Hazards can be dormant or potential, with only a theoretical probability of harm. An event that is caused by interaction with a hazard is called an incident. The likely severity of the undesirable consequences of an incident associated with a hazard, combined with the probability of this occurring, constitute the associated risk. If there is no possibility of a hazard contributing towards an incident, there is no risk.
Identification of hazards is the first step in performing a risk assessment.
Kates (1978) defines environmental hazard as "the threat potential posed to man or nature by events originating in, or transmitted by, the natural or built environment". This definition includes a broader range of hazards ranging from long term environmental deterioration such as acidification of soils and build-up of atmospheric carbon dioxide to communal and involuntary social hazards such as crime and terrorism to voluntary and personal hazards such as drug abuse and mountain climbing. Environmental hazards usually have defined or common characteristics including their tendency to be rapid onset events meaning they occur with a short warning time, they have a clear source of origin which is easily identified, impact will be swift and losses suffered quickly during or shortly after on-set of the event, risk of exposure is usually involuntary due to location or proximity of people to set hazard and the "disaster occurs with an intensity and scale that justifies an emergency response" .
Hazards were grouped by Hewitt and Burton (1971) according to their characteristics. These were factors related to geophysical events which were not process specific. They were:
- Areal extent of damage zone
- Intensity of impact at a point
- Duration of impact at a point
- Rate of onset of the event
- Predictability of the event
In defining hazard it is important to distinguish between natural hazards which may be defined as "extreme events that originate in the biosphere, hydrosphere, lithosphere or atmosphere" or "a potential threat to humans and their welfare" which include earthquake, landslide, hurricane and tsunamis and technological and man made hazards including explosions, release of toxic materials, episodes of severe contamination, structural collapses, and transportation, construction and manufacturing accidents etc. There is also a distinction to be made between rapid onset natural hazards, technological hazards and social hazards which are described as being of sudden occurrence and relatively short duration, and the consequences of environmental degradation such as desertification and drought, (McGuire, et al., 2002).
In defining hazard, whether it be of natural or anthropogenic origin, Keith Smith argues that what may be defined as a natural hazard is not in fact a hazard unless there is the presence of humans to make it a hazard and that it is merely an event of scientific interest. In this sense the environmental conditions we may consider hostile or hazardous can really be seen as neutral in that it is our perception, human location and actions which identify resources and hazards with the range of natural events. In this regard human sensitivity to environmental hazards is a combination of both physical exposure (natural and/or technological events at a location related to their statistical variability) and human vulnerability (in regard to social and economic tolerance of the same location).
Keith Smith states that natural hazards are best seen in an ecological framework in order to distinguish between natural events as natural hazards. He says "natural hazards, therefore, result from the conflict of geophysical processes with people and they lie at the interface what has been called the natural events system and the human interface system." He says that "this interpretation of natural hazards gives humans a central role. Firstly through location, because it is only when people and their possessions get in the way of natural processes that hazard exists."
We can regard hazard then as a geophysical event which when it occurs in extremes and a human factor is involved may be called risk of hazard. In this context we can see that there may be an acceptable variation of magnitude which can vary from the estimated normal or average range with upper and lower limits or thresholds. In these extremities the natural occurrence will become an event that presents risk to the environment or people. Smith says "most social and economic activities are geared to some expectation of the 'average' conditions. As long as the variation of the environmental element remains fairly close to this expected performance, insignificant damage occurs and the element will be perceived as beneficial. However when the variability exceeds some threshold beyond the normal band of tolerance, the same variable starts to impose a stress on society and become a hazard." Thus above average wind speeds resulting in a tropical depression or hurricane according to intensity measures on the Sapphire Simpson Scale will provide an extreme natural event or hazard.
Hazards can be classified as different types in several ways. One of these ways is by specifying the origin of the hazard. One key concept in identifying a hazard is the presence of stored energy that, when released, can cause damage. Stored energy can occur in many forms: chemical, mechanical, thermal, radioactive, electrical, etc. Another class of hazard does not involve release of stored energy, rather it involves the presence of hazardous situations. Examples include confined or limited egress spaces, oxygen-depleted atmospheres, awkward positions, repetitive motions, low-hanging or protruding objects, etc.
Hazards may also be classified as natural, anthropogenic, or technological. They may also be classified as health or safety hazards and by the populations that may be affected, and the severity of the associated risk.
In most cases a hazard may affect a range of targets, and have little or no effect on others. Identification of hazards assumes that the potential targets are defined.
Based on energy source
- Biological hazard
- Biological hazards, also known as biohazards, originate in biological processes of living organisms, and refer to agents that pose a threat to the health of living organisms, the security of property, or the health of the environment.
- The term and its associated symbol may be used as a warning, so that those potentially exposed to the substances will know to take precautions. The biohazard symbol was developed in 1966 by Charles Baldwin, an environmental-health engineer working for the Dow Chemical Company on the containment products. and is used in the labeling of biological materials that carry a significant health risk, such as viral samples and used hypodermic needles.
- Biological hazards include viruses, parasites, bacteria, food, fungi, and foreign toxins.
- Many specific biological hazards have been identified. For example, the hazards of naturally-occurring bacteria such as Escherichia coli and Salmonella, are well known as disease-causing pathogens and a variety of measures have been taken to limit human exposure to these microorganisms through food safety, good personal hygiene and education. However, the potential for new biological hazards exists through the discovery of new microorganisms and through the development of new genetically modified (GM) organisms. Use of new GM organisms is regulated by various governmental agencies. The US Environmental Protection Agency (EPA) controls GM plants that produce or resist pesticides (i.e. Bt corn and Roundup ready crops). The US Food and Drug Administration (FDA) regulates GM plants that will be used as food or for medicinal purposes.
- Biological hazards can include medical waste or samples of a microorganism, virus or toxin (from a biological source) that can affect health.
- Many biological hazards are associated with food, including certain viruses, parasites, fungi, bacteria, and plant and seafood toxins. Pathogenic Campylobacter and Salmonella are common foodborne biological hazards. The hazards from these bacteria can be avoided through risk mitigation steps such as proper handling, storing, and cooking of food. Disease in humans can come from biological hazards in the form of infection by bacteria, antigens, viruses, or parasites.
- Chemical hazard
- A chemical can be considered a hazard if by virtue of its intrinsic properties it can cause harm or danger to humans, property, or the environment.
- Health hazards associated with chemicals are dependent on the dose or amount of the chemical. For example, iodine in the form of potassium iodate is used to produce iodised salt. When applied at a rate of 20 mg of potassium iodate per 1000 mg of table salt, the chemical is beneficial in preventing goiter, while iodine intakes of 1200–9500 mg in one dose have been known to cause death. Some chemicals have a cumulative biological effect, while others are metabolically eliminated over time. Other chemical hazards may depend on concentration or total quantity for their effects.
- A variety of chemical hazards (e.g. DDT, atrazine, etc.) have been identified. However, every year companies produce more new chemicals to fill new needs or to take the place of older, less effective chemicals. Laws, such as the Federal Food, Drug, and Cosmetic Act and the Toxic Substances Control Act in the US, require protection of human health and the environment for any new chemical introduced. In the US, the EPA regulates new chemicals that may have environmental impacts (i.e. pesticides or chemicals released during a manufacturing process), while the FDA regulates new chemicals used in foods or as drugs. The potential hazards of these chemicals can be identified by performing a variety of tests prior to the authorization of usage. The amount of tests required and the extent to which the chemicals are tested varies, depending on the desired usage of the chemical. Chemicals designed as new drugs must undergo more rigorous tests that those used as pesticides.
- Some harmful chemicals occur naturally in certain geological formations, such as radon gas or arsenic. Other chemicals include products with commercial uses, such as agricultural and industrial chemicals, as well as products developed for home use. Pesticides, which are normally used to control unwanted insects and plants, may cause a variety of negative effects on non-target organisms. DDT can build up, or bioaccumulate, in birds, resulting in thinner-than-normal egg shells which can break in the nest. The organochlorine pesticide dieldrin has been linked to Parkinson's disease. Corrosive chemicals like sulfuric acid, which is found in car batteries and research laboratories, can cause severe skin burns. Many other chemicals used in industrial and laboratory settings can cause respiratory, digestive, or nervous system problems if they are inhaled, ingested, or absorbed through the skin. The negative effects of other chemicals, such as alcohol and nicotine, have been well documented.
- Mechanical hazard
- A mechanical hazard is any hazard involving a machine or industrial process. Motor vehicles, aircraft, and air bags pose mechanical hazards. Compressed gases or liquids can also be considered a mechanical hazard.
- Hazard identification of new machines and/or industrial processes occurs at various stages in the design of the new machine or process. These hazard identification studies focus mainly on deviations from the intended use or design and the harm that may occur as a result of these deviations. These studies are regulated by various agencies such as the Occupational Safety and Health Administration and the National Highway Traffic Safety Administration.
- Physical hazard
- A physical hazard is a naturally occurring process that has the potential to create loss or damage. Physical hazards include earthquakes, floods, and tornadoes. Physical hazards often have both human and natural elements. Flood problems can be affected by the natural elements of climate fluctuations and storm frequency, and by land drainage and building in a flood plain, human elements. Another physical hazard, X-rays, naturally occur from solar radiation, but have also been utilized by humans for medical purposes; however, overexposure can lead to cancer, skin burns, and tissue damage.
- Psychosocial hazard
- Psychological or Psychosocial hazards are hazards that affect the psychological well-being of people, including their ability to participate in a work environment among other people. Psychosocial hazards are related to the way work is designed, organized and managed, as well as the economic and social contexts of work and are associated with psychiatric, psychological and/or physical injury or illness. Linked to psychosocial risks are issues such as occupational stress and workplace violence which are recognized internationally as major challenges to occupational health and safety.
- Ergonomic hazard
- Ergonomic hazards are physical conditions that may pose risk of injury to the musculoskeletal system, such as the muscles or ligaments of the lower back, tendons or nerves of the hands/wrists, or bones surrounding the knees. Ergonomic hazards include things such as awkward or extreme postures, whole-body or hand/arm vibration, poorly designed tools, equipment, or workstations, repetitive motion, and poor lighting. Ergonomic hazards occur in both occupational and non-occupational settings such as in workshops, building sites, offices, home, school, or public spaces and facilities.
Based on origin
- Natural hazards
- Natural hazards such as earthquakes, floods, volcanoes and tsunami have threatened people, society, the natural environment, and the built environment, particularly more vulnerable people, throughout history, and in some cases, on a day-to-day basis. According to the Red Cross, each year 130,000 people are killed, 90,000 are injured and 140 million are affected by unique events known as natural disasters.
- Recent policy-oriented work into hazard management began with the work of Gilbert White, the first person to study engineering schemes as a means of mitigating flooding in the US. From 1935 to 1967 White and his colleagues led the research into flood defences, and further collaboration on investigation was undertaken at the University of Chicago.
- In December 1989, after several years of preparation, the United Nations General Assembly adopted resolution 44/236 proclaiming the 1990s as the International Decade for Natural Disaster Reduction. The objective of that decade was stated in the annex of Resolution 44/236 as follows:
"…to reduce through concerted international action, especially in developing countries, the loss of life, property damage, and social and economic disruption caused by natural disasters, such as earthquakes, wind-storms, tsunamis, floods, landslides, volcanic eruptions, wildfire, grasshopper and locust infestations, drought and desertification and other calamities of natural origin."
- Methods to reduce risk from natural hazards include construction of high-risk facilities away from areas with high risk, engineering redundancy, emergency reserve funds, purchasing relevant insurance, and the development of operational recovery plans.
- Anthropogenic hazards
- Hazards due to human behaviour and activity.
- The social, natural and built environment are not only at risk from geophysical hazards, but also from technological hazards including industrial explosions, release of chemical hazards and major accident hazards (MAHs).
- Technological hazards
- Hazards due to technology, and therefore a sub-class of anthropogenic hazards.
- Sociological hazard
- Hazards due to sociological causes, also a sub-class of anthropogenic hazards
- Sociological hazards include crime, terrorist threats and war.
Based on effects
- Health hazards
- Hazards affecting the health of exposed persons, usually having an acute or chronic illness as the consequence. Fatality would not normally be an immediate consequence.
- Safety hazards
- Hazards affecting the safety of individuals, usually having an injury or immediate fatality as the consequence of an incident
- Economic hazards
- Hazards affecting property, wealth and the economy.
- Environmental hazards
- Hazards affecting the environment, particularly the natural environment and ecosystems.
Disaster can be defined as a serious disruption, occurring over a relatively short time, of the functioning of a community or a society involving widespread human, material, economic, societal or environmental loss and impacts, which exceeds the ability of the affected community or society to cope using its own resources. Disaster can manifest in various forms, threatening those people or environments specifically vulnerable. Such impacts include loss of property, death, injury, trauma or post-traumatic stress disorder.
Disaster can take various forms, including hurricane, volcano, tsunami, earthquake, drought, famine, plague, disease, rail crash, car crash, tornado, deforestation, flooding, toxic release, and spills (oil, chemicals). These can affect people and the environment on the local regional level, national level or international level (Wisner et al., unknown) where the international community becomes involved with aid donation, governments give money to support affected countries' economies with disaster response and post-disaster reconstruction.
A disaster hazard is an extreme geophysical event that is capable of causing a disaster. 'Extreme' in this case means a substantial variation in either the positive or the negative direction from the normal trend; flood disasters can result from exceptionally high precipitation and river discharge, and drought is caused by exceptionally low values. The fundamental determinants of hazard and the risk of such hazards occurring is timing, location, magnitude and frequency. For example, magnitudes of earthquakes are measured on the Richter scale from 1 to 10, whereby each increment of 1 indicates a tenfold increase in severity. The magnitude-frequency rule states that over a significant period of time many small events and a few large ones will occur. Hurricanes and typhoons on the other hand occur between 5 degrees and 25 degrees north and south of the equator, tending to be seasonal phenomena which are thus largely recurrent in time and predictable in location due to the specific climate variables necessary for their formation.
- At least 100 people dead,
- at least 100 people injured, or
- at least $1 million damage.
This definition includes indirect losses of life caused after initial onset of the disaster such as secondary effects of, e.g., cholera or dysentery. This definition is still commonly used but has the limitations of number of deaths, injuries and damage (in $). UNDRO (1984) defined a disaster in a more qualitative fashion as:
an event, concentrated in time and space, in which a community undergoes severe danger and incurs such losses to its members and physical appurtenances that the social structure is disrupted and the fulfillment of all or some of the essential functions of the society is prevented.
As with other definitions of disaster, this definition not only encompasses social aspect of disaster impact and stresses potentially caused but also focuses on losses, implying the need for an emergency response as an aspect of disaster. It does not however set out quantitative thresholds or scales for damage, death or injury respectively.
Status of a hazard
Hazards are sometimes classified into three modes or statuses:
- Dormant—The situation environment is currently affected. For instance, a hillside may be unstable, with the potential for a landslide, but there is nothing below or on the hillside that could be affected.
- Armed—People, property, or environment are in potential harm's way.
- Active—A harmful incident involving the hazard has actually occurred. Often this is referred to not as an "active hazard" but as an accident, emergency, incident, or disaster.
The terms "hazard" and "risk" are often used interchangeably. However, in terms of risk assessment, these are two very distinct terms. A hazard is any agent that can cause harm or damage to humans, property, or the environment. Risk is defined as the probability that exposure to a hazard will lead to a negative consequence, or more simply, a hazard poses no risk if there is no exposure to that hazard. Consider the following example from David Okrent's 1980 article, "Comment on Societal Risk":
Three people crossing the Atlantic in a rowboat face a hazard of drowning... Three hundred people crossing the Atlantic in an ocean liner face the same hazard of drowning... The risk to each individual per crossing is given by the probability of the occurrence of an accident in which he or she drowns... Clearly the hazard [drowning] is the same for each individual, but the risk [probability of drowning] is greater for the individuals in the rowboat than in the ocean liner.
Risk can be defined as the likelihood or probability of a given hazard of a given level causing a particular level of loss of damage (Alexander, 2000). David Alexander outlined the elements of risk as populations, communities, the built environment, the natural environment, economic activities and services which are under threat of disaster in a given area. Risk can be equated with a simple equation, although it is not mathematical. The total risk according to UNDRO 1982 is the "sum of predictable deaths, injuries, destruction, damage, disruption, and costs of repair and mitigation caused by a disaster of a particular level in a given area or areas.
David Alexander :13 distinguishes between risk and vulnerability saying that "vulnerability refers to the potential for casualty, destruction, damage, disruption or other form of loss in a particular element: risk combines this with the probable level of loss to be expected from a predictable magnitude of hazard (which can be considered as the manifestation of the agent that produces the loss)." As hazard have varying degrees of severity the more intense or severe the hazard, the greater vulnerability there will be as potential for damage and destruction is increased with respect to severity of hazard. Ben Wisner argues that risk or disaster is "a compound function of the natural hazard and the number of people, characterised by their varying degrees of vulnerability to that specific hazard, who occupy the space and time of exposure to the hazard event." (Wisner, et al., 1994).
Risk, vulnerability and hazard are the three factors or elements which we are considering here in this pseudo equation. Another definition of risk given by Factor analysis of information risk which may be related to disaster is 'the probable frequency and probable magnitude of future losses. Again this definition focuses on the probability of future loss whereby degree of vulnerability to hazard represents the level of risk on a particular population, built environment or environment. The relationship between severity of environmental hazard, probability and risk. Hazard severity will obviously vary it is necessary to outline threats posed by hazard. These are:
- Hazards to people – death, injury, disease and stress
- Hazards to goods – property damage and economic loss
- Hazards to environment –loss of flora and fauna, pollution and loss of amenity
Marking of hazards
Hazard symbols or warning symbols are easily recognisable symbols designed to warn about hazardous materials, locations, or objects, The use of hazard symbols is often regulated by law and directed by standards organisations. Hazard symbols may appear with different colors, backgrounds, borders and supplemental information in order to specify the type of hazard and the level of threat (for example, toxicity classes). Warning symbols are used in many places in lieu of or addition to written warnings as they are quickly recognized (faster than reading a written warning) and more universally understood, as the same symbol can be recognized as having the same meaning to speakers of different languages.
- Sperber, William H. (2001). "Hazard identification: from a quantitative to a qualitative approach". Food Control. 12: 223–228. doi:10.1016/s0956-7135(00)00044-x.
- Smith, Keith (1992). Environmental Hazards: Assessing Risk and Reducing Disaster. Routledge Physical Environment Series (first ed.). Routledge. ISBN 9780415012171.
- Hewitt, Kenneth; Burton, Ian (1971). The hazardousness of a place: a regional ecology of damaging events. University of Toronto Department of Geography Research Publications, Volume 6. University of Toronto Press. ISBN 9780802032812.
- Alexander, David E. Confronting catastrophe: new perspectives on natural disasters. Harpenden, England: Terra Publishing. ISBN 0-19-521695-4.
- "Biohazard Symbol History". Archived from the original on February 13, 2012.
- Natio-clearnal Restaurant Association. (2008). Servsafe Essentials, 5th edition.
- Ropeik, David (2002). Risk. New York, New York, USA: Houghton Mifflin Company. ISBN 0-618-14372-6.
- Jones, David (1992). Nomenclature for hazard and risk assessment in the process industries. Rugby, Warwickshire, UK: Institution of Chemical Engineers. ISBN 0-85295-297-X.
- Agency for Toxic Substances & Disease Registry. (2004). Toxicological profile of iodine. Retrieved from http://www.atsdr.cdc.gov/toxprofiles/tp158-c3.pdf.
- Song, C.; Kanthasamay, A.; Anatharam, V.; Sun, F.; Kanthasamy, A.G. (2010). "Environmental neurotoxic pesticide increases histone acetylation to promote apoptosis in dopaminergic neuronal cells: relevance to epigenetic mechanisms of neurodegeneration". Mol Pharmacol. 77: 621–632. doi:10.1124/mol.109.062174.
- Smith, Keith (2001). Environmental Hazards: Assessing risk and reducing disaster. New York, New York, USA: Routledge. ISBN 0-415-22464-0.
- Sraff. "Ergonomic hazards". Comcare. Australian Government. Retrieved 5 June 2017.
- Craig Taylor, Erik VanMarcke, ed. (2002). Acceptable Risk Processes: Lifelines and Natural Hazards. Reston, VA: ASCE, TCLEE. ISBN 9780784406236.
- Staff. "What is a disaster?". www.ifrc.org. International Federation of Red Cross and Red Crescent Societies. Retrieved 21 June 2017.
- Wolman, M. Gordon & Miller, John P. (1960) in Alexander, David E. "2". Confronting catastrophe: new perspectives on natural disasters. Harpenden, England: Terra Publishing. ISBN 0-19-521695-4.
- Hewitt, K.; Sheehan, L. (1969). A Pilot Survey of Global Natural Disasters the Past Twenty Years. (Report). Natural Hazards Research Working Paper, No. 11. Toronto: University of Toronto. Retrieved 21 June 2017.
- David MacCollum (December 18, 2006). Construction Safety Engineering Principles: Designing and Managing Safer Job Sites. McGraw-Hill Professional. ISBN 978-0-07-148244-8. Retrieved 2010-07-10.
- Okrent, David (1980). "Comment on Societal Risk". Science. 208 (4442): 372–375. doi:10.1126/science.208.4442.372.