If you're serious about indoor air quality, you need to be thinking about ozone monitoring. The risks of ozone exposure have been acknowledged by government agencies including the FDA, OSHA, NIOSH, and EPA, as well as in healthy building standards such as WELL and Fitwel.
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However, ozone is often poorly understood compared to other indoor air quality factors. As a result, companies often struggle to compare between different ozone monitoring solutions, leading to the topic being overlooked or improperly addressed.
In this article, we&#;ll clear up some of the daunting technical terminology around ozone and ozone measurement. By the end, you&#;ll know what ozone is, when you should be concerned about it, and the various types of sensors used to measure ozone levels indoors and outdoors. Are you ready? Let&#;s go!
What is Ozone?
A quick technical definition. Ozone (O3) is a colorless gas composed of three atoms of oxygen. Two oxygen atoms form O2 oxygen, which is essential for all life on Earth. That extra atom can detach from ozone and attach itself to other substances, altering them in the process.
Good vs bad ozone. When ozone occurs naturally in the upper atmosphere, 10 to 30 miles above the ground, it protects us from the sun&#;s ultraviolet radiation that would otherwise have harmful effects on plant and human life. This is the good ozone - the one we&#;re worried is depleting over time (colloquially referred to as the ozone hole).
However, at ground level, ozone is a harmful air pollutant for human beings and the environment. Smog, which most of us have had the displeasure of experiencing, is primarily composed of ozone.
Bad ozone is formed by nitrogen oxides mixing with volatile organic compounds (VOCs), in the presence of sunlight. These compounds are released by burning fossil fuels such as coal and gasoline, as well as by chemicals such as solvents evaporating.
Ozone is a form of oxygen. When formed naturally in the stratosphere, it positively affects life on Earth; when formed at ground level by human activity it is harmful.
For the rest of this article, we&#;ll be referring to ground level or &#;bad&#; ozone.
Why Indoor Ozone is Cause for Concern
In the past, scientists assumed that indoor ozone levels were negligible and not something to worry about. However, today this is seen as a misperception: significant levels of ozone seep indoors from outdoor environments, especially during the summer. We&#;ve also filled our offices with more indoor ozone emission devices such as photocopiers, printers, and certain types of air purifiers. Schools and offices have been found to be particularly risky in this regard.
Learn more about common sources of indoor ozone.
Ozone is a health hazard. Inhaling ozone can damage the lungs. At low amounts, this can manifest in chest pain, coughing, shortness of breath and throat irritation. People with existing respiratory conditions can be especially susceptible.
At higher levels and with prolonged exposure, ozone can reduce lung function, inflame and damage cells that line the lungs, aggravate asthma and chronic lung disease, and cause permanent lung damage (see this summary by the EPA).
Ozone can hurt your business. As with other elements of poor indoor air quality, ozone-related ailments hurt businesses over the long run due to the costs of absenteeism and reputational damage. Ozone also plays a part in healthy building standards such as WELL, which may require business to meet thresholds for indoor ozone in order to become certified.
Ways to Measure Ozone - How Ozone Sensors Work
Reducing harmful indoor ozone exposure starts with accurately measuring ozone levels in your buildings. There are two main types of sensors used in commercial air quality monitoring devices:
Metal Oxide Semi-conductor (MOS) Sensors
The nitty-gritty:
MOS sensors work by heating a thin film of metal-oxide particles (or, in the case of Kaiterra products, nanoparticles). When heated to around 300&#;C, this surface adsorbs ozone and other gasses, releasing electrons from the oxygen present on the surface and changing the electrical resistance of the metal-oxide layer.The sensor detects these changes, which are proportional to the presence of a gas or group of gasses in the air.
Pros:
- Can detect even low levels of ozone typically found outdoors ( < 0.1 ppm)
- Can reach lab levels of accuracy
- Less cross sensitive to nitrogen dioxide
Cons:
- Cross-sensitive to other VOCs typically found indoors
- Takes some time to start up (due to the film needing to heat)
- Require more power than alternatives, which can make buildings less energy efficient
The bottom line:
MOS sensors are accurate and can detect even very low levels of ozone, and aren&#;t likely to report erroneous results due to the presence of NO2, which is often found outdoors. However, they can be cross sensitive to indoor VOCs and can drive up energy costs, which makes them less suitable for indoor air monitoring. This is why Kaiterra uses MOS sensors for monitoring TVOC, but not ozone.
Electrochemical (EC) Sensors
The nitty-gritty:
Simply put, in an electrochemical sensor, ozone gas diffuses across a permeable barrier into a cell containing electrodes and electrolytes. As ozone gas permeates the membrane, it alters the electrochemical potential of the electrodes, increasing the conductivity proportionally to the amounts of ozone in the air. The EC sensor can translate this signal into a numeric ozone concentration (in ppb or ppm).
Pros:
- Return consistent results over time - measurements can be repeated and give an accurate picture of improvement or decline over time
- Accurate at detecting ozone at the ppm levels that are typically found indoors
- Less susceptible to cross-interference from other volatile organic compounds (VOCs)
Cons:
- Less accurate at detecting lower ozone levels, which might be needed for ambient ozone measurement)
- Can be susceptible to changes in humidity
- Cross sensitive to nitrogen dioxide (NO2) - typically generated by diesel engines and present outdoors
The bottom line:
For more information, please visit ozone monitoring equipment.
Electrochemical sensors are the go-to solution for measuring ozone indoors, where they can provide accurate and consistent measurements and clearly &#;single out&#; ozone among other VOCs. This is why Kaiterra uses EC sensors for monitoring ozone using the Sensedge Mini.
Challenges of Measuring Ozone
Despite increased awareness of the risks of indoor exposure to ozone, many challenges still remain when it comes to measuring it accurately:
Lack of Consistent Standards
Different government agencies and certifying organizations have set different thresholds for acceptable levels of ozone, for example:
- According to the US Occupational Safety and Health Administration (OSHA), workers should not be exposed to more than 0.10 ppm over a period of 8 hours.
- The UK&#;s Health and Safety Executive (HSE) set the workplace exposure limit at 0.2 ppm over a 15 minute reference period.
- The WELL v2 standard talks about 0.051 ppm.
- Fitwel&#;s Enhanced Indoor Air Quality Testing and Monitoring Protocol sets the level at 0.07 ppm
Despite increased awareness of the risks of indoor exposure to ozone, many challenges still remain when it comes to measuring it accurately:Different government agencies and certifying organizations have set different thresholds for acceptable levels of ozone, for example:
As we&#;ve covered in our previous article about ozone in the workplace, there&#;s no definitive way to frame indoor ozone, and instead the tendency is to rely on industrial exposure limits and ambient ozone breakpoints. These environments are not necessarily identical to an office.
Variable Ozone Levels Make Measurement Difficult
Another major challenge in measuring ozone is that it varies dramatically. As Charles Weschler summarizes in Ozone in Indoor Environments: Concentration and Chemistry:
Under normal conditions, the half-life of ozone indoors is between 7 and 10 min and
is determined primarily by surface removal and air exchange.
Indoor ozone concentrations can vary from hour-to-hour, day-to-day, and season-to-season, as well as from room-to-room and structure-to-structure... It is not unusual for indoor ozone levels to change 30 or 40 ppb in less than 1 hour. Given that indoor ozone levels vary with multiple factors including time-of-day, weather conditions, ventilation parameters, geographic location and season, it is not reasonable to speak of a single indoor ozone concentration that is representative of most indoor environments.
These frequent and unpredictable changes in ozone levels mean that measurement needs to be an ongoing process rather than a singular effort. Organizations looking to effectively implement ozone monitoring will find that continuous monitoring is better suited, rather than periodic spot testing (read our full comparison between the two).
Incorporate Ozone Monitoring in Your Indoor Air Quality Strategy
As you become more familiar with different aspects of indoor air quality, you can better tailor your tools and strategies. Getting a comprehensive picture of the current state of air quality in your buildings - including ozone, particular matter, variants of concern and carbon dioxide levels - is an essential step towards improving it.
Ready to get started? We&#;ve recently announced that Kaiterra&#;s Sensedge Mini indoor air quality monitor now supports ozone monitoring. Check out the details below:
Dr Greg Bodeker was a research scientist for the National Institute of Water and Atmospheric Research (NIWA), based at Lauder in Central Otago. Lauder is the primary southern hemisphere mid-latitude site in the Network for the Detection of Atmospheric Composition Change (NDACC), and Greg collaborated with other scientists around the world in this network to monitor the amount of ozone in the atmosphere, mainly where ozone has greatest concentration in the &#;ozone layer&#; between 15 and 30 kilometres above the Earth&#;s surface. This is important work because ozone absorbs most of the UV radiation from the Sun and so protects the Earth from too much UV.
One way the Lauder scientists measure ozone concentrations is through weekly launches of an ozonesonde attached to a hydrogen-filled weather balloon. As it rises, the ozonesonde takes regular samples of air, mixes the samples with chemicals to determine the ozone concentration, and radios the measurement back to Lauder along with measurements of altitude, temperature, humidity and air pressure. This way, a vertical profile of ozone concentration is obtained.
Ozonesonde launch
The weekly launch of an ozonesonde at Lauder in Central Otago enables scientists to monitor the distribution of ozone up through the atmosphere.
The researchers at Lauder also use a ground-based instrument &#; the Dobson spectrophotometer &#; to measure the total amount of ozone above Lauder. The spectrophotometer measures and compares the UV light intensity at wavelengths that are strongly absorbed and weakly absorbed by ozone. The column ozone content of the atmosphere is calculated from the ratios of these intensities.
Dobson spectrophotometer
The Dobson spectrophotometer at Lauder in Central Otago is a key ozone-measuring instrument used by NIWA and is part of a global network of similar instruments.
Greg&#;s research centred on trying to find a better understanding of the links between ozone depletion and climate change and to improve computer models of those links so that more accurate predictions can be made, so he and other colleagues around the world can advise politicians in the implementation of international policies. Linked with this, Greg and his colleagues have found a definite increase in atmospheric ozone levels since the Montreal Protocol, where countries started to phase out emissions of ozone-depleting substances such as chlorofluorocarbons (CFCs) used in spray cans.
Studies by Greg and his colleagues have shown a two-way link between ozone and climate change. Using a very complex &#;coupled chemistry-climate model&#; developed by the United Kingdom Metrological Office and running on NIWA&#;s supercomputer, Kupe, they have shown that increases in greenhouse gases in the atmosphere will actually speed the recovery of the ozone layer, at least over New Zealand. On the other hand, the Antarctic ozone hole has played a key role in the surface climate in Antarctica. It has caused the interior of the Antarctic continent to warm more slowly than it would otherwise.
Nature of science
Where appropriate, scientists construct mathematical computer models of systems they are studying so that they can understand the relationships within the system and predict future trends. New measurements of the real systems enable the computer models to be fine-tuned to make them more accurate.
Greg and Hamish Struthers at Lauder also collaborated with 21 other scientists world-wide to extend their coupled chemistry-climate computer model to simulate the effect of the Sun&#;s 11-year cycle on ozone and temperature in the Earth&#;s atmosphere. Their results agree with actual satellite observations but are in contrast with most previously published simulations.
Useful links
NASA's Eyes on the Earth site shows the positions of their Earth observation satellites. Use the tabs at the bottom of the page to filter for greenhouse gases and other measurements.
In Greg set up his own atmospheric research company, Bodeker Scientific, specialising in the science of stratospheric ozone depletion, stratospheric composition and climate change.
See the Network for the Detection of Atmospheric Composition Change website.
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