentaenoic acid provokes stronger in vitro antiadipogenic effect than docosahexaenoic acid in differentiated 3T3-L1 cells
The comparative studies of eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) effects on the amount of lipid droplets (LD) and within adipocytes are limited. In this study, 3T3-L1 mouse embryo fibroblasts (ATCCÂź CL-173âą) were expanded up to fifth passage. At the stage of growth arrest, the cells were treated with EPA and DHA separately and in combination at 100 ÎŒg/mL for 2 days. Oil Red O staining protocol, subsequent extraction with isopropanol and spectrophotometric determination of absorbed dye were used to establish the amount of intracellular lipid droplets depo-sition. While DHA administration had no significant effect on reduction of LD intracellular deposi-tion, the EPA treatment decreased optical density (OD) significantly (P<0.05). Furthermore, a syner-gic effect of combined application of both PUFAs was not observed. In conclusion, EPA provoked stronger antiadipogenic effect than DHA suggesting that EPA administration would be more effective in already existing obesity
Durability and wear resistance of laser-textured hardened stainless steel surfaces with hydrophobic properties
Hydrophobic surfaces
are of high interest to industry. While surface functionalization
has attracted significant interest, from both industry and research,
the durability of engineered surfaces remains a challenge, as wear
and scratches deteriorate their functional response. In this work,
a cost-effective combination of surface engineering processes on stainless
steel was investigated. Low-temperature plasma surface alloying was
applied to increase surface hardness from 172 to 305 HV. Then, near-infrared
nanosecond laser patterning was deployed to fabricate channel-like
patterns that enabled superhydrophobicity. Abrasion tests were carried
out to examine the durability of such engineered surfaces during daily
use. In particular, the evolution of surface topographies, chemical
composition, and water contact angle with increasing abrasion cycles
were studied. Hydrophobicity deteriorated progressively on both hardened
and raw stainless steel samples, suggesting that the major contributing
factor to hydrophobicity was the surface chemical composition. At
the same time, samples with increased surface hardness exhibited a
slower deterioration of their topographies when compared with nontreated
surfaces. A conclusion is made about the durability of laser-textured
hardened stainless steel surfaces produced by applying the proposed
combined surface engineering approach
Lotus-leaf inspired surfaces: hydrophobicity evolution of replicas due to mechanical cleaning and mold wear
YesInspired from the low wetting properties of Lotus leaves, the fabrication of dual micro/nano-scale topographies is of interest to many applications. In this research, superhydrophobic surfaces are fabricated by a process chain combining ultrashort pulsed laser texturing of steel inserts and injection moulding to produce textured polypropylene parts. This manufacturing route is very promising and could be economically viable for mass production of polymeric parts with superhydrophobic properties. However, surface damages, such as wear and abrasion phenomena, can be detrimental to the attractive wetting properties of replicated textured surfaces. Therefore, the final product lifespan is investigated by employing mechanical cleaning of textured polypropylene surfaces with multipurpose cloths following the ASTM D3450 standard. Secondly, the surface damage of replication masters after 350 injection moulding cycles with glass-fiber reinforced polypropylene, especially to intensify mould wear, was investigated. In both cases, the degradation of the dual-scale surface textures had a clear impact on surface topography of the replicas and thus on their wetting properties, too.Europe Union H2020 research and innovation programme
Symmetry and finite-size effects in quasi-optical extraordinarily THz transmitting arrays of tilted slots
Extraordinarily transmitting arrays are promising candidates for quasi-optical (QO) components due to their high frequency selectivity and beam scanning capabilities owing to the leaky-wave mechanism involved. We show here how by breaking certain unit cell and lattice symmetries, one can achieve a rich family of transmission resonances associated with the leaky-wave dispersion along the surface of the array. By combining 2-D and 1-D periodic method of moments (MoM) calculations with QO terahertz (THz) time-domain measurements, we provide physical insights, numerical, and experimental demonstration of the different mechanisms involved in the resonances associated with the extraordinary transmission peaks and how these evolve with the number of slots. Thanks to the THz instrument used, we are also able to explore the time-dependent emission of the different frequency components involved
Laser polishing of 3D printed mesoscale components
Laser polishing of various engineered materials such as glass, silica, steel, nickel and titanium alloys, has attracted considerable interest in the last 20 years due to its superior flexibility, operating speed and capability for localised surface treatment compared to conventional mechanical based methods. The paper initially reports results from process optimisation experiments aimed at investigating the influence of laser fluence and pulse overlap parameters on resulting workpiece surface roughness following laser polishing of planar 3D printed stainless steel (SS316L) specimens. A maximum reduction in roughness of over 94% (from âŒ3.8 to âŒ0.2 ÎŒm Sa) was achieved at the optimised settings (fluence of 9 J/cm2 and overlap factors of 95% and 88â91% along beam scanning and step-over directions respectively). Subsequent analysis using both X-ray photoelectron spectroscopy (XPS) and glow discharge optical emission spectroscopy (GDOES) confirmed the presence of surface oxide layers (predominantly consisting of Fe and Cr phases) up to a depth of âŒ0.5 ÎŒm when laser polishing was performed under normal atmospheric conditions. Conversely, formation of oxide layers was negligible when operating in an inert argon gas environment. The microhardness of the polished specimens was primarily influenced by the input thermal energy, with greater sub-surface hardness (up to âŒ60%) recorded in the samples processed with higher energy density. Additionally, all of the polished surfaces were free of the scratch marks, pits, holes, lumps and irregularities that were prevalent on the as-received stainless steel samples. The optimised laser polishing technology was consequently implemented for serial finishing of structured 3D printed mesoscale SS316L components. This led to substantial reductions in areal Sa and St parameters by 75% (0.489â0.126 ÎŒm) and 90% (17.71â1.21 ÎŒm) respectively, without compromising the geometrical accuracy of the native 3D printed samples
NLO properties of new stryquinolinium dye thin films deposited by pulsed laser deposition
International audienc
Large nonlinear optical properties of new styrylquinolinium dye thin films deposited by pulsed laser deposition
Date du colloque : 09/2011</p
Effects of mould wear on hydrophobic polymer surfaces replicated using plasma treated and laser-textured stainless steel inserts
YesThe mass production of polymeric parts with functional surfaces requires economically viable manufacturing routes. Injection moulding is a very attractive option however wear and surface damage can be detrimental to the lifespan of replication masters. In this research, the replication of superhydrophobic surfaces is investigated by employing a process chain that integrates surface hardening, laser texturing and injection moulding. Austenitic stainless steel inserts were hardened by low temperature plasma carburising and three different micro and nano scale surface textures were laser fabricated, i.e. submicron triangular LaserInduced Periodic Surface Structures (LIPSS), micro grooves and Lotus-leaf like topographies. Then, a commonly available talc-loaded polypropylene was used to produce 5000 replicas to investigate the evolution of surface textures on both inserts and replicas together with their functional response. Any wear orsurface damage progressively built up on the inserts during the injection moulding process had a clear impact on surface roughness and peak-to-peak topographies of the replicas. In general, the polymer replicas produced with the carburised inserts retained the wetting properties of their textured surfaces for longer periods compared with those produced with untreated replication masters.European Unionâs H2020 research and innovation programme under the Marie SkĆodowska-Curie grant agreement No. 675063 (www.laser4fun.eu). The work was also supported by three other H2020 projects, i.e. âHighImpact Injection Moulding Platform for mass-production of 3D and/or large micro-structured surfaces with Antimicrobial, Self-cleaning, Anti-scratch, Anti-squeak and Aesthetic functionalitiesâ (HIMALAIA, No. 766871), âProcess Fingerprint for Zero-defect Net-shape Micromanufacturingâ (MICROMAN, No. 674801) and âModular laser based additive manufacturing platform for large scale industrial applicationsâ (MAESTRO, No. 723826). Further support was provided by the UKIERI DST programme âSurface functionalisation for 18/20 Accepted in the journal Tribology â Materials, Surfaces & Interfaces. food, packaging, and healthcare applications
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