| Type of catastrophe (in the 21st century) | Probability of extinction (%) |
|---|---|
| Any* | 4.26 |
| Any | 1.77 |
| Artificial intelligence | 2.84 |
| Climate change and geoengineering | 0.0106 |
| Nanotechnology | 0.245 |
| Nuclear war | 0.299 |
| Synthetic biology | 0.220 |
| Other | 0.695 |
Thanks to David Denkenberger, Eli Lifland, Gregory Lewis, Misha Yagudin, Nuño Sempere, and Tamay Besiroglu.
I calculated the probability of extinction for catastrophes in the 21st century caused by:
The results for “any” do not explicitly depend on those of the 6 1st types of catastrophe mentioned above, whereas those for “any*” are calculated assuming independence between them.
The inputs to the calculations are:
Concretely, I calculated the probability of extinction from the sum of the following 3 products (see tab “Probability of extinction by catastrophe” of this Sheet):
I computed the probability of the population loss falling into each of the 3 population loss ranges presented above based on the complementary cumulative distribution function (CCDF) of the population loss (see tab “Probability of the population loss”). I assumed the CCDF decreases linearly between each consecutive pair of the following points[3] (see tab “CCDF of the population loss”):
I set the probabilities required to determine the CCDF for the population losses of 10 % and 95 % to Metaculus’ community predictions (collected in tab “Metaculus' predictions”).
I calculated the probability of extinction for each of the 3 population loss ranges presented above for 3 exhaustive scenarios (see tab “Probability of extinction by scenario”):
To illustrate what is intended by “major infrastructure damage” and “major climate change”, Luisa writes:
For the 1st and 2nd scenarios, I determined the probability of extinction from its mean value for each of the population loss ranges. For the 3rd one, I computed it from the geometric mean between the values for the 1st and 2nd scenarios.
I supposed the probability of extinction as a function of the population loss to increase linearly between each consecutive pair of the following points:
PE_1, PL, PE_2 and PE_3 are the geometric means between the lower and upper bounds of the best guesses provided by Luisa here:
My guesses for the probability of each of the 3 scenarios defined in the previous section given a population loss caused by a certain type of catastrophe is in the table below (and in tab “Probability of extinction scenarios by catastrophe”). I calculated the probability for the type “other” from the mean of the probability for the other types of catastrophes (excluding “any”), and the one for the type “any” from the mean of the probability of the various types weighted by their probability of leading to a population between 95 % and 1.
| Type of catastrophe (in the 21st century) | Probability of scenario given a population loss | ||
|---|---|---|---|
| No major infrastructure damage nor climate change | Major infrastructure damage and climate change | Either major infrastructure damage or climate change | |
| Any | 29.2 % | 22.5 % | 48.3 % |
| Artificial intelligence | 1/4 | 1/4 | 1/2 |
| Climate change and geoengineering | 0 | 0 | 1 |
| Nanotechnology | 0 | 1/3 | 2/3 |
| Nuclear war | 0 | 1/3 | 2/3 |
| Synthetic biology | 1 | 0 | 0 |
| Other | 25.0 % | 18.3 % | 56.7 % |
The tables below contain the results for:
| Type of catastrophe (in the 21st century) | Probability (%) of a population loss between… | ||
|---|---|---|---|
| 0 to 10 % | 10 % to 95 % | 95 % to 1 | |
| Any* | 100 | 25.3 | 10.3 |
| Any | 68.0 | 27.8 | 4.16 |
| Artificial intelligence | 90.4 | 2.40 | 7.20 |
| Climate change and geoengineering | 98.4 | 1.58 | 0.0160 |
| Nanotechnology | 99.0 | 0.538 | 0.422 |
| Nuclear war | 90.4 | 9.22 | 0.384 |
| Synthetic biology | 90.4 | 8.74 | 0.864 |
| Other | 92.6 | 5.67 | 1.69 |
| Scenario | Probability of extinction (%) for a population loss between… | ||
|---|---|---|---|
| 0 to 10 % | 10 % to 95 % | 95 % to 1 | |
| No major infrastructure damage nor climate change | 0 | 0.0413 | 25.1 |
| Major infrastructure damage and climate change | 0.176 | 2.05 | 55.1 |
| Either major infrastructure damage or climate change | 0 | 0.291 | 37.2 |
| Type of catastrophe (in the 21st century) | Probability of extinction (%) for a population loss between… | |||
|---|---|---|---|---|
| 0 to 10 % | 10 % to 95 % | 95 % to 1 | 0 to 1 (total) | |
| Any* | 0.180 | 0.141 | 3.95 | 4.26 |
| Any | 0.0269 | 0.171 | 1.57 | 1.77 |
| Artificial intelligence | 0.0397 | 0.0160 | 2.78 | 2.84 |
| Climate change and geoengineering | 0 | 0.00461 | 0.00595 | 0.0106 |
| Nanotechnology | 0.0580 | 0.00471 | 0.182 | 0.245 |
| Nuclear war | 0.0529 | 0.0808 | 0.166 | 0.299 |
| Synthetic biology | 0 | 0.00361 | 0.217 | 0.220 |
| Other | 0.0298 | 0.0312 | 0.634 | 0.695 |
The relative importance of major infrastructure damage and climate change decreases as the severity of the population loss increases. The ratio between the probability of extinction without major infrastructure damage nor climate change and the probability of extinction with both is (see cells F3:F5 of tab “Probability of extinction by scenario”):
This tendency seems correct, as the probability of extinction is 1 for a population loss of 1 regardless of infrastructure damage and climate change.
In the table below (and in tab “Comparison of absolute values with the GCRS”), I compare the probability of extinction by type of catastrophe in the 21st century I estimated with ones I derived from the 2008 Global Catastrophic Risks Survey (GCRS), whose results are presented in this report by Anders Sandberg and Toby Ord from the Future of Humanity Institute[4] (see tab “2008 Global Catastrophic Risks Survey”). The GCRS estimates refer to the period from 2009 to 2099, but I adjusted them to the period from 2023 to 2100 assuming constant risk. Additionally, I derived GCRS’ estimate for “other” risks assuming independence between the types of catastrophes[5].
| Type of catastrophe (in the 21st century) | Probability of extinction (%) for a population loss between… | |||
|---|---|---|---|---|
| My analysis (%) | GCRS (%) | Absolute difference to GCRS (pp) | Relative difference to GCRS (%) | |
| Any* | 4.26 | 16.5 | -12.3 | -74.2 |
| Any | 1.77 | 16.5 | -14.8 | -89.3 |
| Artificial intelligence | 2.84 | 4.30 | -1.46 | -34.0 |
| Nanotechnology | 0.245 | 4.30 | -4.06 | -94.3 |
| Nuclear war | 0.299 | 0.858 | -0.558 | -65.1 |
| Synthetic biology | 0.220 | 1.72 | -1.50 | -87.2 |
| Other | 0.695 | 6.46 | -5.76 | -89.2 |
My probabilities of extinction are lower than those I derived from the GCRS for all types of catastrophe. Nanotechnology has the largest relative difference, and artificial intelligence the smallest.
The GCRS did not address “climate change and geoengineering”, but my estimate of 0.0106 % is similar to:
Ultimately, what is the most relevant for prioritisation is how the various probabilities compare with each other. Having this in mind, in the table below (and in tab “Comparison of priorities with The Precipice”), I present the probability of extinction in the 21st century as a fraction of that for “any*”, and the existential risk between 2021 and 2120 guessed by Toby Ord in The Precipice (see tab “Existential risk estimates from The Precipice”) as a fraction of the total. The existential risk for “other” was estimated from those for “unforeseen anthropogenic risk” and “other anthropogenic risk” assuming independence between them.
| Type of catastrophe | Normalised probability of extinction for a catastrophe in the 21st century (%) | Normalised existential risk from 2021 to 2120 (%) | Ratio | Decimal logarithm of the ratio |
|---|---|---|---|---|
| Artificial intelligence | 66.6 | 60.0 | 1.11 | 0.0455 |
| Climate change and geoengineering | 0.248 | 0.600 | 0.413 | -0.384 |
| Nuclear war | 7.03 | 0.600 | 11.7 | 1.07 |
| Synthetic biology | 5.17 | 20.0 | 0.259 | -0.587 |
| Other | 16.3 | 31.6 | 0.516 | -0.287 |
Relative to Toby Ord’s best guesses, my analysis suggests the relative importance of:
The adequacy of this comparison depends on the extent to which probability of extinction is a good proxy for existential risk.
In essence, the results I obtained are a function of guesses from Metaculus’ forecasters, Luisa Rodriguez, and me. I should note there is margin to improve the quality of the inputs:
That being said, for the reasons outlined by Scott Alexander here, I believe establishing priorities based on a quantitative model with guessed inputs is often better than guessing priorities.
To clarify, the probability refers to catastrophes occurring during the 21st century, but the extinction may happen afterwards.
The results in the Sheet are updated automatically as the Metaculus’ predictions change.
This implies the probability density function (PDF) of the population loss is uniform for each of the 3 ranges.
This implies the GCRS’ estimates for “any*” are the same as for “any”.
“With those caveats in my mind, my best guess estimate is that the indirect risk of existential catastrophe due to climate change is on the order of 1 in 100,000, and I struggle to get the risk above 1 in 1,000. Working directly on US-China, US-Russia, India-China, or India-Pakistan relations seems like a better way to reduce the risk of Great Power War than working on climate change”. I guess John’s best guess for the total risk of existential catastrophe due to climate change is similar to John’s best guess for the indirect risk, which equals John’s upper bound for the direct risk: “I [John] construct several models of the direct extinction risk from climate change but struggle to get the risk above 1 in 100,000 over all time”.
“That said, we [80,000 Hours] still think this risk is relatively low. If climate change poses something like a 1 in 1,000,000 risk of extinction by itself, our guess is that its contribution to other existential risks is at most a few orders of magnitude higher — so something like 1 in 10,000”.