Author: nishuna

Purpose:

To contribute to student success by delivering high-quality teaching, supporting curriculum development, and advancing research within the field of Fire Safety Engineering.

Education:

PhD in fire safety/protection engineering, mechanical engineering, or other relevant engineering disciplines.

Minimum Qualifications:

• Minimum 3 years of teaching experience in Higher Education.
• Demonstrated research experience with a strong publication record in relevant fields.
• Familiarity with the implementation of quality assurance policies and procedures is preferred.
• Membership in a relevant professional organization (e.g., MIFireE, AIFireE, MSFPE, PMSFPE).
• Certified Fire Protection Specialist (CFPS) is preferred.
• Industrial experience in fire safety engineering is preferred.

Skills:

• Ability to work effectively as part of a team.
• Excellent written and verbal communication skills.
• Strong time management and organizational skills.
• Accurate record keeping and documentation.
• Creativity, initiative, and enthusiasm in teaching and research activities.

Work Duties

The Assistant Professor position is designed to help the faculty member develop independence as both a researcher and an educator. The role primarily involves research, teaching, and professional development.

Key Responsibilities:

• Teach courses at the undergraduate and postgraduate levels.
• Conduct research within the subject area.
• Supervise student projects and theses.
• Actively seek external research funding.
• Collaborate with industry and engage with the wider community.
• Perform administrative tasks related to the duties listed above.

Type of employment/Contract: Full time position

Salary: Monthly

Number of positions: 3

Country: Oman

Interested applicants are requested to send their CVs to HR@icem.edu.om

Employer / Host Institution
Universitat Politècnica de Catalunya (UPC), CERTEC research group, Department of Chemical
Engineering, Barcelona, Spain

Supervision / PI
Dr. Ronan Paugam

Location
Barcelona, Spain

Sector / Type
Academic / Full time

Relevant Divisions / Fields
Atmospheric Sciences, Geosciences Instrumentation & Data Systems, Natural Hazards

Level / Experience
Experienced, Post-doctoral

Salary / Contract
Minimum €36,000 per year (gross), remunerated over 14 payments (12 months + two extras in
June and December).
Contract until 31 May 2028.

Required Education
PhD

Application Deadline
Open until the position is filled

Background

This position is part of the EUBURN project (Southern EUrope Biomass BURNing), which advances understanding of extreme wildfires in southern Europe, their climate and air quality impacts, and develops forecasting tools for direct (fire spread) and indirect (air pollution) risks. The project couples biodiversity, fire, and atmospheric processes across scales and aims to support operational services via measurement campaigns and open data sharing. A first campaign (SILEX) in July–August 2025 has tested instruments aboard the SAFIRE ATR-42 aircraft. A subsequent campaign (EUBURN-RISK) is planned in summer 2027, including drones, aircraft, ground platforms, and enhanced monitoring across France, Spain, and Portugal. Partner institutions include Météo-France (CNRM), AEMET, IPMA, University of Évora, UPC, and several other European and operational agencies.

UPC (CERTEC) focuses on fire observation, wildland and WUI fire behavior, fire modeling, and
risk analysis. The successful candidate will contribute to the fire observation component under
Dr. Paugam’s supervision.

Job Description / Tasks

The tasks of the post-doctoral researcher include:

• Process data from the 2025 SILEX campaign: compute Fire Radiative Power (FRP) using the midwave infrared (MWIR) camera aboard SAFIRE ATR-42, and compare with satellite sensors (e.g. VIIRS, SLSTR, FCI).
• Delineate fire fronts and compute Rate of Spread (ROS) from IR observations. Build on earlier methods developed by Dr. Paugam for helicopter observations; extend to operational scenarios. Fire front segmentation will be enhanced via machine learning, using EMA-INFACO’s data archive.
• Develop drone payload for fire activity observation during night flights: detect hotspot locations and intensities in real time. A key challenge is geolocating fire activity despite limited IMU accuracy; a spring 2026 prescribed burn in Andalusia will support required precision estimation, and a prototype will be tested in summer 2026 with EMA-INFACO.
• Facilitate integration of fire observation outputs with modeling teams within the EUBURN consortium.
• Assist in preparation and execution of the 2027 field campaign.
• Disseminate results via scientific publications, conference presentations, and stakeholder communications; contribute to project reports and internal workshops.

Candidate Profile / Requirements

• Holds a PhD in a relevant domain (e.g. remote sensing, fire science, atmospheric science, applied physics, engineering)
• Experience in satellite/airborne/infrared remote sensing, fire behavior monitoring, or data
  processing
• Skills in image processing, machine learning, geospatial data, and programming
• Ability to work independently, initiative in research, and effective communication skills
• Experience or interest in integrating observational data into modeling frameworks

How to Apply

Submit a CV and cover letter to ronan.paugam@upc.edu.

Applications are invited for a fully funded PhD scholarship (up to three years) in the Department of Civil and Environmental Engineering (University of Canterbury UC, New Zealand), under the main supervision of Dr Andres Valencia and co-supervision of academics of the fire engineering group at the UC. The project will be undertaken in close collaboration with Fire and Emergency New Zealand, who are providing funding support.

Description

Water is the most widely used agent for fire suppression, yet critical questions remain on how to optimise delivery methods for different fuels and scenarios. This PhD will focus on experimental and analytical investigations of water-based suppression systems, with emphasis on suppression performance, which can include:

• Firefighting hose streams: studying suppression against well-defined fires (e.g. known heat release profiles) and streams (e.g. well-known droplet distribution and flux).
• Sprinkler systems: studying dispersion and suppression against fires (e.g. known heat release profiles.) Characterizing dispersion flux.
• Emerging technologies (optional depending on additional funding and external collaborators): exploring the feasibility of drone-mounted water delivery systems for rapid initial attack.

The student will conduct laboratory-scale suppression experiments using fuels with clearly defined burning characteristics and heat release rate profiles. Experiments will be designed to expose fires to precisely characterised water fluxes, allowing quantitative assessment of suppression effectiveness. In parallel, the student will develop and apply analytical modelling frameworks (e.g., Valencia et al. 2021a and Valencia et al. 2021b) to interpret results and generalise findings beyond the lab scale. The results will directly support the development and refinement of standards and codes of practice, such as the NZ firefighting water supplies code (e.g. SNZ PAS 4509).

Expected outcome

The successful candidate will:

• Develop experimental protocols for assessing suppression effectiveness with hoses, sprinklers, and novel platforms.
• Quantify relationships between water application rate, droplet characteristics, and fire suppression outcomes.
• Provide data and insights to inform design standards, operational guidelines, and emerging technologies for fire services.
• Present results at leading international conferences and contribute to peer-reviewed publications.

Candidate Profile

Preferred applicants will have:

• A strong background in fire engineering, mechanical engineering, fluid dynamics, or related fields.
• Demonstrated experimental skills, ideally in combustion, heat transfer, or suppression systems.
• Strong analytical and coding ability (Python/Matlab/R) for processing experimental data.
• Interest in translational research that links laboratory experiments with real-world firefighting practice

Scholarship

Provider: Fire and Emergency New Zealand
Amount: NZD 32,000 per annum + domestic tuition fees (up to 4 years)
Location: Department of Civil and Environmental Engineering, University of Canterbury, Christchurch, New Zealand

Closing date: 7th November 2025. To apply, please send your CV, motivation letter and Transcript to Dr. Andres Valencia: andres.valencia@canterbury.ac.nz

The Department of Fire Protection Engineering at the University of Maryland, College Park (UMD),
invites applications for one Postdoctoral Research Associate position and one Ph.D. research
assistantship position in computational modeling of Wildland Urban Interface (WUI)
conflagrations.

The spread of wildfires into WUI communities and their progression into urban fires has severely affected
our communities, resulting in loss of life and extensive damage to properties and infrastructure. A key
element in reducing these impacts and developing effective wildfire adaptation strategies is the ability to
understand and accurately model wildfire spread to and within WUI areas. The main research goal for
both roles is to enhance the mathematical representation of thermal degradation of solid fuel sources and
flaming and smoldering combustion processes in fire simulators and to extend their use to modeling WUI
fires at large spatial and temporal scales. The project will primarily contribute to the advancement of the
open-source fire modeling ecosystems, such as Fire Dynamics Simulator (FDS), and apply the model to
further our understanding of WUI fire spread using high-resolution physics-based simulations.

Job Description

● Postdoctoral Position: The successful candidate will collaborate with our team to develop a
framework for urban fire modeling in FDS; more specifically, building a modular framework for
constructing the computational domain and implementing a firebrand generation module in the
solver. The efforts will involve the integration of large-scale datasets in a computationally
efficient paradigm to enhance the applicability of the simulators in WUI fires.

● Ph.D. Position: The successful candidate will work within a collaborative team to implement a
novel char oxidation and smoldering-to-flaming transition model and conduct high-resolution
simulations and validation studies of WUI fire scenarios.

Qualifications

● Expertise in thermal degradation of solid fuel sources and combustion (reactive flow) modeling.
● Strong background in computational fluid and fire dynamics.
● Demonstrated expertise in fire modeling using Fire Dynamics Simulator (FDS).
● Strong programming skills in FORTRAN; familiarity with CUDA is an advantage.

Appointment

● The postdoctoral position is an 18-month appointment, renewable for an additional 12 months
based on performance and availability of funding.
● The Ph.D. position is a 36-month appointment, renewable until graduation.
● The Department of Fire Protection Engineering at UMD fosters interdisciplinary collaboration
with academic and industry partners and is committed to advancing fire and wildfire science.

How to apply

Submit your application package via email before October 15 to Prof. Arnaud Trouve
(atrouve@umd.edu) and Ali Tohidi (atohidi@umd.edu).

Applications must include:
● A cover letter elaborating on your interests, expertise, and why you are a good fit.
● Your full CV, along with an official copy of your transcripts/degree
● Email addresses of at least three references.

Applications are invited for two fully funded (four years maximum) PhD scholarships in the department of Civil and Natural Resources Engineering (New Zealand), to work on overpressure events in combustible compartment under the supervision of Dr Andres Valencia, Dr Aatif Khan and Emeritus Prof. Charles Fleischmann in the context of the Project “Investigating Overpressure Events in Combustible Compartments” funded by Fire Safety Research Institute.

Description
Fires are inherently unexpected and unpredictable events that threaten both the occupants and firefighters. One of the most unexpected phenomena in a compartment fire is an overpressure event (OPE) that can occur with no apparent flammable liquid or gas within the building. Sometimes referred to as a smoke explosion or backdraft, an OPE represents a significant danger to firefighters operating within the building due to its explosive nature that can cause burns and traumatic injuries. In this project, OPE in combustible compartment will be experimentally investigated in the state-of-the art fire facilities at UC. The student will design and perform experiments to

1. Determine the ventilation openings factors and geometry that result in an OPE in a combustible compartment.
2. Evaluate the compartment conditions (temperature and gas species) immediately preceding an OPE.
3. Quantify the intensity of an OPE based on the volume of the external fireball, compartment pressure, and maximum opening velocity.
4. Evaluate the impact of vertical ceiling obstruction, i.e. joists/rafters, on the intensity of an OPE over a range of opening factors.

Selected candidates will attend technical conferences and symposia to present their research results.

It is preferred that the candidates demonstrate strong experimental background in fire engineering and strong analytical skills using Python/R/Matlab.
Scholarship
Provided by: Fire Safety Research Institute
Amount: $32,000 per annum + tuition fees (New Zealand Dollars)
Closing date: 13th October 2025.
To apply, please send your CV, motivation letter and Transcript to Dr. Aatif Khan: aatif.khan@canterbury.ac.nz

Supervision: Jean-Louis Consalvi¹, Dominique Morvan¹, Gilbert Accari³ & Pierre Boivin²

1 Aix-Marseille Université, IUSTI/UMR CNRS 7343, 5 rue E. Fermi, 13453 Marseille
Cedex 13, France
2 Aix Marseille Univ, CNRS, IUSTI, Marseille, France
3 Lebanese American University (LAU), P.O. Box 36, Byblos, Lebanon

Description of the Post Doc

This research project will be funded by the “Institute for Mechanical Engineering” of Aix-Marseille University. Once selected by the reaserch team, the project and the candidate will be evaluated in a sigle round in November, 2025 for a final decision in December, 2025. The Post Doc will last up to 24 months (12 months renewable once). He/she will benefit from an additional support budget of 5k euros/year (for symposium participation, international collaboration missions, small equipment, etc.).

This research project investigates firebrand spotting, a critical mechanism for fire spread in both wildland and wildland-urban interface (WUI) fires. Firebrands, which are flaming or glowing embers, are generated by burning vegetation or structures. These embers are then lifted by fire plumes and carried downwind, where they can ignite new fires or structures far from the main flame front [1]. Spotting significantly influences fire spread patterns because it acts over much longer distances than heat transfer mechanisms from flames to unburnt vegetation. In addition, it is estimated that more than half of the homes destroyed in WUI fires are due to firebrands [2].

The complex problem of spot wildfires can be broken down into three individual processes:

1. Firebrand generation and thermochemical state: How firebrands are produced and their initial chemical and thermal properties [3].

2. Transport and thermochemical evolution during flight [4].

3. Ignition upon landing: the initiation of smoldering or flaming combustion in a receptive fuel bed after the firebrand lands [1].

Stochastic models have been developed to model firebrand spotting [5, 6, 7]. These models are particularly well-suited for integration into operational fire spread models, providing real-time capabilities that are highly valuable for operational use and decision-making in fire management [7]. The stochastic spotting models rely on model parameters that are difficult to estimate and strongly depend on the weather (wind speed, ambient temperature, relative humidity) and the vegetation (type, moisture content).

This project research aims to combine CFD modeling of the spotting process with statistical learning methods to explore how the stochastic model parameters evolve with the most sensitive input data. The CFD simulations of the spotting process will be performed with FireStar3D, a fully physical, three-dimensional wildfire simulation model, co-developed at M2P2, the Lebanese American University and Toulon University. [8]. A particular fundamental focus of this project will be on developing ignition models for fuel beds by firebrands. This aspect is crucial as it represents the least understood of the three processes previously described in firebrand spotting.

Candidate profile

The desired candidate must hold a PhD related to combustion, fire research, and numerical simulation. The candidate will work in a research laboratory environment and will have to demonstrate autonomy, pragmatism, and a proactive approach.

• Contact and candidature: Jean-Louis Consalvi (jean-louis.consalvi@univ-amu.fr).

References

[1] A. C. Fernandez-Pello, Wildland fire spot ignition by sparks and firebrands, Fire Safety J. 91 (2017) 2–10.

[2] S. E. Caton, R. S. P. Hakes, D. J. Gorhan, A. Zhou, M. J. Gollner, Review of pathways for building fire spread in the wildland urban interface part i: exposure conditions, Fire Technol. 53 (2017) 429–473.

[3] S. L. Manzello, S. Suzuki, M. J. Gollner, A. C. Fernandez-Pello, Role of firebrand combustion in large outdoor fire spread, Prog. Ener. Combust. SCi. 76 (2020) 100801.

[4] N. Sardoy, J. L. Consalvi, B. Porterie, A. C. Fernandez-Pello, Modeling transport and combustion of firebrands from burning trees, Combust. Flame 150 (2007) 151–169.

[5] B. Porterie, N. Zekri, J. P. Clerc, J. C. Loraud, Modeling forest fire spread and spotting process with small world networks, Combust. Flame 149 (2007) 63–78.

[6] E. Mastorakos, S. Gkantonas, G. Efstathiou, A. G. b, A hybrid stochastic lagrangian – cellular automata framework for modelling fire propagation in inhomogeneous terrains, Proc. Combust. Inst. 39 (2023) 3853–3862.

[7] G. Efstathiou, S. Gkantonas, A. Giusti, E. Mastorakos, C. M. Foale, R. F. c, Simulation of the december 2021 marshall fire with a hybrid stochastic lagrangian-cellular automata model, Fire Safety J. 138 (2023) 103795.

[8] N. Frangieh, G. Accary, D. Morvan, S. Meradji, O. Bessonov,Wildfires front dynamics: 3d structures and intensity at small and large scales, Combust. Flame 211 (2020) 54–67.

Graduate Research Assistantships available in the FPE Department at UMD

The Department of Fire Protection Engineering (FPE) provides support for several Graduate Research Assistantships (GRAs) every year. The support is provided to outstanding, incoming Master of Science (MS) students, domestic or international, in the UMD FPE Department and is awarded on a competitive basis. The support goes to individuals who have already applied or will be applying to the FPE MS program. Incoming students are defined as students who intend to start their MS program in Summer 2025, Fall 2025, Winter 2026 or Spring 2026.

In 2025, we have the following opportunities:

• One John L. Bryan Award: this GRA Award is funded by the John L. Bryan endowment. The John L. Bryan Awardee is expected to complete his/her proposed research project under the supervision of members of the Faculty of the FPE Department. A requirement in the Award is that the Awardee agrees to serve as a Teaching Assistant (TA) for one course during each Fall and Spring term (1/2 TA position). The duration of the Award is up to 16 months.
• One or two UL Fellowships: these GRA Fellowships are funded by UL Fire Safety Research Institute (FSRI). The UL Fellows are expected to complete their proposed research project under the supervision of FSRI research engineers with advising/support from a member of the Faculty of the FPE Department. The duration of the Fellowship is up to 16 months. The research work is typically performed off-campus, at the FSRI office located in Columbia, MD; some of the work could involve travel (which would be supported by UL).
• One FRA Fellowship: this GRA Fellowship is funded by Fire Risk Alliance (FRA). The FRA Fellow is expected to complete his/her proposed research project under the supervision of FRA research engineers with advising/support from a member of the Faculty of the FPE Department. The duration of the Fellowship is up to 16 months. The research work is typically performed off-campus, at the FRA office located in Rockville, MD; some of the work could involve travel (which would be supported by FRA).

Identification of a research project is welcome but is not required during the application process. The research project will be defined by members of the FPE Faculty (John L. Bryan Award), or by engineers from UL FSRI (UL Fellowships) or from FRA (FRA Fellowship) in collaboration with members of the FPE Faculty.

Interested applicants should provide a one-page statement of purpose explaining their interest in the FPE MS degree program in general and in fire research in particular. Applicants should indicate which GRA opportunity they are applying for (i.e., for the John L. Bryan Award and/or a UL Fellowship and/or a FRA Fellowship). Applicants should also provide an updated résumé and (official or unofficial) copies of transcripts. Applications should be submitted via email to Dr. Arnaud Trouvé, Professor and Chair in the FPE Department (atrouve@umd.edu). The deadline for application is Friday February 28, 2025. Decisions on applications will be made by Selection Committees made up of members of the FPE Faculty and engineers from UL FSRI (UL Fellowships) or from FRA (FRA Fellowship). Decision will be made in early March.

Because of a possible delay between the time of the announcement of the Award and Fellowships (March 2025) and the start of the MS program (possibly as late as Spring 2026), changes to the original plan submitted by the GRA recipients may be allowed (e.g., changes in the proposed research area, the start date of the MS program, etc); in that case, changes need to be authorized by the Chair of the FPE Department.