Document Type : Original Research Paper-English Issue

Authors

• R. Raisi
• K. Fattahi
• S.M. Zakeri
• S. Daneshmand

Faculty of Art and Architecture, Shiraz University, Shiraz, Iran

Abstract

Background and Objectives: The learning environment refers to different settings in which students partake in their studies or learning.  In recent years, there has been a focus on implementing diverse research to analyze physical settings to improve students' performance in educational settings. The emergence of Neuro-architecture, a growing field that integrates neuroscience principles into architectural design, has gained popularity in optimizing student engagement and learning outcomes. By understanding the neural mechanisms that influence interactions with the built environment, neuro-architecture provides novel avenues for developing learning spaces that support optimal students’ performance. Previous Neuro-architecture research has explored various physical aspects within educational settings, including classroom size, color palettes, lighting, acoustics, and indoor air quality, revealing their impacts on memory, attention, emotional reactions, cognitive abilities, and learning advancement. However, limited attention has been given to stress-induced arousal, as well as the influence of classroom ceiling slope on students' stress levels and cognitive abilities. This study seeks to fill this gap by examining how the classroom ceiling slope relates to students' stress levels and cognitive function. Employing Virtual Reality (VR) simulations, cognitive assessments, and physiological measures, the study aims to answer the research question: How do varying ceiling slope orientations affect physiological responses linked to stress-induced arousal and cognitive function? The findings of this study will enhance the realm of research on learning environments by providing insight into the influence of physical features, such as the slope angle of classroom ceilings, on student wellness and academic performance.
Materials and Methods: The research employed a quasi-experimental design to explore the effects of various Ceiling Slope Variations (CSV) on stress-induced arousal and cognitive performance. A total of 18 participants, comprising nine males and nine females, participated in the experiment, selected based on five inclusion criteria established to maintain study consistency and reliability. In the first phase, participants' stress levels were evaluated through the utilization of an Emotibit bio-data logger and Visual Analogue Scales (VAS) test for measuring and mapping psychological responses. This involved monitoring heart rate variability (HRV) and electrodermal activity (EDA) in the surveyed individuals, with the objective of understanding how various ceiling slope orientations affected stress levels. The subsequent phase focused on assessing participants' cognitive abilities by utilizing the N-back test, a well-established task for gauging working memory and attention. The aim was to investigate how different CSV configurations influenced cognitive performance. In the final phase, the relationship between participants' psychological and physiological responses was analyzed using the Analysis of Variance (ANOVA) test. This examination aimed to uncover the connection between stress-induced arousal and cognitive performance in relation to the diverse ceiling slope orientations.
Findings: The findings highlight the important role of ceiling slope orientation in impacting stress levels and cognitive performance among students. Specifically, the research emphasizes that a backward-sloping ceiling design, particularly in relation to the class board, is associated with enhanced cognitive abilities, including higher accuracy rates and reduced instances of incorrect answers, compared to traditional classroom layouts. Conversely, the conventional classroom design results in the lowest cognitive performance levels. Furthermore, the study indicates that variations in ceiling slope can also trigger physiological responses in students, such as changes in heart rate and skin conductance, leading to diverse stress levels. The results suggest that integrating a backward sloping ceiling design can significantly alleviate stress levels in the surveyed participants, showcasing the potential benefits of such ceilings in educational environments.
Conclusions: This research highlights the critical importance of educational space design in alleviating stress and enhancing cognitive abilities among students. Through the utilization of VR simulations and the assessment of physiological and cognitive reactions, the study offers valuable insights into how variations in ceiling slope can impact stress levels and cognitive performance. The results indicate that integrating a backward sloping ceiling design can play a significant role in reducing stress and boosting cognitive functions in students. These findings underscore the importance of developing educational environments that prioritize neuro-architectural principles to promote optimal learning outcomes and student welfare. It is imperative for educational institutions to take into account these considerations when structuring classrooms, ensuring the creation of spaces that nurture students' cognitive processes and overall well-being.

Keywords

• Learning environment
• Ceiling slope
• Neuro-architecture
• Physiological measures
• Stress
• Cognitive performance

Main Subjects

• Technology-based learning environments

COPYRIGHTS 
© 2025 The Author(s).  This is an open-access article distributed under the terms and conditions of the Creative Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) (https://creativecommons.org/licenses/by-nc/4.0/)