Introduction: Why Air Monitoring Is Now a Scientific and Regulatory Priority
Air quality monitoring is increasingly becoming a top priority for the scientific community, institutions, and citizens. Rising concentrations of air pollutants, especially in urban and industrial areas, have direct effects on public health, the environment, and climate change. According to the World Health Organization (WHO), thousands of premature deaths in Europe each year are attributable to exposure to air pollutants (Air quality - WHO).
In the landscape of European environmental legislation, 2024 marked a significant turning point: Directive - UE - 2024/2881 was published, replacing the historical Directive - 2008/50 on air quality. This new legislative text is part of the European Green Deal and aims for an ambitious goal: achieving zero pollution by 2050, protecting citizens’ health and improving environmental quality. The directive came into force on December 10, 2024, and must be transposed by Member States by December 11, 2026.
Directive (EU) 2024/2881 introduces major innovations in air quality monitoring, aiming to ensure more accurate, consistent, and accessible assessments across the European Union.
Member States are required to strengthen monitoring networks by increasing the number and types of measurement stations. In particular, the directive calls for the establishment of “monitoring supersites”—advanced stations strategically distributed and capable of measuring not only traditional pollutants like PM10, PM2.5, and NO₂, but also ultrafine particles, black carbon, and other emerging compounds.
Beyond direct measurements, the directive promotes the use of dispersion models and integrated assessment techniques, which combine data from various sources to provide a more comprehensive picture of pollutant distribution. The collected data must be published transparently and accessibly, including through digital tools, to ensure timely information for citizens.
In Italy, the upgrade of the monitoring system must occur alongside the transposition of the directive by 2026.
The new directive also promotes indoor air monitoring, recognizing its importance for public health. Directive (EU) 2024/2881 explicitly acknowledges the relevance of monitoring air quality in enclosed environments, complementing traditional outdoor monitoring. While the latter concerns open spaces such as streets, parks, and industrial areas, the former focuses on enclosed and frequently occupied places like homes, schools, offices, and hospitals, where exposure to pollutants can be equally significant.
To ensure effective monitoring, the directive is based on three key principles: temporal continuity, which allows for constant data collection and detection of changes over time; spatial representativeness, which ensures that measurements reflect the actual conditions of monitored areas; and data quality, essential for producing reliable information to support evidence-based decision-making.
Air quality monitoring has traditionally relied on fixed reference stations managed by regional environmental protection agencies (ARPA), which provide validated data compliant with European standards. However, Directive (EU) 2024/2881 encourages the adoption of complementary and innovative technologies that can expand territorial coverage and improve the spatial and temporal resolution of measurements.
Among emerging solutions are low-cost, portable, and easily deployable sensors that enable real-time data collection even in areas not covered by official networks. These devices, often integrated into mobile or wearable networks, have already been tested in urban contexts to map pollution in greater detail, also involving citizens in active monitoring (Environmental monitoring with sensor networks — Municipality of Pordenone).
The integration of traditional stations, mobile sensors, and digital models enables the creation of dynamic, three-dimensional maps of air pollution, useful for identifying critical areas such as urban “canyon effects,” where pollutants tend to stagnate.
While these technologies do not replace official methods, they represent a strategic complement to improve the representativeness and timeliness of monitoring, in line with the transparency and participation goals promoted by the new directive.
Traditional Technologies: Robustness and Standardization
Fixed Monitoring Stations (Public and Private Networks)
At the core of air quality monitoring networks are fixed stations, managed by public entities such as ARPA and ISPRA, as well as authorized private operators. These stations are designed to ensure high-quality, validated, and comparable data in compliance with European technical standards, for example, UNI EN 12341:2014 for atmospheric particulate matter and UNI EN 14211:2012 for nitrogen dioxide.
These networks are strategically distributed across the territory based on population density, environmental type, and criteria established by D. Lgs. 155/2010, with the goal of providing representative coverage aligned with European standards.
The stations are equipped with automatic analyzers that continuously measure, typically on an hourly basis, the concentrations of air pollutants such as NOx, SO₂, CO, O₃, PM10, PM2.5, and benzene. The instrumentation used varies depending on the environmental context—urban, industrial, traffic-related, or rural—and the types of pollutants to be monitored. Not all stations are equipped with the same analytical tools; instead, they are configured to meet local specificities.
Technologies employed include UV spectrophotometry for ozone, infrared absorption for carbon monoxide, and gravimetric analysis on filters for particulate matter, ensuring highly precise and regulation-compliant data. These measurements are often complemented by temporary campaigns conducted with mobile laboratories and portable samplers, which help integrate fixed station data with targeted surveys—for example, for fine particulate matter or black carbon—using advanced instruments such as optical particle counters.
However, despite their reliability, fixed stations have some structural limitations. Installation and operational costs are high, spatial coverage is limited—especially in peripheral or rural areas—and the equipment requires frequent maintenance and calibration to ensure data reliability. For this reason, the new Directive (EU) 2024/2881 not only reaffirms the central role of these systems but also promotes their integration with innovative technologies, such as mobile sensors and distributed networks, to make monitoring more widespread, flexible, and accessible.
Innovative Technologies: Widespread Sensor Networks and Intelligent Platforms
IoT Sensors and Microstations
In the last years, the spread of low-cost environmental sensors has radically transformed the way air quality is monitored, enabling more widespread and dynamic territorial coverage. These devices, often integrated into IoT (Internet of Things) systems, are small, affordable, and easy to install, allowing real-time data collection even in areas not served by official networks.
The technological variety is broad: electrochemical sensors detect gases such as NO₂, CO, and O₃; optical sensors, based on laser scattering or nephelometry, measure atmospheric particulate matter; while MOS (Metal Oxide Semiconductor) sensors are used to detect volatile organic compounds and reactive gases. These tools are deployed in mobile urban networks, on public transport, bicycles, backpacks, and even drones (Messapi project), offering a more detailed and three-dimensional mapping of pollution.
The main advantage of these technologies is operational flexibility: they can be rapidly deployed at low cost and extend monitoring to areas that are difficult to reach with traditional stations. However, they also have technical limitations, such as sensor drift over time, the need for frequent calibration, and lower accuracy compared to official systems.
Despite these limitations, the new Directive (EU) 2024/2881 recognizes their strategic value, promoting their integration into environmental monitoring systems. In synergy with fixed stations, these emerging technologies help build a more widespread, participatory, and resilient surveillance system, capable of responding more effectively to air quality challenges.
Integration with Dispersion Models and Forecasting Systems
One of the most promising developments in air quality monitoring is the integration of data collected from sensors—both traditional and low-cost—with atmospheric dispersion models. Tools such as AERMOD, CALPUFF, FARM, and WRF-Chem (Air Quality Dispersion Modeling - US EPA) simulate the behavior of pollutants in the atmosphere, taking into account meteorological, topographical, and anthropogenic variables.
This synergy allows a shift from a static snapshot of pollution to a dynamic and predictive view, useful for anticipating future scenarios and supporting decision-making in environmental emergencies. Techniques such as spatial interpolation, assimilation with meteorological models, and the use of machine learning algorithms help fill data gaps, improve spatial resolution, and refine forecasts.
The integration of real data and simulation models is also applied in urban and industrial planning, in assessing the impact of new infrastructure, and in defining more effective environmental policies (PROMPT project). In this context, the new Directive (EU) 2024/2881 encourages the adoption of forecasting approaches, recognizing their strategic value for proactive air quality management.
Cloud Platforms and Data Analysis
The evolution of environmental monitoring also involves the digitalization of data collection and analysis processes. Modern cloud platforms enable real-time management of large volumes of information from fixed and mobile sensors, ensuring automatic validation, secure storage, and interactive visualization. These systems not only simplify data access but also enhance usability, making data available for analysis, reporting, and decision support (EMC4Ports project).
PM_TEN has long been involved in developing integrated solutions for environmental monitoring, combining sensor technologies, modeling, and digital tools to provide decision support systems for public administrations, companies, and research centers.
Real-World Applications: Case Studies and Use Examples
Innovative air quality monitoring technologies are being applied across a wide range of contexts. In urban settings, distributed sensor networks enable real-time data collection, which is useful for traffic management, public space design, and heat island analysis. In industrial environments, continuous monitoring of diffuse emissions and high-risk areas helps control environmental impact and ensures worker safety.
In these fields, PM_TEN is actively involved in several projects in collaboration with universities and research centers, contributing to the development of multidisciplinary approaches and tailored solutions:
Toward Smarter and More Integrated Air Monitoring
Technological advancements now make it possible to overcome the limitations of traditional networks by offering more flexible, cost-effective, and adaptable tools. The combined use of low-cost sensors, dispersion models, and cloud platforms enables the creation of a dynamic and predictive monitoring system, capable of responding in real time to the needs of citizens, public administrations, and businesses.
In this context, tools and services like those offered by PM_TEN (Air Quality Modelling - Our Services) represent a strategic resource for building healthier cities, safer workplaces, and more effective environmental policies.