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- Aufgaben: Develop a physics-based model for reliability in advanced transistor structures.
- Arbeitgeber: Join imec, a leader in nanoelectronics and digital technologies.
- Mitarbeitervorteile: Collaborate with top researchers and industry partners; gain hands-on experience.
- Warum dieser Job: Tackle real-world challenges in semiconductor technology while enhancing your skills.
- Gewünschte Qualifikationen: MS in physics, electrical engineering, or materials science; solid programming skills required.
- Andere Informationen: Reference code 2024-032 needed for application.
Das voraussichtliche Gehalt liegt zwischen 36000 - 60000 € pro Jahr.
Multi-scale Modeling of Reliability Concerns in Ge and SiGe Transistors
The breath-taking development of modern nanoelectronic devices together with the arrival of the mobile era and the Internet of Things raised new challenges and requirements to the next generation transistor structures. One of the major demands is long battery lifetime and tackling this task requires improvement of the channel control, a steeper sub-threshold slope, and hence an improved ratio between ON and OFF currents.
Fulfilling these requirements relies on the introduction of new device structures, such as fin, nanowire, nanosheet, and forksheet field-effect-transistors (fin, NW, NS, and FS FETs, respectively) as well as novel channel materials. Among the elemental semiconductors, Ge has the highest hole mobility and can be grown epitaxially, resulting in strained Si[1-x]Ge[x] layers. This makes Ge/SiGe the most attractive material for p-channel FETs. However, introduction of any new device can be hindered by reliability concerns. Thus, the ability to fully understand, correctly model, and accurately predict how reliable future devices will behave is as crucial as the ability to fabricate them.
The main goal of this PhD project is to develop a comprehensive physics-based model which can accurately reproduce degradation characteristics of fin, NW, NS, and FS FETs on Ge/SiGe. In these devices, the most detrimental degradation concerns are bias temperature instability (BTI) and hot-carrier degradation (HCD). Both phenomena originate from a collective response of defects activated by an external driving force (such as applied bias, increased temperature, etc.). The situation is further complicated by the confined channels of these novel transistor architectures, giving rise to another detrimental effect, so-called self-heating (SH). Since defect generation is a temperature activated process, SH can substantially accelerate BTI and HCD and therefore these three degradation phenomena should be modeled within an entire framework.
Special attention will also be paid to recovery/healing of BTI and HCD at elevated temperatures. Understanding and modeling of these mechanisms should help us elaborate strategies to accelerate device/circuit recovery. The basis of this modeling framework will be the set of underlying microscopic defect physics. This information will be obtained with density functional theory calculations. Reliability effects will be considered as various responses of defects triggered by different driving forces. This will be addressed by employing transport simulations and modeling of the degraded devices using traditional TCAD tools. Our model should be able to reproduce and predict changes of transistor characteristics and will be validated over a broad spectrum of devices and stress conditions.
We expect that the applicant has in-depth knowledge in the field of solid-state /semiconductor/semiconductor device physics, solid programming skills (C/C++ and/or Python), eagerness to obtain exciting results and learn. Within this multiscale cross-disciplinary project, the PhD student will be part of a large imec team working in collaboration with academic research centers as well as with industrial partners and therefore good team player skills are desired.
- Required background: MS degree in physics, electrical engineering, or materials science
- Type of work: 70% modeling, 20% experimental, 10% literature
- Supervisor: Michel Houssa
- Daily advisor: Stanislav Tyaginov
The reference code for this position is 2024-032. Mention this reference code on your application form.
Multi-scale Modeling of Reliability Arbeitgeber: GE Deutschland Holding GmbH
Kontaktperson:
GE Deutschland Holding GmbH HR Team
StudySmarter Bewerbungstipps 🤫
So bekommst du den Job: Multi-scale Modeling of Reliability
✨Tip Number 1
Make sure to familiarize yourself with the latest advancements in Ge/SiGe transistor technology. Understanding the current challenges and innovations in this field will not only help you during the interview but also show your genuine interest in the project.
✨Tip Number 2
Brush up on your programming skills, especially in C/C++ and Python. Being able to demonstrate your coding proficiency can set you apart from other candidates, as solid programming skills are crucial for this role.
✨Tip Number 3
Highlight any previous experience you have with modeling and simulations, particularly in semiconductor device physics. Providing specific examples of your work in this area can greatly enhance your application.
✨Tip Number 4
Since this position involves collaboration with both academic and industrial partners, emphasize your teamwork skills. Share experiences where you successfully worked in a team setting to achieve a common goal.
Diese Fähigkeiten machen dich zur top Bewerber*in für die Stelle: Multi-scale Modeling of Reliability
Tipps für deine Bewerbung 🫡
Understand the Project: Make sure to thoroughly read the job description and understand the key aspects of the PhD project. Familiarize yourself with terms like bias temperature instability (BTI), hot-carrier degradation (HCD), and self-heating (SH) as they are crucial for your application.
Highlight Relevant Experience: In your CV and cover letter, emphasize any experience you have in solid-state physics, semiconductor device physics, or programming skills in C/C++ and Python. Provide specific examples of projects or research that relate to the modeling and experimental work described.
Reference Code Inclusion: Don’t forget to mention the reference code 2024-032 in your application form. This is important for ensuring your application is processed correctly.
Show Team Collaboration Skills: Since the position involves working within a large team and collaborating with academic and industrial partners, make sure to include examples of your teamwork skills and experiences in your cover letter.
Wie du dich auf ein Vorstellungsgespräch bei GE Deutschland Holding GmbH vorbereitest
✨Show Your Technical Expertise
Make sure to highlight your in-depth knowledge in solid-state physics and semiconductor device physics. Be prepared to discuss specific projects or experiences where you applied this knowledge, especially related to Ge/SiGe transistors.
✨Demonstrate Programming Skills
Since solid programming skills in C/C++ and/or Python are crucial for this role, be ready to talk about your programming experience. You might even want to prepare a small coding example or discuss a project where you utilized these languages.
✨Emphasize Team Collaboration
This position involves working within a large team and collaborating with academic and industrial partners. Share examples of how you've successfully worked in teams, highlighting your communication skills and ability to collaborate effectively.
✨Prepare for Technical Questions
Expect technical questions related to modeling degradation phenomena like BTI and HCD. Brush up on relevant theories and be ready to explain how you would approach modeling these effects in novel transistor architectures.