Termofil rötning av drankvatten

Wiberg, Heli

January 2007

<p>Biogasprocessen är en komplex anaerob nedbrytningskedja där olika mikroorganismer är inblandade. Vanligast är att biogas produceras i mesofil rötning (cirka 38 ^oC), men även termofil rötning används (> 50 ^oC).</p><p>Svensk Biogas i Norrköping använder återstoden av etanoldestillationen hos en närliggande etanolproducent (drankvatten) som substrat. Substratets höga temperatur vid leverans motiverar termofilt rötningsförsök av drankvatten.</p><p>Försöket genomfördes i 55 ^oC med två kontinuerligt omrörda tankreaktorer (CSTR) och en termofil ymp. Biogasproduktion av drankvatten undersöktes. Sätt att hantera och motverka höga ammoniumhalter, samt effekter av näringslösningstillsats undersöktes. Det tog cirka 30 dagar för ympen att acceptera det nya substratet och då hade tillsats av processhjälpmedel KMB1 samt järnklorid använts. Reaktorerna kunde belastas med 3 g VS / (L • dygn) (VS, volatile solids, glödförlust). Den specifika gasproduktionen var 0,6 – 0,7 L / g VS och metanhalten ungefär 45 %. Höga ammoniumhalter motverkades genom förkortning av uppehållstiden. Under en period tillsattes nickelklorid i en av reaktorerna och under denna period hade reaktorn med nickelkloridtillsats något bättre specifik gasproduktion jämfört med reaktorn där ingen nickelklorid tillsattes.</p><p>Drankvatten kan rötas under termofila förhållanden. För att temperaturförändring vid biogasanläggningen i Norrköping ska var ekonomiskt försvarbart måste processen klara högre belastning.</p>

Biogas

termofil rötning

metan

destillationsåterstod

drankvatten

ammonium

nickel

Microbiology

Mikrobiologi

Fabrication of Highly Ordered Nanoparticle Arrays Using Thin Porous Alumina Masks

Lei, Y., Teo, L.W., Yeong, K.S., See, Y.H., Chim, Wai Kin, Choi, Wee Kiong, Thong, J.T.L.

01 1900

Highly ordered nanoparticle arrays have been successfully fabricated by our group recently using ultra-thin porous alumina membranes as masks in the evaporation process. The sizes of the nanoparticles can be adjusted from 5-10 nm to 200 nm while the spacing between adjacent particles can also be adjusted from several nanometers to about twice the size of a nanoparticle. The configuration of the nanoparticles can be adjusted by changing the height of the alumina masks and the evaporation direction. Due to the high pore regularity and good controllability of the particle size and spacing, this method is useful for the ordered growth of nanocrystals. Different kinds of nanoparticle arrays have been prepared on silicon wafer including semiconductors (e.g., germanium) and metals (e.g., nickel). The germanium nanoparticle arrays have potential applications in memory devices while the nickel catalyst nanoparticle arrays can be used for the growth of ordered carbon nanotubes. / Singapore-MIT Alliance (SMA)

porous alumina

nanoparticle arrays

nanofabrication

germanium

nickel

carbon nanotubes

Carbon Nanotube Growth Using Ni Catalyst in Different Layouts

Nguyen, H. Q., Krishnan, R., Choi, K. W., Thompson, Carl V., Lim, F. Y.

01 1900

Vertically aligned carbon nanotubes have been grown using Ni as catalyst by plasma enhanced chemical vapor deposition system (PECVD) in various pre-patterned substrates. Ni was thermally evaporated on silicon substrates with anodized alumina mask prepared in different methods including 2 step anodization of porous alumina template and interference lithography assisted array of pores. The templates helped to define Ni nanodots inside the pores which in turn catalyzed the growth of carbon nanotubes inside the PECVD system at temperature of 700-750C using mixture of ammonia and acetylene gases. The resulting well-aligned multi-walled carbon nanotubes were further investigated using SEM, TEM and Raman spectroscopy. The size, shape and structure of the grown carbon nanotubes were also discussed. / Singapore-MIT Alliance (SMA)

Nickel

Carbon nanotubes

On the interaction between liquid/ solid during sintering and solidification

Antonsson, Tomas

January 2003

No description available.

liquid phase

sintering

heavy metal

tungsten

iron

nickel

penetration

solidification

In vitro analyses of immune responses to metal and organic haptens in humans with contact allergy

Masjedi, Khosro

January 2008

Contact allergy is one of the most common skin diseases with great social and economical impact. The origin and nature of contact allergens (haptens) capable of inducing T-cell mediated allergic reactions are diverse, ranging from organic molecules to metal ions. Most of the current knowledge on T-cell responses to haptens in humans with contact allergy have been established by studies on the metal ion nickel (Ni), the most common cause of contact allergy, whereas reactivity to the large group of organic haptens has been less studied. Haptens are not immunogenic by themselves but must bind carrier molecules prior to their presentation on MHC class I or II molecules and subsequent recognition by T cells. Due to differences in their chemical nature, haptens interact with host molecules by different mechanisms and differences in their solubility can influence their access to different antigen-presenting pathways. The aim of the present study was to define immune responses elicited by haptens of different chemical nature including Ni (hydrophilic metal ion), methylisothiazolinones (hydrophilic organic molecule) and parthenolide (lipophilic organic molecule). The immune response displayed by subjects with allergy to these substances, and non-allergic control subjects, was assessed by measuring hapten-induced cytokine production in peripheral blood mononuclear cells (PBMC) with a focus on ELISpot analysis of T-cell type 1 (e.g. IFN-g and IL-2) and type 2 (e.g. IL-4, IL-5 and IL-13) cytokines. For Ni and parthenolide, the phenotype of the hapten-reactive T cells was determined. The allergic status of subjects was defined by clinical history and patch testing. The latter is the established diagnostic method for contact allergy, based on applying various haptens to the subjects’ back and grading the skin reaction after 2-3 days. All three haptens elicited a concomitant T-cell type 1 and 2 response in subjects with contact allergy to the corresponding hapten, suggesting the induction of a functionally related cytokine profile, irrespective of the chemical character of the hapten. The cytokine response was related to the degree of the subjects’ patch test reactivity; PBMC from a vast majority of subjects with strong and moderate patch test reactivity displayed detectable cytokine responses to the corresponding haptens, whereas subjects with weak or no (controls) patch test reactivity did not. Despite the similar cytokine profile induced, the phenotype of the reactive T cells was found to differ between haptens with Ni eliciting CD4+ T cells and parthenolide eliciting CD8+ T cells. This difference may be explained by a better ability of a lipophilic hapten to gain access to the MHC class I-restricted antigen-presentation pathway. Moreover, the data suggest that analysis of cytokine responses to haptens may facilitate future development of in vitro-based diagnostics assay for contact allergy. Finally, the relationship between the variation over time in patch test reactivity and systemic reactivity to Ni, in terms of cytokine responses to Ni in vitro, was investigated. The degree of patch test reactivity is known to vary over time, in particular in subjects with weak reactivity. Ni-allergic subjects were patch tested three times with three month intervals and PBMC obtained at the same time points were assessed for in vitro reactivity to Ni. The overall reactivity in the patch test and the in vitro test was well correlated confirming that both methods provide a good and comparable estimate of the systemic reactivity to Ni. However, fluctuations in the patch test reactivity over time were not well correlated with variations in the cytokine response elicited in vitro suggesting that other parameters besides changes in the systemic reactivity could significantly contribute to the variation in patch test reaction over time.

ELISpot

contact allergy

parthenolide

methylisothiazolinones

nickel

hapten

Allergology

Allergologi

Termofil rötning av drankvatten

Wiberg, Heli

January 2007

Biogasprocessen är en komplex anaerob nedbrytningskedja där olika mikroorganismer är inblandade. Vanligast är att biogas produceras i mesofil rötning (cirka 38 oC), men även termofil rötning används (&gt; 50 oC). Svensk Biogas i Norrköping använder återstoden av etanoldestillationen hos en närliggande etanolproducent (drankvatten) som substrat. Substratets höga temperatur vid leverans motiverar termofilt rötningsförsök av drankvatten. Försöket genomfördes i 55 oC med två kontinuerligt omrörda tankreaktorer (CSTR) och en termofil ymp. Biogasproduktion av drankvatten undersöktes. Sätt att hantera och motverka höga ammoniumhalter, samt effekter av näringslösningstillsats undersöktes. Det tog cirka 30 dagar för ympen att acceptera det nya substratet och då hade tillsats av processhjälpmedel KMB1 samt järnklorid använts. Reaktorerna kunde belastas med 3 g VS / (L • dygn) (VS, volatile solids, glödförlust). Den specifika gasproduktionen var 0,6 – 0,7 L / g VS och metanhalten ungefär 45 %. Höga ammoniumhalter motverkades genom förkortning av uppehållstiden. Under en period tillsattes nickelklorid i en av reaktorerna och under denna period hade reaktorn med nickelkloridtillsats något bättre specifik gasproduktion jämfört med reaktorn där ingen nickelklorid tillsattes. Drankvatten kan rötas under termofila förhållanden. För att temperaturförändring vid biogasanläggningen i Norrköping ska var ekonomiskt försvarbart måste processen klara högre belastning.

Biogas

termofil rötning

metan

destillationsåterstod

drankvatten

ammonium

nickel

Microbiology

Mikrobiologi

Ligand-based Reactions of Metal Bis- and Trisdithiolenes: Fresh Insights into Old Reactions and New Frontiers

Harrison, Daniel

21 April 2010

Metal dithiolenes [M(S2C2R2)n] have been studied for decades because of their interesting chemical and spectroscopic properties, which are related to the unusual electronic properties of the dithiolene ligand. The ligand-based reactivity of metal bisdithiolenes [M(S2C2R2)2] toward alkenes has been proposed for use in alkene purification schemes. According to the proposal, compounds Ni(S2C2R2)2 (R=CF3,CN) react with simple alkenes to form stable S,S-interligand adducts and the alkene can be released from the adduct by reduction. We showed that Ni(S2C2(CF3)2)2 reacts with ethylene and 1-hexene to form, preferentially, S,S-intraligand adducts, which rapidly decompose to inactive metal-containing materials and dihydrodithiins. However, the product selectivity can be significantly modified so that stable S,S-interligand adducts are obtained as dominant products by adding [Ni(S2C2(CF3)2)2]- to Ni(S2C2(CF3)2)2/alkene reaction mixtures. Mechanistic implications are discussed. Next, the reactions of Pt(S2C2(CF3)2)2 with 2,3-dimethyl-1,3-butadiene are addressed. Prior to our report, only symmetry-allowed S,S-interligand adducts had been observed as products in the reactions between conjugated dienes and metal bisdithiolenes. We discovered a novel mode of diene binding, where two dienes bind to one dithiolene ligand of Pt(S2C2(CF3)2)2, in an C,S-intraligand fashion, forming a new chiral bisthioether ligand. From bisdithiolenes, the focus shifts to new mixed-ligand molybdenum trisdithiolenes [Mo(S2C2(CF3)2)2(S2C6H4) and Mo(S2C6H4)2(S2C2(CF3)2)]. These complexes rapidly and cleanly bind ethylene, in an S,S-intraligand fashion, as predicted by MO arguments. The resulting intraligand adducts are sufficiently stable to be characterized, in contrast to the nickel bisdithiolene case. The metal-chelated dihydrobenzodithiin, formed upon ethylene addition, can be substituted with a variety of donor ligands, allowing access to new types of molybdenum dithiolenes. We have recently extended these studies to catalytic reactions: Mo(S2C2(CF3)2)2(S2C6H4) was used as a catalyst to form dihydrobenzodithiins from (S2C6H4)2 and a variety of alkenes, in the first example of dithiolene-based reactivity being exploited for carbon-heteroatom bond-forming catalysis. Finally, the synthesis, characterization and redox reactivity of a new Fe2Ni bis-double-decker complex is described, demonstrating for the first time a sandwich complex of a metal bisdithiolene with both NiS2C2 rings in an η5 π-donating mode. For the radical cation, experimental and computation evidence indicates that the lone electron is delocalized over the entire molecule.

dithiolene

transition metal

nickel

iron

platinum

coordination

ligand

noninnocent

0488

Microstructure Evolution and Mechanical Properties of Electroformed Nano-grained Nickel upon Annealing

Li, Zong Shu

10 January 2011

Nano-grained nickel produced by electroforming technique was investigated for its microstructure evolution and mechanical properties upon annealing. It was found that during low temperature annealing (T<250 oC), electroformed nano-grained nickel showed scattered and isolated abnormal grain growth, followed by a major abnormal grain growth at 320 oC. A secondary abnormal grain growth, featuring faceted grain boundaries, was observed at a higher annealing temperature (T=528 oC). A semi-in-situ observation using optical microscopy was conducted to track the movement of the faceted grain boundaries, and it was found that these boundaries were mostly immobile. The mechanical properties under various annealing conditions were studies using hardness and tensile testing. The hardness was observed to decrease with increasing annealing temperature. The material became very brittle after annealing at 320 oC or higher temperatures. Fractography investigation showed that the brittleness is caused by intergranular fracture.

nanocrystalline nickel

microstructure evolution

mechanical properties

electroformed

0794

Disrupting the Non-specific Interactions between DNA and the Escherichia coli Transcriptional Repressor NikR

Krecisz, Sandra

20 July 2012

The Escherichia coli transcription factor NikR is responsible for nickel-mediated repression of the nik operon. The crystal structure of NikR in complex with its operator sequence provided insight into the mechanistic details of nickel-activated NikR-DNA complex formation. The crystal structure revealed that the α3 helix and its preceding loop (residues 63-79) in two of the metal-binding domains—which become structurally ordered after high-affinity nickel binding—make non-specific contacts with the DNA phosphodiester backbone. The proposed mechanism of NikR binding to DNA suggests that the non-specific interactions between the DNA phosphodiester backbone and the positively-charged residues Lys64 and Arg65 anchor NikR to the DNA, thereby allowing the protein to initiate a one-dimensional search for its recognition sequence. The DNA-binding studies presented here strongly support an important role for Lys64 and Arg65 in NikR-DNA complex formation which is in agreement with the proposed model of NikR binding to DNA.

NikR

nickel

transcription factor

transcriptional repressor

0485

0487

Microstructure Evolution and Mechanical Properties of Electroformed Nano-grained Nickel upon Annealing

Li, Zong Shu

10 January 2011

Nano-grained nickel produced by electroforming technique was investigated for its microstructure evolution and mechanical properties upon annealing. It was found that during low temperature annealing (T<250 oC), electroformed nano-grained nickel showed scattered and isolated abnormal grain growth, followed by a major abnormal grain growth at 320 oC. A secondary abnormal grain growth, featuring faceted grain boundaries, was observed at a higher annealing temperature (T=528 oC). A semi-in-situ observation using optical microscopy was conducted to track the movement of the faceted grain boundaries, and it was found that these boundaries were mostly immobile. The mechanical properties under various annealing conditions were studies using hardness and tensile testing. The hardness was observed to decrease with increasing annealing temperature. The material became very brittle after annealing at 320 oC or higher temperatures. Fractography investigation showed that the brittleness is caused by intergranular fracture.

nanocrystalline nickel

microstructure evolution

mechanical properties

electroformed

0794