Brad Farmilo | Ecology | Editorial Board Member

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Dr. Brad Farmilo | Ecology | Editorial Board Member

Senior Scientist | Arthur Rylah Institute for Environmental Research | Australia

Dr. Brad Farmilo is a dedicated environmental scientist whose work spans ecological conservation, biodiversity management, and the study of plant community dynamics in fragmented landscapes. With a strong academic foundation in biological and environmental sciences, he has built a career marked by scientific leadership, field-based research, and collaborative problem-solving. His professional experience includes guiding multidisciplinary teams, designing and delivering ecological monitoring programs, conducting advanced data analyses, and contributing to conservation strategy development. His research has explored themes such as weed management in sensitive habitats, ecological responses within forest fragments, and patterns of species distribution across altered landscapes. Through publications in respected scientific journals, he has provided evidence-based insights that support conservation planning and environmental policy. Dr. Farmilo’s influence is reflected not only in his scientific outputs but also in his commitment to mentoring emerging researchers and fostering collaborative projects that bridge science and practice. His expertise with statistical analysis and geospatial tools enhances the precision and impact of his findings, while his contributions to grant development underscore his role in advancing innovative environmental research. Widely regarded for his thoughtful approach to ecological challenges, Dr. Farmilo continues to shape the understanding of landscape-scale biodiversity processes and supports the development of sustainable conservation initiatives that benefit both ecosystems and the scientific community.

Profiles: Scopus | Google Scholar

Featured Publications

Farmilo, B. J., Melbourne, B. A., Camac, J. S., & Morgan, J. W. (2014). Changes in plant species density in an experimentally fragmented forest landscape: Are the effects scale-dependent? Austral Ecology, 39(4), 416–423.

Farmilo, B. J., & Nimmo, D. G., & Morgan, J. W. (2013). Pine plantations modify local conditions in forest fragments in southeastern Australia: Insights from a fragmentation experiment. Forest Ecology and Management, 305, 264–272.

Schultz, N., Keatley, M., Antos, M., Wong, N., Moxham, C., Farmilo, B., … (2017). The golf ball method for rapid assessment of grassland structure. Ecological Management & Restoration, 18(2), 134–140.

Morgan, J. W., & Farmilo, B. J. (2012). Community (re)organization in an experimentally fragmented forest landscape: Insights from occupancy–scale patterns of common plant species. Journal of Vegetation Science, 23(5), 962–969.

Moxham, C., Dorrough, J., Bramwell, M., & Farmilo, B. J. (2016). Fire exclusion and soil texture interact to influence temperate grassland flora in south-eastern Australia. Australian Journal of Botany, 64(5), 417–426.

Morteza Hazbei | Built Environment Ecology | Best Researcher Award

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Dr. Morteza Hazbei | Built Environment Ecology | Best Researcher Award

Research associate | Concordia University | Canada

Dr. Morteza Hazbei is a dedicated scholar and practitioner in architecture and urban design, focusing on sustainable architecture, urban livability, inclusive urbanism, and resiliency. His work integrates parametric and computational design with a deep understanding of contextual influences in the built environment, aiming to optimize architectural solutions for functionality, sustainability, and social value. He has contributed to both academic and professional spheres, engaging in innovative research projects that explore the intersections of design, biodiversity, livability, and quality in urban spaces. His research investigates the impact of digital and algorithmic tools on architectural practice, addressing challenges related to context, optimization complexity, and environmental performance. In addition to his research, he has developed and taught graduate and undergraduate courses, emphasizing sustainable and equitable design principles, and has supervised numerous student projects and theses. Hazbei’s professional practice includes architectural design and project supervision, emphasizing sustainable and contextually responsive approaches. He has published extensively, including peer-reviewed journal articles, book chapters, and conference presentations, focusing on parametric design, eco-didactic approaches, and quality in the built environment. His work has been recognized for its academic excellence and societal relevance, contributing to knowledge mobilization, public engagement, and interdisciplinary collaboration. Active in academic service, he has served as a reviewer for multiple journals, participated in jury panels, moderated conferences, and contributed to committees that promote research dissemination and graduate student representation. His scholarship bridges theory, technology, and practice, fostering innovative approaches to architecture and urban design that prioritize sustainability, livability, and social impact.

Profile: Scopus | Orcid | Google Scholar

Featured Publications

Hazbei, M., Yesayan, T., Yu, N., Hutt-Taylor, K., & Ziter, C. D. (2025). Lessons from exploring the relationship between livability and biodiversity in the built environment. Urban Forestry & Urban Greening. Advance online publication.

Cucuzzella, C., Hazbei, M., & Asgari, M. H. (2024). Parametrizing the unmeasurable: Urban qualities as quantitative parameters for computer games. International Journal of Architectural Computing.

Hazbei, M., Rafati, N., Kharma, N., & Eicker, U. (2024). Optimizing architectural multi-dimensional forms: A hybrid approach integrating approximate evolutionary search, clustering and local optimization. Energy and Buildings.

Rafati, N., Hazbei, M., & Eicker, U. (2023). Louver configuration comparison in three Canadian cities utilizing NSGA-II. Building and Environment.

Hazbei, M., Cucuzzella, C., & Mauro, G. M. (2023). Revealing a gap in parametric architecture’s address of “context.”