|
[Sponsors] |
Job Record #19178 | |
Title | PhD in Thermal Management for Future Aerospace Propulsion |
Category | PhD Studentship |
Employer | Heriot Watt University |
Location | United Kingdom, Edinburgh |
International | Yes, international applications are welcome |
Closure Date | Monday, July 22, 2024 |
Description: | |
Global targets to cut carbon-dioxide emissions by 2050 are pushing forward the development of sustainable aircraft. If action is not taken, the annual atmospheric CO2 emissions from aviation are expected to grow 67% by 2050 [1]. While small sub-regional aircraft are seeing transition to fully electric propulsion systems, significant technological development is needed to decarbonise larger regional, narrowbody, and widebody aircraft. Based on current trends, it has been predicted that the regional aircraft market will see the first use of hydrogen technology in service with the use of hydrogen fuel cell architectures as early as 2035 [2]. Converting hydrogen fuel and oxygen into electricity using reverse electrolysis, hydrogen fuel cells are not without their challenges. Despite the high energy density of hydrogen, its very low volumetric energy density is problematic for aircraft applications, particularly in terms of fuel storage. While many industrial players and academic researchers focus on this on this challenge, a lesser-known challenge lies in the large quantities of heat generated by hydrogen fuel cell stacks. According to Scholz et al. [3], the amount of heat produced by Proton Exchange Membrane fuel cells (PEMFCs) is of the same order of magnitude as the electrical power produced. Adapting and optimising fuel cell cooling and thermal management systems specifically for aerospace applications presents a significant technical challenge. [1] FlyZero Aerospace Technology Institute (2022) Market Forecasts & Strategy. Available at: https://www.ati.org.uk/wp-content/uploads/2022/03/FZO-CST-REP- 0043-Market-Forecasts-and-Strategy.pdf (Accessed 13 March 2024) [2] FlyZero Aerospace Technology Institute (2022) Technology Roadmaps. Available at: https://www.ati.org.uk/wp-content/uploads/2022/03/FZO-IST-MAP-0012-FlyZero- Technology-Roadmaps.pdf (Accessed 13 March 2024) [3] Scholz, A.E., Michelmann, J., and Hornung, M. (2023) Fuel Cell Hybrid- Electric Aircraft: Design, Operational, and Environmental Impact. Journal of Aircraft 60(3), pp.606-622 Project Aims: This project will explore innovative thermal management solutions for aircraft fuel-cell systems with a focus on miniaturization and weight reduction. It is expected that the project will involve: - Multiphase (and potentially multiscale) fluid modelling using Computational Fluid Dynamics (CFD). - Development/use of tools to model the integration thermal management systems within the aircraft conceptual design stages. Requirements: • Candidates should hold a first or second-class Honours degree in Aerospace, Mechanical, Electrical Engineering, or other relevant disciplines. • Candidates should be passionate about making contributions to sustainable aviation challenges. • A strong background in fluid simulation, thermal management and/or aerospace design are desirable but not essential. How to apply: Interested candidates are invited to submit their CV, academic transcripts, and a brief statement detailing their research interests and how their knowledge applies to the proposed topic. Please send your application to stephanie.docherty@hw.ac.uk, referring to the project title. Shortlisted candidates will be contacted for interviews. Application Deadline: 22/07/2024 This studentship is open to UK citizens and EU applicants with pre-settled or settled status. International candidates are welcome to apply, however only the home student’s tuition fees are covered. Additional funding may be made available for excellent international applicants. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19178 when responding to this ad. | |
Name | Stephanie Docherty |
stephanie.docherty@hw.ac.uk | |
Email Application | Yes |
Record Data: | |
Last Modified | 12:43:29, Friday, May 17, 2024 |
Job Record #19175 | |
Title | PhD in Fluid Topology Optimization |
Category | PhD Studentship |
Employer | King's College London |
Location | United Kingdom, London |
International | Yes, international applications are welcome |
Closure Date | Friday, May 31, 2024 |
Description: | |
Job Description: PhD in Fluid Topology Optimization of Compact Heat Exchangers Position Overview: We are seeking a highly motivated and skilled Research Assistant to join our interdisciplinary research team at King's College London. The successful candidate will contribute to a pioneering project aimed at revolutionizing the design and manufacturing of compact heat exchangers. The research will focus on leveraging additive manufacturing, high-fidelity Computational Fluid Dynamics (CFD) simulations, and fluid topology optimization to enhance the thermal performance and efficiency of heat exchangers across various engineering applications. Responsibilities: 1. Conducting extensive literature reviews on additive manufacturing technologies, fluid topology optimization, high-fidelity CFD simulations, and compact heat exchangers to inform research objectives and methodologies. 2. Collaborating with the research team to develop an integration framework that seamlessly combines additive manufacturing capabilities, high-fidelity CFD simulations, and fluid topology optimization algorithms. 3. Utilizing the developed framework to investigate and optimize heat exchanger designs, with a focus on maximizing thermal performance, reducing pressure drop, and minimizing size and weight. 4. Designing and conducting experiments using flow measurement/visualization rigs to validate simulation results and assess real-world performance of optimized heat exchanger designs. 5. Analyzing data, interpreting results, and contributing to the dissemination of research findings through publications, presentations, and reports. 6. Adhering to project timelines and milestones, and collaborating effectively with team members to achieve research objectives. Qualifications: - A Master's degree or equivalent in Mechanical Engineering, Aerospace Engineering, Computational Sciences, or a related field. - Strong background in Computational Fluid Dynamics (CFD), fluid mechanics, and heat transfer. - Proficiency in programming languages such as Python, MATLAB, or C++. - Experience with additive manufacturing technologies and CAD software. - Excellent analytical and problem-solving skills, with the ability to work both independently and collaboratively in a research team. - Effective communication skills, with the ability to present complex technical concepts clearly and concisely. Duration: This is a full-time position for the duration of the research project, with an initial appointment period of 3 years and the possibility of extension based on performance and funding availability. Application Process: Interested candidates should submit a detailed curriculum vitae (CV), a cover letter outlining their research interests and relevant experience, and contact information for at least two references to Dr. Juan Li (juan.li@kcl.ac.uk) and to Dr. Richard Jefferson-Loveday(https://www.kcl.ac.uk/people/richard-jefferson- loveday). Review of applications will begin immediately and will continue until the position is filled. Equal Opportunity Statement: King's College London is committed to diversity, equity, and inclusion, and encourages applications from individuals of all backgrounds and identities. We are dedicated to creating a welcoming and inclusive environment where all members of our community can thrive. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19175 when responding to this ad. | |
Name | Juan Li |
juan.li@kcl.ac.uk | |
Email Application | Yes |
URL | https://www.kcl.ac.uk/people/juan-li |
Address | Strand Building Strand Campus, Strand, London, WC2R 2LS |
Record Data: | |
Last Modified | 11:28:15, Friday, May 17, 2024 |
Job Record #19177 | |
Title | Working Student - Compressor Inclement Weather |
Category | Internship |
Employer | GE Aviation |
Location | Germany, Munich |
International | Yes, international applications are welcome |
Closure Date | Friday, May 31, 2024 |
Description: | |
Job description - R3606959 Working Student - Compressor Inclement Weather Summary: In the framework of Catalyst engine certification process a number of numerical analyses are being carried out in order to predict inclement weather threats for the engine - such as icing, rain, hail or other particle matter ingestion. The Aerodynamics team at GEA Munich is looking for a student who will be responsible for the numerical modeling of the inclement weather threats. The student will furthermore support the planning, execution and presentation of the project. The task is envisioned to have a duration of 6 months. The work will involve the setup of complex numerical models (particle tracking in Ansys CFX), results post-processing, as well as interpretation of multi-phase CFD data. Your specific responsibilities will include: perform and interpret numerical simulations; participate in and present during technical reviews; work on the task with the support of members of the Aerodynamics team and under supervision of a dedicated mentor. Desired qualifications include: • Good understanding of the physics and principles associated with turbomachinery aerodynamics. • Proven track record in delivering on complex programs and ability to work in crossfunctional global team in multi-cultural environments. • Demonstrated ability to advance the technology state of the art and ability to generate innovative solutions. • Fluency in English. Are you interested in this position? Please send your application in German or English with the relevant documents to Mr. Steffen Jebauer (Steffen.Jebauer@ge.com) and to Mr. Andrea Milli (andrea.milli@ge.com). |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19177 when responding to this ad. | |
Name | Steffen Jebauer |
Steffen.Jebauer@ge.com | |
Email Application | Yes |
Address | GE Aviation, Garching, Munich, Germany |
Record Data: | |
Last Modified | 11:22:49, Friday, May 17, 2024 |
Job Record #19176 | |
Title | PhD in 3D Topology Optimization in Multi-physics Problems |
Category | PhD Studentship |
Employer | TU Braunschweig |
Location | Germany, Braunschweig |
International | Yes, international applications are welcome |
Closure Date | Friday, May 31, 2024 |
Description: | |
Job Description: PhD in 3D Topology Optimization in Multi-physics Problems Topology optimization stands as a paramount engineering design methodology, surpassing conventional shape and size optimization by theoretically generating optimal structures de novo. The burgeoning interest in applying topology optimization across various industries underscores its significance in addressing diverse design challenges. This project endeavors to pioneer a technological breakthrough by developing a platform for high-fidelity, high-resolution, and robust 3D topology optimization tailored for multi-physics phenomena, encompassing thermofluid dynamics and fluid-structure interaction. Key Objectives: - Spearheading the development of a cutting-edge technology for 3D topology optimization capable of addressing multi-physics problems. - Harnessing expertise in computational fluid dynamics (CFD) code development, optimization techniques, and leveraging high-performance computing (HPC) resources. Responsibilities: - Collaborating with interdisciplinary teams to conceptualize and implement advanced algorithms for 3D topology optimization. - Conducting thorough research and development to enhance the fidelity, resolution, and robustness of the optimization framework. - Contributing to the integration of multi-physics simulations, particularly in thermofluid dynamics and fluid-structure interaction, into the optimization process. - Validating and benchmarking the developed methodologies through rigorous testing and comparison with existing approaches. - Disseminating research findings through peer-reviewed publications and presentations at academic conferences. Qualifications: - Master of Science (MSc.) degree in Aerospace Engineering, Mechanical Engineering, or a closely related field. - Demonstrated experience in CFD code development, optimization algorithms, and proficiency in high-performance computing. - Strong analytical skills and a keen interest in tackling complex engineering problems. - Ability to work collaboratively in a multidisciplinary research environment and communicate technical concepts effectively. Application Process: Interested candidates should submit a comprehensive curriculum vitae (CV), a cover letter outlining their relevant experience and research interests, and contact information for at least two references to Anadika Paul Baghel (a.baghel@tu-braunschweig.de) and Inken Knop (i.knop@tu-braunschweig.de). Equal Opportunity Statement: We are committed to fostering diversity, equity, and inclusion in our research community and encourage applications from individuals of all backgrounds and identities. We aim to create an inclusive environment where all members can thrive and contribute to cutting-edge research initiatives. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19176 when responding to this ad. | |
Name | Anadika Paul Baghel |
a.baghel@tu-braunschweig.de | |
Email Application | Yes |
Phone | +4953139194281 |
URL | https://www.tu-braunschweig.de/en/ism/research/multiphase-flow-and-icing/team/baghel |
Address | Technische Universität Braunschweig, Institute of Fluid Mechanics, Hermann-Blenk-Str. 37, 38108 Braunschweig, Germany |
Record Data: | |
Last Modified | 11:17:27, Friday, May 17, 2024 |
Job Record #19174 | |
Title | PhD in the CFD-Wind Energy Project |
Category | PhD Studentship |
Employer | Esslingen University of Applied Sciences |
Location | Germany, Esslingen |
International | Yes, international applications are welcome |
Closure Date | Friday, May 31, 2024 |
Description: | |
Job Description: Research Associate for the CFD-Wind Energy Project, NG/2404 The Esslingen University of Applied Sciences is seeking a Research Associate for an immediate position within a wind energy research project at the Faculty of Applied Natural Sciences, Energy, and Building Technology, located at the Esslingen Campus. The global advancement of wind energy as a renewable and environmentally friendly source of power is underway. Increasingly, hilly, mountainous, and forested areas are being tapped for wind energy generation. Due to orography and land use, these areas often exhibit heterogeneous wind flows coupled with high turbulence. Thus, identifying suitable locations becomes a challenging task, demanding innovative simulation methods for the detailed characterization of meso- and micro-scale flow phenomena within the atmospheric boundary layer. Our Conditions: - Remuneration will be in accordance with the assigned duties and personal qualifications, up to Salary Group 13 TV‑L. - Employment volume may be up to 100%. - The position is initially limited until July 31, 2027. Your Responsibilities: - Development and implementation of numerical fluid flow simulation models (CFD) to describe fluid mechanics and thermodynamic phenomena within the atmospheric boundary layer, considering orography and land use. - Participation in a research project funded by the Federal Ministry for Economic Affairs and Climate Action (BMWK), aimed at submitting a doctoral thesis. - Publication of research findings in peer-reviewed journals and presentation at scientific conferences. Your Profile: - Master's degree in Engineering or Physics. - Enthusiasm for academic research in the field of wind energy. - Ability to work independently on innovative topics. - Strong interest in collaborating with other research groups in an interdisciplinary project. - Solid knowledge of fluid mechanics and thermodynamics. - Proficiency in CFD, preferably with OpenFOAM. - Additional knowledge of the Linux operating system and programming languages such as Python, C, or C++ is desirable. Application Process: Interested candidates should submit a detailed curriculum vitae (CV), a cover letter outlining their research interests and relevant experience, and contact information for at least two references to Prof. Dr. Hermann Knaus (hermann.knaus@hs-esslingen.de), and to Prof. Dr.-Ing. Rainer Stauch (rainer.stauch@hs-esslingen.de). Review of applications will begin immediately and will continue until the position is filled. Equal Opportunity Statement: The Esslingen University of Applied Sciences is committed to diversity, equity, and inclusion, and encourages applications from individuals of all backgrounds and identities. We are dedicated to creating a welcoming and inclusive environment where all members of our community can thrive. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19174 when responding to this ad. | |
Name | Hermann Knaus |
hermann.knaus@hs-esslingen.de | |
Email Application | Yes |
URL | https://www.hs-esslingen.de/personen/hermann-knaus/ |
Address | Campus Esslingen Stadtmitte Raum: S 05.210 Kanalstraße 33 73728 Esslingen |
Record Data: | |
Last Modified | 11:00:04, Friday, May 17, 2024 |
Job Record #19173 | |
Title | Modeling and numerical simulation of parietal heat transfer |
Category | PhD Studentship |
Employer | PROMES-CNRS |
Location | France, Perpignan |
International | Yes, international applications are welcome |
Closure Date | * None * |
Description: | |
Context In order to increase the efficiency of next-generation solar tower power plants, the operating temperature of the solar receiver must be increased to around 1000°C. Current transfer fluids cannot withstand these temperature levels, so new alternatives must be found. One way of achieving this goal is to use a gas-particle mixture as the transfer fluid within the solar receiver. Controlling gas-particle flows in future solar tower power plants is a major scientific challenge. Couplings between agitation, the two-phase nature of the flow and temperature make the physics particularly complex. This PhD thesis aims to improve the understanding and modeling of parietal heat transfer in these flow configurations. Objectives The objectives of the PhD project are as follows (presented in chronological order): 1. Development of the thermal part of the fluid-particle numerical simulation method using the Front-Tracking method of the TrioCFD software and a DEM approach. 2. Realization and analysis of anisothermal numerical simulations of dense gas/particle flows. 3. Development of heat transfer models between the solar receiver wall and the gas/particle mixture. Method In this PhD thesis, we will use the Front-Tracking method of the TrioCFD software to take into account the two-phase nature of the flow. This uses a moving surface mesh that explicitly represents the interfaces. It can therefore accurately describe any particle geometry and its interaction with the surrounding fluid. Recently, this method, originally developed for liquid/gas flows, has been adapted for fluid/particle flows (see [1] and [2]). Particle/particle interactions are modeled by Soft Sphere Collision Laws (SSCL), and the non-deformable nature of the particles is achieved by penalizing them with the viscosity of the solid phase. To simulate dense fluid/particle flows, by explicitly representing the particles, we use high-performance computing and several hundred or even thousands of processors. According to the literature, direct numerical simulation (DDS) of fluidized beds requires mesh sizes of at least forty meshes per particle diameter, in order to properly capture the viscous sublayer (friction) and the conductive sublayer (fluid/solid heat transfer). These simulations are therefore extremely costly numerically. However, to take into account the collective effects prevalent in this type of flow - and thus get closer to solar applications - it is essential to carry out simulations with more than 10,000 particles. The aim of this PhD thesis is to find the resolution that strikes the right balance between computational cost, accuracy and representativeness of flows in high-temperature solar receivers. To this end, the PhD student will carry out a mesh sensitivity study and a parametric study on the size of the domain and the number of particles simulated. He/she will build up an extensive database of anisothermal fluidized bed simulations resolved on a scale smaller than particle diameter. He/she will physically analyze the results obtained. Particular attention will be paid to parietal heat transfer. For example, the part of the flow exchanged with the particles and that exchanged with the gas will be evaluated. To do this, he/she will look at averages, standard deviations, Fourier transforms and probability densities of these heat fluxes as a function of flow properties. These analyses will enable the development of heat transfer models between the wall of the solar receiver and the gas/particle mixture. A first step could be the development of a correlation for the mean wall to bed heat flux. However, the aim of the PhD work is more ambitious, with the development, by upscaling, of a model that can be used in the Euler-Euler approach (two-fluid model - TFM). The challenge is to estimate the instantaneous local wall to bed heat flux from data such as solid volume fraction, gas and dispersed phase velocities and temperatures, and fluid and particle agitation. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19173 when responding to this ad. | |
Name | Adrien Toutant |
adrien.toutant@univ-perp.fr | |
Email Application | Yes |
URL | https://www.promes.cnrs.fr/projet-de-these-modelisation-et-simulation-numerique-des-transferts-thermiques-parietaux-en-ecoulements-gaz-particules-dans-les-recepteurs-solaires/ |
Record Data: | |
Last Modified | 22:42:21, Thursday, May 16, 2024 |
Job Record #19172 | |
Title | PhD studentship - Modelling bubble-particle interactions |
Category | PhD Studentship |
Employer | University of Birmingham |
Location | United Kingdom, Birmingham |
International | No, only national applications will be considered |
Closure Date | * None * |
Description: | |
Bubble-particle systems are encountered in a wide range of industrial and environmental applications (flotation, bioreactors, slurry bubble columns) but the complex dynamics and interactions make the design and operation of such systems particularly challenging. This collaborative project between the University of Birmingham and McGill University (Montreal, Canada) aims at better understanding bubble-particle dynamics for novel applications in recycling. This project is in collaboration with Professor Kristian Waters at McGill University, with the possibility of a research placement in his laboratories during the PhD. The student will also benefit from association with the EPSRC PREMIERE Programme Grant (https://premiere.ai) and be part of the PREMIERE research team including researchers from Birmingham, UCL and Imperial College. Froth flotation is an established method of separating minerals in a slurry based upon the relative hydrophobicity of the particles and while it has been used for decades in the minerals industry to recover high value materials, less attention has been paid to ridding water of low value ones (e.g. plastics). Surface active agents known as collectors are used to enhance the particle separation with the polar part of the molecule becoming attached to surface of the target particles, with the hydrophobic part forming a surface which is attracted to bubbles in the liquid. The target particles rise with the bubbles to form a froth, which overflows the cell to be recovered. To maintain stable, small bubbles, frothing agents known as frothers are added. The froth flotation principle has the potential to be used in a variety of novel applications outside its original use in the minerals industry, for example in the recycling of plastics or battery materials. However, there are many aspects of its operation which are still poorly understood which affect the overall efficiency of the process. This project will aim at investigating: - the dynamics of the frothing agent with the forming bubble interfaces: how the surface-active molecules alter the local interfacial tension and how Marangoni stresses may impact the performance of the froth and the attachment of the particles; - the interaction of the particles in the wake of the bubbles, where recent research has shown that this may be an important feature affecting the process selectivity, therefore efficiency. Both are critical to understanding the overall potential and efficiency of separation in novel applications. The research will involve a series of experimental work involving visualisation of particle and bubble dynamics in small-scale test cells and measurements of interfacial properties including dynamic interfacial tension. These will feed into a finite volume numerical model based on open-source libraries (OpenFOAM or Basilisk). The interfacial properties measured in the lab will be implemented and 3D numerical simulations of bubbly flows will be performed. The dynamics of the solid particles will also be coupled to the bubble dynamics and will be compared to the experiments in terms of flow structure, entrainment in the wake and adhesion to the interface. The understanding of these phenomena at reduced scale will help in developing empirical or data-driven models for improving larger scale models and the design of flotation columns. Funding: EPSRC DTP/College studentship in support of EPSRC PREMIERE Programme Grant (EP/T000414/1). Applicant: Applicants must be eligible for home fee status and should have a first-class degree or good 2:1 (or equivalent) in Chemical Engineering, Mechanical Engineering, Computing, Mathematics, or related areas. We are looking for an enthusiastic and self-motivated person with a keen interest in conducting numerical simulations, as well as experimental work in the lab. Deadline: The position will be filled as soon as a suitable person has been found; hence you are encouraged to apply as soon as possible (by email to t.abadie@bham.ac.uk or online https://www.birmingham.ac.uk/schools/chemical- engineering/postgraduate/phd-research.aspx). PhD Starting October 2024 or soon after. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19172 when responding to this ad. | |
Name | Thomas Abadie |
t.abadie@bham.ac.uk | |
Email Application | No |
URL | https://www.birmingham.ac.uk/schools/chemical-engineering/postgraduate/phd-research |
Record Data: | |
Last Modified | 14:33:36, Wednesday, May 15, 2024 |
Job Record #19171 | |
Title | PostDoc in CFD analysis of open and ducted wind turbines |
Category | Job in Academia |
Employer | University of Naples Federico II |
Location | Italy, Italy, Naples |
International | Yes, international applications are welcome |
Closure Date | * None * |
Description: | |
The research activity deals with the numerical analysis of the flow field through open and ducted wind turbines. The analysis will include both 3D blade-resolved, actuator line and actuator disk RANS simulations, which will be compared to the results of an LES actuator line approach. The objective is to investigate the effect of the main geometrical parameters and operating conditions on the device performance and the stability of the duct boundary layer. Net salary: 1817.58 euro/month Contract duration: 1 year The commencement of the contract is scheduled for the 1st of October 2024. The initial 3-4 months can be conducted remotely to facilitate the process of finding accommodation and addressing administrative matters. The company International Students Union (https://www.isu-services.it/it/universities/universita-degli-studi-di-napoli-federico-ii) could give you some assistance in locating accommodation in Naples. The service, offered on behalf of the University of Naples Federico II, is free of charge. More information on the application procedure (including the deadline) will be provided by mail. The evaluation process will be probably carried out in September and it is divided into two steps: an assessment of the candidates' curricula (publications and MSc final grades), and an online interview. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19171 when responding to this ad. | |
Name | Rodolfo Bontempo |
rodolfo.bontempo@unina.it | |
Email Application | No |
Record Data: | |
Last Modified | 11:06:51, Wednesday, May 15, 2024 |
Job Record #19170 | |
Title | Professor/Associate Professor/Postdoc |
Category | Job in Academia |
Employer | Wuhan University of Science and Technology |
Location | China, HuBei, Wuhan |
International | Yes, international applications are welcome |
Closure Date | Tuesday, December 31, 2024 |
Description: | |
武汉科技大学核磁共振与分子科学交叉研究院“多相流与固废热化学转化”团队海内外人才及师资博 士后招聘 一、招聘团队简介及需求 武汉科技大学核磁共振与分子科学交叉研究院“多相流与固废热化学转化”团队主要从事化工与能源 领域的反应性多相流、固体废弃物分离及热化学转化、过程集成及强化等方面的模拟和实验研究。 核心研究方向如下: 1、反应性多相流(热态流态化等反应性多相流系统的多尺度模拟(MD、CFD等)与实验(原位与非 原位测量、反应器操作与设计等)); 2、固体废弃物分离及热化学转化制备燃料(柴油、航空煤油等)、化学品(甲醇、烯烃等)和材料 (金属离子电池负极、超级电容器电极等)等; 3、过程集成及优化(流程模拟、系统集成、协同强化、构型强化、外场强化等)。 现因团队发展需要,急需招聘海内外人才及师资博士后多名。 二、招聘岗位及条件 招聘岗位:香涛学者学术带头人、香涛学者学术骨干、香涛青年百人(青年学术带头人、青年学术 骨干)、青年后备人才、师资博士后,具体如下: 1、香涛学者学术带头人 基本申报条件:(1)在学术研究领域从事前瞻性、创新性研究,已取得学术同行认可的标志性研究 成果,在研究领域内具有一定的学术影响力;(2)申报当年1月1日,原则上不超过40周岁(女性不 超过42周岁)。 基本支持待遇:基本薪酬每年45万元左右,享受业绩奖励绩效,安家费70-160万元,科研资助经费 60-160万元,直聘教授(长聘岗)。 2、香涛学者学术骨干 基本申报条件:(1)在学术研究领域从事前瞻性、创新性研究,已取得学术同行认可的标志性研究 成果,在研究领域内具有一定的学术影响力;(2)申报当年1月1日,原则上不超过40周岁。 基本支持待遇:基本薪酬每年30万元左右,享受业绩奖励绩效,安家费18-50万元,科研资助经费 30-70万元,直聘教授或副教授(长聘岗)。 3、香涛青年百人 基本申报条件:(1)拥有海内外知名高校、科研院所、企业博士学位或博士后科研经历,已经取得 较好的学术成果,其学术见解或者技术成果的独创性和原创性较高;(2)申报当年1月1日,青年学 术带头人原则上不超过38周岁,青年学术骨干原则上不超过36周岁。 基本支持待遇:基本薪酬每年28-45万元,享受业绩奖励绩效,安家费18-130万元,科研资助经费 30-160万元,直聘教授或副教授(长聘岗)。 4、青年后备人才 基本申报条件:(1)拥有海内外知名高校、科研院所、企业博士学位或博士后科研经历,已经取得 一定的学术成果;(2)申报当年1月1日,原则上不超过34周岁。 基本支持待遇:基本薪酬每年16-21万元,享受业绩奖励绩效,提供一定金额的安家费和科研资助经 费,聘为准聘制讲师(优秀者可聘为准聘制副教授)。 5、师资博士后 基本申报条件:(1)获得博士学位时间不超过3年,具备较强的科研能力,取得较高水平的研究成 果;(2)申报当年1月1日,原则上不超过32周岁。 基本支持待遇:支持三年,基本薪酬每年20-26万元,享受业绩奖励绩效,住房补贴每月1800元,提 供科研资助经费10-15万元,考核达到要求后可申请转准聘制教师或香涛青年百人。 三、应聘方式 应聘者请将个人详细简历及其他支撑材料的电子版(主要包括个人基本信息、经历背景、研究方 向、主要学术成果及影响等)发送给罗老师:haoluo@wust.edu.cn,我们保证在收到应聘邮件一周 内给与回复。 满足申报条件、达成意向协议的,学校将优先推荐申报国家、地方各类人才项目,入选者纳入“楚才 卡”管理,持卡人在省内按照有关政策规定可享受出入境、落户、金融、税收优惠、医疗、养老等诸 多高效便捷的专享服务。更多待遇保障可参考: https://mp.weixin.qq.com/s/ZpUdPaMqN7orvNQAd_wlEg。海外人才可参考: https://www.wust.edu.cn/info/1501/418642.htm。 |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19170 when responding to this ad. | |
Name | Hao Luo |
haoluo@wust.edu.cn | |
Email Application | Yes |
URL | https://hxyhg.wust.edu.cn/info/1601/24212.htm |
Record Data: | |
Last Modified | 06:10:18, Wednesday, May 15, 2024 |
Job Record #19169 | |
Title | 12569 - Post-Doc or Jr Scientist on Ocean Wave Modelling |
Category | Contract Work |
Employer | CMCC |
Location | Italy, Italy, Lecce/Bologna |
International | Yes, international applications are welcome |
Closure Date | Saturday, June 15, 2024 |
Description: | |
Job Opening cod. 12569 CMCC Position Post-Doc or Jr Scientist on Ocean Wave Modelling (Deadline: June 15th, 2024) ABOUT US The CMCC Foundation is a scientific research center on climate change and its interactions with the environment, society, the world of business, and policymakers. Our work aims to stimulate sustainable growth, protect the environment, and develop strategies for the adaptation and mitigation of climate change. WHAT WE ARE LOOKING FOR Our Institute for Earth System Predictions (IESP) is hiring a talented, motivated and proactive Post-Doc or Junior Scientist to work in the Global Coastal Ocean division in the framework of the EDITO-ModelLab and FOCCUS projects. The position is open for an Ocean Wave Modeller to join our dynamic team and contribute to cutting-edge research in wave modelling at both global and coastal scales. Workplace location: Lecce or Bologna ROLE AND RESPONSIBILITIES The position involves conducting research activities focused on global and coastal processes, understanding the connection between different spatial scales with a seamless continuum approach. The study will mainly investigate extreme events, with a special focus on waves and storm surges, with the aim of contributing to the design of mitigation and adaptation strategies against climate change. The work will include developing and implementing wave spectral models and coupling with circulation models, performing high-resolution modeling simulations using unstructured grids, calibrating models with observational data, and applying downscaling techniques both dynamic and based on Artificial Intelligence. Furthermore, it will contribute to improving the complexity of our coupled numerical models, including new physics, and investigating interactions between waves, currents, atmosphere, and ice. The study will focus on short-term forecasting and long-term climate scenarios, employing both deterministic and ensemble approaches. REQUIREMENTS We are seeking candidates with a strong background in wave modelling and coastal nearshore processes. Proficiency in programming languages and experience with processing and interpreting simulation-based and observational datasets are essential for success in this role. PhD or equivalent experience in Physical Oceanography, Coastal Engineering, Computational Fluid Dynamics or other scientific disciplines dealing with numerical modelling (e.g. Physics, Mathematics) Experience in developments and implementations of ocean wave models Knowledge of coastal processes and high-resolution modelling, preferably based on unstructured mesh Good knowledge and skills in programming language, preferably Python and Fortran/C. Knowledge of UNIX/Linux operating systems and script languages (i.e. *nix shell) Knowledge of parallel programming on HPC architectures Fluency in English Experience in ensemble forecasting is not mandatory but will be a plus Knowledge of general ocean circulation models is a plus and will be positively evaluated DURATION, COMPENSATION & BENEFITS The appointment period will be initially of 12 months starting from June 2024, renewable for 24 months additional months pending a positive evaluation. Tenure can be granted from 2 to 4 years after being appointed as a junior researcher. The gross annual salary range is from 32 to 38K Euros for the PostDoc and 35 to 45K for the Junior Scientist, depending on qualification and working experience. Welfare package Flexible working time Support during the immigration process, if needed Belonging to legally protected categories (ex L. 68/99) will constitute a preferential condition. Some fiscal benefits could be applied for repatriated workers or foreign researchers/professors, having the requirements defined by Dlgs 147/2015 (for repatriates) or Dl 78/2010 (for foreigners). CMCC is an equal-opportunity employer. We evaluate qualified applicants without regard to race, color, religion, sex, sexual orientation, gender identity, national origin, disability, veteran status, age, familial status, and other legally protected characteristics. Please omit from your CV any data you or we might consider discriminatory. This job announcement is an invitation to express interest in the above-mentioned CMCC Position. |
|
Contact Information: | |
Please mention the CFD Jobs Database, record #19169 when responding to this ad. | |
Name | GOCO |
recruiting@cmcc.it | |
Email Application | Yes |
URL | https://cmccfoundation.applytojob.com/apply/45up6jYq8c/12569-PostDoc-Or-Jr-Scientist-On-Ocean-Wave-Modelling?source=Our%20Career%20Page%20Widget |
Record Data: | |
Last Modified | 14:27:24, Tuesday, May 14, 2024 |