SHI Delays Delivery of LNG Carrier Duo

first_imgzoom South Korean shipbuilder Samsung Heavy Industries (SHI) is in talks on a new delivery deadline for a liquefied natural gas (LNG) carrier duo with an unnamed Asian shipowner. The two ships were ordered in January 2015 and were supposed to be delivered at the end of September 2017.SHI said in a regulatory filing that once the new delivery schedule is agreed it would arrange for the necessary refunding to be carried out resulting from the delay.The LNG carrier duo was priced at USD 395 million.The shipbuilder has been busy with deliveries of OOCL’s ultra large container vessels (ULCVs) newbuildings over the recent months, which saw four 21,413 TEU containerships delivered to the company since May this year, OOCL United Kingdom, OOCL Germany, OOCL Japan and OOCL Hong Kong.Two more ships from the batch remain to be delivered.Late last month, the company secured an order for the construction of six ULCVs. The contract is worth KRW 1.118 trillion (USD 982.6 million), according to SHI.The Korean shipbuilder said the order was placed by a European shipowner but did not disclose its identity.The company’s order backlog stands at USD 12.9 billion, with USD 6.5 billion worth of orders bagged this year.World Maritime News Stafflast_img read more

Tourist Board Resumes Public Service Training

first_img Related Items:#magneticmedianews Electricity Cost of Service Study among the big agenda items at September 11 Cabinet meeting Facebook Twitter Google+LinkedInPinterestWhatsAppProvidenciales, TCI, February 21, 2017 – The Turks and Caicos Tourist Board today announced that training for persons interested in public service transportation has resumed.  Training will be conducted throughout the Turks and Caicos Islands. All interested persons residing in Providenciales and Grand Turk are encouraged to visit the Tourist Board’s office, request a TIDES Public Service Driver’s Application, complete and submit the application to the office receptionist.The Training Manager will vet all submitted applications. Once vetting is completed, registered persons will receive a courtesy call from the Training Manager confirming your date, time and location for training.Interested persons residing in North Caicos, Middle Caicos, South Caicos or Salt Cay are encouraged to register through their respective District Commissioner’s Office or contact the Tourist Board Office in Providenciales at (649) 946-4970 or the Tourist Board Office in Grand Turk at (649) 946-2321.The Tourist Board will also be conducting customer service training with the Immigration Department during the month of February.#MagneticMediaNews ALERT # 2 ON POTENTIAL TROPICAL CYCLONE NINE ISSUED BY THE BAHAMAS DEPARTMENT OF METEOROLOGY THURSDAY 12TH SEPTEMBER, 2019 AT 9 PM EDT Recommended for you Facebook Twitter Google+LinkedInPinterestWhatsApp The Luxury of Grace Bay in Down Town Provolast_img read more

Nemanja Matic makes surprise admission about United

first_imgManchester United midfielder Nemanja Matic has made a surprising admission about the team following their draw against Arsenal on Wednesday.Matic insists the United squad is currently low on confidence as they go through a poor season so far.Jose Mourinho’s United came back from a goal down on two separate occasions to earn a 2-2 draw with Arsenal at Old Trafford.“Both teams attacked,” said Matic, according to Mirror Football.“It was a great game for the supporters but I thought we deserved a point.”harry maguire, manchester UnitedMaguire says United need to build on today’s win George Patchias – September 14, 2019 Harry Maguire wants his United teammates to build on the victory over Leicester City.During the summer, Harry Maguire was referred to as the ultimate…“Everyone knows the confidence is not high, but this is the fight that we have to show. Everyone is ready to play wherever the manager asks.”Meanwhile, United defender Chris Smalling said the players are well aware of their problems.“All of us know we are in a tough path of form and everyone is giving everything to help us through,” he said.“Everyone is digging in. We were on the front foot and pressing them because we know they like to play and I thought we were unlucky not to get the third goal.”last_img read more

Tiny magnets huge fields Nanoscale ferromagnetic electrodes create chemical equivalent of solidstate

first_imgIn the study of ways to determine the position of and manipulate magnetic nanoparticles – a capability that would benefit a wide range of applications – there’s good news and bad: While a magnetic gradient force field (a magnetic field that varies with respect to position) can accomplish this, it is limited in its ability to affect most paramagnetic materials – that is, materials that respond to magnetic fields, but do not retain magnetic properties when those fields are removed – the exception being sufficiently small magnetic nanoparticles, which can behave like paramagnets at room temperature due to thermal agitation (an effect known as superparamagnetism). Explore further This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only. Magnetic gradient force density field for nanoscale Ni electrodes. (Upper) Diagrams sketch the relaxed magnetization orientation in the electrodes, with a related broken or straight line symbolizing an open and closed electric contact. The electrodes are made of rectangular bars 300 nm long, 30 nm wide, and 16 nm high, with slightly rounded corners. (Lower Left) The external field of 0.8-T magnitude is applied along the longitudinal direction x. (Lower Right) The field is applied along the transversal direction y. The vector field reveals the direction of the forces. The color code indicates the amplitude of the forces, attractive (blue) in the longitudinal case and repulsive (red) in the transverse case. The maximum color intensity corresponds to a magnitude of 109 N/m3. More quantitative details can be found in SI Text. Copyright © PNAS, doi:10.1073/pnas.1322828111 That being said, the ability to use a magnetic gradient force field to precisely control paramagnetic molecules in solutions has remained elusive. Recently, however, scientists at University of Strasbourg, France have proposed that this limitation can be addressed by using miniaturized ferromagnetic electrodes to create powerful localized force fields that can be tuned by an external magnetic field. The researchers then illustrated this concept by immersing a metallic nickel (Ni) nanobridge electrode in a solution containing paramagnetic molecules and controlling the electrode’s magnetization direction with an external magnetic field. In so doing, the scientists created a conductive molecular-sized switching system that they say is the chemical equivalent of a spintronics (that is, spin transport electronics) solid-state spin valve two-terminal device. Prof. Bernard Doudin discussed the paper that he, Researcher Petru Lunca Popa and their co-authors published in Proceedings of the National Academy of Sciences. “Our concept of extending the spintronics spin valve to magnetic electrodes in solution using magnetic control of their chemical environment totally novel, and essentially results from an unexpected discovery,” Doudin tells “We were looking for spin valve effects in a metallic contriction,” a type of nanowire, “and found that changing the chemistry was producing a large change of resistance associated with a change of applied magnetic field.” The challenge, Doudin says, was to devise an experimental controlled microfluidic setup that allowed a continuous and reversible change of the sample’s chemical environment. Doudin points out that conducting micromagnetic simulations was essential to confirming the creation of a chemical equivalent of a solid-state spin valve device. “This provided confidence in a model of magnetic forces, backed by several reported experiments in the field of electrochemistry,” he explains, adding that an unexpected result of these simulations was the occurrence in transverse magnetic fields of repulsive forces. “From a micromagnetic point of view this was a bit counterintuitive, and reinforced our gradient force field concept.” The paper suggests that the magnetic field gradient can become a dominant influencing factor on chemical reactions at the nanoscale. “We devised a system where any equilibrium change can result in a large change in a physical property, such as conduction of the nickel nanobridge,” Doudin explains, “and designed a magnetic circuit where this force is maximal. ” That said, Doudin points out that while their experiment was originally designed with nickel as part of their evaluation of spin valve effects in metals. “However, our paper adopted a more expansive approach based on our goal of asserting that what is observed with nickel can be more generally applied.”Their findings also suggest that the reaction yields or the chemical equilibrium can also be influenced by the gradient of the magnetic field. Specifically, the single reversible reaction step, yield is either metallic (Ni) or ionic (Ni++). “We use the phrasing of yield for comparison with the literature on chemical equilibrium modified by magnetic fields rather than gradients, where the equilibrium changes are small, and relate to intermediate products,” Doudin says. “The largest impact, in these cases, is usually the reactions yields of some final product.”Regarding the implications of extending magnetophoresis to magnetic forces on paramagnetic molecules in solution, Doudin tells that performing magnetophoresis on single molecules will always be limited by the dominant Brownian motion of molecules. “We can, however, significantly modify the average residency time of molecular species at a given position,” he adds, “and thereby impact chemistry.” This, in turn, may lead to the creation of new types of spin-sensitive devices. “These might include single-spin detection by electrical means, or realize stable chemical structures of highly sensitive to local magnetic fields,” Doudin illustrates. “As mentioned in our conclusions, supramolecular architectures can be sensitive to the magnetic forces effects, and their role in a chemical reaction, or as intermediate bridging element in a biochemistry reaction process, could be modified under local magnetic forces.”Another possibility is the development of a metallic nanobridge exhibiting electrical properties tunable through a change of magnetic orientations of the electrodes. “In our paper, a change of electrode magnetization is induced by an external field,” Doudin explains. “One can imagine other ways to control the magnetization, such as an electric current or a substrate deformation.” (The latter is a current trend in spintronics, he notes, where spin-dependent devices should be controlled by means other than an external magnetic field.) “As the conductance is highly sensitive to paramagnetic ions, one can imagine detecting ions by electrical means.”In their paper, the scientist also proposed a tabletop tool and methodology for influencing chemical reactions. “We can search for other reactions implying paramagnetic species – for example, radical polymerization – and test this happening or not between magnetic electrodes,” Doudin points out. “One can also imagine creating patterned magnetic substrates, where surface chemical reactions will be controlled by their magnetic orientation, thereby realizing tunable chemically-active substrates.” He adds that their tabletop tool refers to the laboratory equipment required by their approach relative to that used in spin chemistry, where usually very large magnetic fields are needed to impact significantly the chemistry. “With the magnetic field values we use, a simple tabletop device is enough to create such fields.”Moving forward, says Doudin, the scientists plan to investigate single-spin detection using similar metallic nanobridges, and to search for other chemical reactions that can be modified by our magnetic circuit – in particular, control of supramolecular architectures. “Most molecular architectures seen in nature are based on rather weak and dynamic chemical bonds. Therefore,” he concludes, “the study of the equilibrium and stability of supramolecular architectures under magnetic field gradients, which can have important implications in biochemistry processes, might benefit from our research.” © 2014 Horizontal levitation: The ultimate solution to particle separation Journal information: Proceedings of the National Academy of Sciences Doudin notes that there were a range of techniques critical to addressing these challenges:Microfluidic control A dedicated setup with controllable applied magnetic fields in which amplitude and direction could be rapidly changed was needed due to metallic constrictions having very brief lifetimes A well-controlled experimental procedure for electrochemically stabilizing a metallic nanobridgeData showing an inverse relationship between switching magnitude and Ni ion concentration that allowed the scientists to reconcile several reports with highly variable outcomes by showing that they used very different solution concentrations”A key innovation is our model of the influence of magnetic forces on chemistry, since it goes against the general belief that magnetic gradient force should not have any noticeable effect,” Doudin adds. “In fact, work by J. Michael D. Coey1 – our paper’s editor – is among a small number of published papers showing such effects.” Ni nanocontact construction, with ON/OFF switching of its conductance when varying the direction of the external magnetic field. (A) Sketch of the microfluidic cell, with electron microscopy zoom of the nanoelectrodes used as working electrodes W1, W2 in an electrochemical cell including a reference R and a counter C electrode. (B) Time evolution of the conductance under oscillating (0.5 Hz) rotation of the applied magnetic field of constant 0.8-T amplitude. The top line represents the time oscillation of the magnetic field orientation, with an opening of the contact when the field is along the direction of the electrodes (zero angle) and closure at angles in the vicinity of ± π/2. The diagrams on the right present schematics of the related open (OFF) and closed (ON) nanocontacts. Copyright © PNAS, doi:10.1073/pnas.1322828111 More information: The magnetoelectrochemical switch, Proceedings of the National Academy of Sciences, Published online before print on July 9, 2014, DOI: 10.1073/pnas.1322828111Related1Magnetic stabilization and vorticity in submillimeter paramagnetic liquid tubes, Proceedings of the National Academy of Sciences, June 2, 2009 vol. 106 no. 22 8811-8817, DOI: 10.1073/pnas.0900561106 Citation: Tiny magnets, huge fields: Nanoscale ferromagnetic electrodes create chemical equivalent of solid-state spin valve (2014, July 31) retrieved 18 August 2019 from read more