High Entropy Alloys For Hydrogen Storage Applications Operable At Room Temperature (HEART)Ģ023/CSIR-NCL/ORG/HCP44-03, GAP330826/315ĭevelopment Of Versatile Liquid Organic Hydrogen Carriers & Development Of Manganese And Iron-Based Metal Catalysts For Asymmetric Hydrogenation Of Imines And Enaminesįilling Up Of A Position For Engagement As A Project Associate-I (PA-I) Pathway-Flux Redirection By CRISPR-Cas9/Cpf1- Mediated Gene Editing For Enhancement Of Medicinal Traits In Rosmarinus Officinalisįilling Up Of Position For Engagement As Project Scientist III In Polymer Processing And Rheology PA-I Post On Project 'Pathogen Detection, Surveillance And Genotyping By Sequencing'įilling Up Of Position(S) For Engagement As Project Associate-I, Project Associate-II And Senior Project Associate For Sponsored Project Taken Up In The Lab.Ĭarbon Capture Utilization And Storage (CCUS) Recruitment Of Project Scientist II For The Project Titled, "Development Of Spinnable Grade Meta- And Para-Aramid Polymers And Their Fibre Spinning" Targeting Juvenile Hormone Degradation Pathway For Helicoverpa Armigera ManagementĪdvertisement For SPA And PA-1 Positions Under Govt.Sponsored Projectįilling Up Of Position For Engagement As Project Associate IIįilling Up Of Position For Engagement As Scientific Administrative Assistant Under CSIR Sponsored Projects Taken Up In The Lab Next Generation Low Temperature Proton Exchange Membrane Fuel Cell-Technology Development These aspects are strongly interconnected and facilitate an extensive collaboration network with national and international experts.Filling Up Of A Position For Engagement As A Project Associate-I (PA - I)Īdvertisement For Senior Project Associate (SPA) Position Under Govt. In-situ observation of deformations in HEAs under electron microscopes.Defects, segregations and thermodynamics in HEAs.High-temperature refractory high-strength HEAs.Resistances to hydrogen-embrittlement and corrosion of HEAs.Excellent strength-ductility combination of transitional metal HEAs.Our research group (High-Entropy Alloys) conducts the state-of-the-art research work employing novel experimental-theoretical methodologies (e.g., EBSD, ECCI, FIB-APT, TEM, Calphad and DFT Figure 2) in the following specific aspects: This leads to the exceptional strength-ductility combination of the novel HEAs, exceeding that of most metallic materials. steels, Ti-alloys, Al-alloys), our recently developed novel interstitial TWIP-TRIP-HEAs concept combines all available strengthening effects, namely, interstitial and substitutional solid solution, TWIP, TRIP, multiple phases, precipitates, dislocations, stacking faults and grain boundaries. As a breakthrough of this restriction, the concept of HEAs opens a new realm of numerous opportunities for investigations in the huge unexplored compositional space of multi-component alloys.Īs a typical example shown in Figure 1, while conventional alloys use strengthening mechanisms such as grain boundaries, dual-phase structure, dislocation interactions, precipitates and solid solution (e.g. This was achieved by using the advanced experimental techniques and the state-of-the-art theoretical methods.Ĭonventional alloy design over the past centuries has been constrained by the concept of one or two prevalent base elements.
The goal of our group was to develop novel high-entropy alloys (HEAs) with exceptional mechanical, physical and chemical properties based on the understanding of their structure-properties relations. © Max-Planck-Institut für Eisenforschung GmbH
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