INDOOR AIR QUALITY SURVEY

The average family spends 90% of their time indoors, so the quality of your indoor air is paramount to your health and to the health of your loved ones.

In fact, the EPA has listed indoor air pollution among the top five environmental dangers posed to Americans today. Getting regular measurements of your home’s indoor air quality is a vital step in ensuring the health of your family.

Fast & Accurate Measurement

Because you can’t often see or smell air contaminants, we’ll measure particulate matter in any room of your house, pinpointing any issue areas.

Instant Results

You will receive a summary report, which will help you determine the condition of the air in your home and whether any areas require additional sampling.

A Cost-Effective Solution

Our Indoor Air Quality provides a thorough and inexpensive alternative. Protect Your Family’s Health – Get a quick and efficient Indoor Air Quality Survey Today!

What are PM2.5 and PM10 Pollutants?

Particulate matter (PM) or particle pollution in the air is a mixture of airborne tiny particles and liquid droplets that consists of tiny solid fragments, liquid fragments, and fragments mixing with both solid and liquid.

These tiny fragments are made up of various components, such as acids, toxic exhaust, organic chemicals, metal, dust, soot, soil, or a mixture of these components. There are many classes of particulates. However, among these classes, PM10 and PM2.5 are the most regulated ones.

PM10 refers to inhalable coarse particles that are with a diameter of about 10 micrometers.
PM2.5 refers to fine particles that are 2.5 micrometers in diameter and smaller.

Sources of PM2.5 & PM10

There are both natural and anthropogenic (i.e. manmade) sources of PM2.5. Carbonaceous (organic) material from traffic causes a direct adverse effect on health and has been identified as a most evident source of PM2.5. Burning fuels such as oil, gasoline, or wood can directly contribute to the rising of PM levels. On the other hand, windblown dust and chemical reactions between different gases (e.g., nitrogen, sulfur, phosphorus etc.) and other substances (e.g., ammonia) can indirectly enhance the rising of atmospheric PM levels. Power stations as well as Industrial sources contribute most to manmade pollutants (35%), trailed by vehicles or road traffic (24%), suburban (13%), and shipping (10%). Natural sources of particulate matter include sea salt that results in 5-15% of urban background PM2.5 and with higher contributions found near the coastal areas.

Health Effects of PM2.5 & PM10

Exposure to airborne particulate matter (PM) has harmful consequences on human health, the environment, and climate change. Many researches have already provided multitudes of information concerning the hazardous adverse effects of PM exposure.

As PM2.5 are finer particles, they can penetrate deeply and travel through the respiratory system to reach the lung. The Committee on the Medical Effects of Air Pollutants (COMEAP) reported that high-level exposure to PM could increase hospital admissions and premature death of the old and sick because of respiratory and cardiovascular system illnesses. As evidence, the COMEAP showed statistical data on high pollution days and this data revealed that both PM10 and PM2.5 caused additional hospital admissions and premature deaths. The EPA has more information on the effects of particulate pollution.

Long-term PM exposure is associated with chronic respiratory, cardiovascular, and neurological diseases, including lung cancer, neurodevelopmental disorders, poor cognitive function, diabetes, and heart attack. Short-term PM exposure during pollution episodes can produce less severe effects, including temporary breathing difficulty, worsening of asthma symptoms, feeling of unwell, decreased activity level, etc.

In addition to adverse health effects, PM2.5 also has other widespread effects on the environment and climate change. The environmental effect can contribute to biodiversity loss, damaging plants as well as corrosion of buildings.

eTVOC – Equivalent Total Volatile Organic Compounds

What Does eTVOC Mean?

eTVOC stands for equivalent total volatile organic compounds (VOCs) and is a measurement of the total amount of any emitted gases coming from toxins and chemicals. When you have an enclosed space like a home or office, these emitted gases accumulate and pollute the air. The air quality survey does NOT speciate what all the VOCs are, it simply gives the total amount of all VOCs in the air. Volatile organic compounds are gases that are given off by many indoor sources that evaporate at room temperature. Concentrations of most volatile organic compounds are higher in indoor air than outdoor air.

Sources of VOCs

Some sources of VOCs include the burning of fuels such as gas, wood and kerosene and tobacco products. VOCs can also come from personal care products such as perfume and hair spray, cleaning agents, dry cleaning fluid, paints and paint thinner, lacquers, varnishes, hobby supplies, alcohols, vinegars and from copying and printing machines.

Formaldehyde, one of the most common VOCs, is a colourless gas with an acrid (sharp and bitter) smell. It is common in many building materials such as plywood, particleboard and glues.

Formaldehyde can also be found in some drapes and fabrics and in certain types of foam insulation.

*Formaldehyde compounds are not speciated with the Pocket Particle AQI 2.0 Sensor.*

Health Effects of VOCs

VOCs include a variety of chemicals that can cause eye, nose and throat irritation, shortness of breath, headaches, fatigue, nausea, dizziness and skin problems. Higher concentrations may cause irritation of the lungs, as well as damage to the liver, kidney, or central nervous system. Long-term exposure may also cause damage to the liver, kidneys or central nervous system.

Some VOCs are suspected of causing cancer and some have been shown to cause cancer in humans. The health effects caused by VOCs depend on the concentration and length of exposure to the chemicals.

Most people are not affected by short-term exposure to the low levels of VOCs found in homes.

Some people may be more sensitive, such as people with asthma. For long-term exposure to low

levels of VOCs, research is ongoing to better understand any health effects from these exposures.

eCO2 – Equivalent Carbon Dioxide

What Does eCO2 Mean?

Equivalent carbon dioxide, also known as “CO2e”, “eCO2”, “CO2eq”, “CO2equivalent”, or even “CDE”, and these terms can be used interchangeably. This term is used for describing different greenhouse gases in a common unit. For any quantity and type of greenhouse gas, eCO2 signifies the amount of CO2 which would have the equivalent global warming impact. eCO2 bottomline starts at 400 ppm (parts per million), the current environmental background level of CO2ٰ.

Sources of CO2

CO2 is the fourth most abundant gas in the earth’s atmosphere. At room temperature, carbon dioxide (CO2) is a colorless, odorless, non-flammable gas. At other temperatures and pressures, carbon dioxide can be a liquid or a solid. Solid carbon dioxide is called dry ice because it slowly changes from a cold solid directly into a gas. Carbon dioxide is a byproduct of normal cell function when it is breathed out of the body. CO2 is also produced when fossil fuels are burned or decaying vegetation. Surface soils can sometimes contain high concentrations of this gas, from decaying vegetation or chemical changes in the bedrock.

Health Effects of CO2

Exposure to CO2 can produce a variety of health effects. These may include headaches, dizziness, restlessness, a tingling or pins or needles feeling, difficulty breathing, sweating, tiredness, increased heart rate, raised blood pressure, coma, asphyxia, and convulsions.

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