Micromort

A micromort (from micro- and mortality) is a unit of risk defined as a one-in-a-million chance of death. Micromorts can be used to measure the riskiness of various day-to-day activities. A microprobability is a one-in-a million chance of some event; thus, a micromort is the microprobability of death. The micromort concept was introduced by Ronald A. Howard who pioneered the modern practice of decision analysis.

Micromorts for future activities can only be rough assessments, as specific circumstances will always have an impact. However, past historical rates of events can be used to provide a ball park, average figure.

Sample values

Baseline

Death from Context Time period N deaths N population Micromorts per unit of exposure Reference
All causes England and Wales 2012 499,331 56,567,000 24 per day
8,800 per year
ONS Deaths Table 5.
All causes Canada 2011 242,074 33,476,688 20 per day
7,200 per year
Statistics Canada
All causes US 2010 2,468,435 308,500,000 22 per day
8,000 per year
CDC Deaths Table 18.
Non-natural cause England and Wales 2012 17,462 56,567,000 0.8 per day
300 per year
ONS Deaths Table 5.19.
Non-natural cause US 2010 180,000 308,500,000 1.6 per day
580 per year
CDC Deaths Table 18
Non-natural cause (excluding suicide) England and Wales 2012 12,955 56,567,000 0.6 per day
230 per year
ONS Suicides
Non-natural cause (excluding suicide) US 2010 142,000 308,500,000 1.3 per day
460 per year
CDC Deaths Table 18.
All causes – first day of life England and Wales 2007 430 per first day of life Walker, 2014
All causes – first year of life US 2013 16.7 per day
6100 per year
CDC Life Tables
Blastland & Spiegelhalter, 2014
Murder/homicide England and Wales 2012/13 551 56,567,000 10 per year ONS Crime
Homicide Canada 2011 527 33,476,688 15 per year Statistics Canada
Murder and non-negligent manslaughter US 2012 14,173 292,000,000 48 per year FBI Table 16

Leisure and sport

Death from Context Time period N deaths N exposure Micromorts per unit of exposure Reference
Scuba diving UK: BSAC members 1998–2009 75 14,000,000 dives 5 per dive BSAC
Scuba diving UK: non-BSAC 1998–2009 122 12,000,000 dives 10 per dive BSAC
Scuba diving US – insured members of DAN 2000–2006 187 1,131,367 members 164 per year as member of DAN
5 per dive
DAN p75
Paragliding Turkey 2004-2011 18 242,355 jumps 74 per jump Canbek 2015
Skiing US 2008/9 39 57,000,000 days skiing 0.7 per day Ski-injury.com
Skydiving US 2000–2016 413 48,600,000 jumps 8 per jump USPA
Skydiving UK 1994–2013 41 4,864,268 jumps 8 per jump BPA
Running marathon US 1975–2004 26 3,300,000 runs 7 per run Kipps C 2011 (the referenced article does not support the claimed number of micromorts, and contains no data from which it is possible to calculate the risk of death)
BASE jumping Kjerag Massif, Norway 1995–2005 9 20,850 jumps 430 per jump Soreide 2007
Mountaineering Ascent to Matterhorn 1981–2011 213 about 75,000 ascents

(about 2500 per year)

about 2,840 per ascent attempt Bachmann 2012
Mountaineering Ascent to Mt. Everest 1922–2012 223 5,656 successful ascents 37,932 per successful ascent NASA 2013

Travel

Activities that increase the death risk by roughly one micromort, and their associated cause of death:

  • Travelling 6 miles (9.7 km) by motorcycle (collision)
  • Travelling 17 miles (27 km) by walking (collision)
  • Travelling 10 miles (16 km) or 20 miles (32 km) by bicycle (collision)
  • Travelling 230 miles (370 km) by car (collision) (or 250 miles)
  • Travelling 1,000 miles (1,600 km) by jet (collision)
  • Travelling 6,000 miles (9,656 km) by train (collision)

Other

Increase in death risk for other activities on a per event basis:

  • Hang gliding – 8 micromorts per trip
  • Ecstasy (MDMA) – 0.5 micromorts per tablet, rising to 13 if using other drugs
  • Giving birth (vaginal) – 120 micromorts
  • Giving birth (caesarean) – 170 micromorts
  • mRNA vaccination against COVID-19 (Pfizer or Moderna) – smaller than 0.03-0.5 micromorts
  • AstraZeneca vaccination against COVID-19 – 2.9 micromorts
  • Infection fatality rate COVID-19 at age 10 – 20 micromorts
  • Infection fatality rate COVID-19 at age 25 – 100 micromorts
  • Infection fatality rate COVID-19 at age 55 – 4,000 micromorts
  • Infection fatality rate COVID-19 at age 65 – 14,000 micromorts
  • Infection fatality rate COVID-19 at age 75 – 46,000 micromorts
  • Infection fatality rate COVID-19 at age 85 – 150,000 micromorts

Value of a micromort

Willingness to pay

An application of micromorts is measuring the value that humans place on risk. For example, a person can consider the amount of money they would be willing to pay to avoid a one-in-a-million chance of death (or conversely, the amount of money they would receive to accept a one-in-a-million chance of death). When offered this situation, people claim a high number. However, when looking at their day-to-day actions (e.g., how much they are willing to pay for safety features on cars), a typical value for a micromort is around $50 (in 2009). This is not to say the $50 valuation should be taken to mean that a human life (1 million micromorts) is valued at $50,000,000. Rather, people are less inclined to spend money after a certain point to increase their safety. This means that analyzing risk using the micromort is more useful when using small risks, not necessarily large ones.

Value of a statistical life

Government agencies use a nominal Value of a Statistical Life (VSL) – or Value for Preventing a Fatality (VPF) – to evaluate the cost-effectiveness of expenditure on safeguards. For example, in the UK the VSL stands at £1.6 million for road improvements. Since road improvements have the effect of lowering the risk of large numbers of people by a small amount, the UK Department for Transport essentially prices a reduction of 1 micromort at £1.60. The US Department of Transportation uses a VSL of US$6.2 million, pricing a micromort at US$6.20.

Chronic risks

Micromorts are best used to measure the size of acute risks, i.e. immediate deaths. Risks from lifestyle, exposure to air pollution, and so on are chronic risks, in that they do not kill straight away, but reduce life expectancy. Ron Howard included such risks in his original 1979 work, for example an additional one micromort from:

  • Drinking 0.5 liter of wine (cirrhosis of the liver)
  • Smoking 1.4 cigarettes (cancer, heart disease)
  • Spending 1 hour in a coal mine (black lung disease)
  • Spending 3 hours in a coal mine (accident)
  • Living 2 days in New York or Boston in 1979 (air pollution)
  • Living 2 months with a smoker (cancer, heart disease)
  • Drinking Miami water for 1 year (cancer from chloroform)
  • Eating 100 charcoal-broiled steaks (cancer from benzopyrene)
  • Traveling 6000 miles (10,000 km) by jet (cancer due to increased background radiation)

Such risks are better expressed using the related concept of a microlife.

See also

Notes

  1. ^ however due to the health effects of cycling the net effect of cycling on life expectancy is likely positive in most cases

This page was last updated at 2022-09-19 15:31 UTC. Update now. View original page.

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