Analysts at JPMorgan recommended selling or "underweight" emerging market local currency sovereign debt because of the global impact of the Ukraine-Russia crisis.
JPMorgan estimated that fixed-income assets in emerging markets have lost 6-9 percent of their value since Russia invaded Ukraine a month ago, with nervousness about the war and its impact on global energy and food prices adding to existing pressures.
Some leading emerging market central banks are signaling that interest rates now need to rise faster than previously expected, which fuels fears of "stagflation". Stagflation means when high inflation and higher interest rates undermine economic growth.
With both the U.S. Federal Reserve and emerging market central banks raising interest rates, JPMorgan also said it made sense to "underweight" emerging market assets by taking advantage of the recent pullback in local currency bond yields relative to TREASURIES.
JPMorgan said major metals exporters such as South Africa, Chile, and Peru could still do well, but warned that emerging market fixed income assets now faced a more "stagflationary" trajectory.
The markets and prices of many commodities, metals, chemicals like the Lithium-ion batteries still face uncertainty.
Lithium-ion batteries have become hotspots in energy research due to their higher energy density, long service life, and smaller volume compared with lead-acid, nickel-cadmium, nickel-metal hydride, and other batteries, and no memory effect. One. The negative electrode material is one of the critical components of lithium-ion batteries. It acts as the acceptor of lithium ions and realizes the insertion and extraction of lithium ions during the charging and discharging process. Therefore, the quality of the negative electrode material directly affects the overall performance of the lithium-ion battery. Graphite and modified graphite are widely used as anode materials for commercial lithium-ion batteries. Still, their theoretical capacity is only 372mAh/g, which significantly restricts the development of high-energy power batteries. Group IV element (silicon, germanium, tin)-based anode materials have become a research hotspot for next-generation lithium-ion batteries due to their high theoretical capacities (3579mAh/g, 1600mAh/g, 994mAh/g, respectively). However, silicon, germanium, and tin-based anode materials have the problem of significant volume expansion during the charging and discharging process. Long-term charging and discharging will cause the pulverization of particles and the shedding of active materials, thus affecting the cycle stability of lithium-ion batteries.
In recent years, the advanced lithium-ion battery team led by Han Weiqiang, a researcher at the Institute of New Energy Technology affiliated with the Ningbo Institute of Materials Technology and Engineering, Chinese Academy of Sciences, has made a series of progress in high-capacity silicon, germanium, and tin-based anode materials. In terms of high-performance silicon-based anode materials, researchers have developed a low-cost, high-capacity, and high-stability porous silicon-based anode material technology. By carbon coating, the porous silicon, the performance of the silicon-based negative electrode material for lithium-ion batteries is further improved. The capacity retention rate of the silicon-carbon composite electrode material was 86.8% after 300 charge-discharge cycles. Related research has applied for Chinese invention patents (201410150747.5, 201410276413.2), and the research results were published in NanoEnergy (2015, 11, 490-499) in the form of Communication.
Based on the previous work, the team synthesized and prepared a series of new phase MSn5 (M=Fe, Co, Fe0.5Co0.5) alloy nano-anode materials using the wet chemical method of improving polyols. The synthesized FeSn5 alloy nanoparticles have a theoretical capacity of 929mAhg-1 when used as a negative electrode material for lithium-ion batteries, which is the material with the highest theoretical specific capacity among the reported M-Sn (M is an electrochemically inert metal) alloy. The researchers prepared a series of Fe0.5Co0.5Sn5 new phase alloy nanoparticles with a 30-50nm particle size range, which further expanded the Co-Fe-Sn phase diagram. Related achievements have applied for invention patents (2013104705134, 201310706760X, 2103715406A). At the same time, the charge-discharge mechanism was deeply discussed and explained by in-situ XAFS, in-situ XRD, and electrochemical test methods. The research on the electrochemical mechanism of this series of tin-based new phase alloy anode materials provides effective theoretical guidance for the team's subsequent development of high-performance tin-based anode materials. Relevant results were published in JournalofMaterialsChemistryA (2015, 3(13):7170-7178) and ACS Appl.Mater.Interfaces (2015,7,7912-7919).
The team has also made progress in the research and development of long-life titanium-based anode materials, applying for an invention patent (201310685139. X), and the relevant results were published in the Journal of Materials Chemistry (2014(2), 10599-10606).
High-quality lithium-ion batteries supplier
Luoyang Moon & Star New Energy Technology Co., LTD, founded on October 17, 2008, is a high-tech enterprise committed to developing, producing, processing, selling, and technical services of lithium-ion battery anode materials. After more than 10 years of development, the company has gradually developed into a diversified product structure with natural graphite, artificial graphite, composite graphite, intermediate phase, and other negative materials (silicon-carbon materials, etc.). The products are widely used in high-end lithium-ion digital power and energy storage batteries. If you are looking for Lithium battery anode material, click on the needed products and send us an inquiry：email@example.com.
A preparation developed in China; the comfort and the multifunctional properties of nanomaterials make "dead skin" capable of sensing again. Electronic skin is artificial skin that mimics the function of human skin. Recently, the world-renowned journal Advanced Science reported a simple and highly programmable electronic skin on a leather substrate developed by a Chinese team, which combines the natural complex structure of leather, the comfort of wearing, and the multi-functional properties of nanomaterials. , so that the "dead skin" has the ability to sense again.
In the future, Lithium-ion batteries will be used in various high-tech fields, and the market demand for Lithium-ion batteries will also be great. Please contact us for more information on Lithium-ion batteries.
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