Thanks for writing this, Vasco! And thanks for inviting me to comment given that you expected me to disagree with the conclusion (which I do :)). Iām still confused about these questions but I think there are two analogies from physics/āmathematics that might apply here and cast doubt on the postās conclusions, namely, (1) phase transitions and (2) topological transformations.
NB: I recorded a voice note into Claude and then asked it to structure and clarify my thinking, which I then cleaned up.
Your argument, as I understand it, goes something like this:
A human body can be described by the state of all its fundamental particles.
For any two states that differ only infinitesimally, the pain intensities must be quantitatively comparable.
You can get from any state to any other state via a chain of infinitesimal changes.
Therefore, all pain intensities are quantitatively comparable.
I think (2) is doing a lot of heavy lifting here, and I donāt think itās obviously true. The key issue is that continuous variation in underlying physical parameters does not entail continuous variation in the properties that emerge from them. This happens for example in phase transitions and topology.
Phase transitions
When you heat a ferromagnet continuously, nothing dramatic happens for a while. Then, at a specific critical temperature (the Curie temperature), ferromagnetism doesnāt just decrease, but it vanishes entirely. The property ābeing able to attract ironā is not something that fades smoothly to zero. It disappears at a sharp threshold, even though the underlying control parameter (temperature) was varied continuously.
Similarly, when you cool certain materials, electrical resistance drops to exactly zero at a critical temperature (superconductivity). āVery low resistanceā and āzero resistanceā are not just quantitatively different. Superconductors exhibit qualitatively new phenomena (persistent currents, the Meissner effect, flux quantization) that materials with merely very low resistance simply do not have.
In our earlier exchange, I used the water/āsteam analogy, and you responded that we can still compare the temperature of water and steam. Thatās true, but I should have added that I think pain might not be analogous to temperature, but to some other property. Temperature is a property that varies smoothly across the phase boundary, but there are other properties that only exist in one phase. For example, steam can do mechanical work via expansion (it drives turbines); liquid water cannot. Liquid water has surface tension (it forms droplets, menisci, capillary action); steam doesnāt. These properties arenāt ālessā or āmoreā across the transition. Theyāre categorically present or absent.
So the question is: is pain intensity more like temperature (a quantity that varies smoothly across all physical states), or more like magnetism or surface tension (a property that can appear, disappear, or transform categorically /ā jump at critical thresholds)?
I think thereās good reason to suspect the latter. For example, neurons themselves exhibit all-or-nothing action potentials. Below a voltage threshold, nothing propagates. Above it, a full spike fires. Continuous variation in input produces a binary output. If certain pain experiences depend on whether particular neural cascades fire or not, then the inference from āinfinitesimal change in particle positionsā to āinfinitesimal change in pain intensityā breaks down at these thresholds.
Topological transformations
Consider a rubber sphere. You can stretch it, compress it, bend it, twist it however you like, and it remains topologically a sphere. But to turn it into a torus (a donut shape), you need to introduce a hole. The number of holes (the āgenusā) is an integer. It cannot change by 0.01. And yet this discrete invariant determines fundamental properties of the surface, like how many independent loops can exist on it.
Or consider a loop of string. You can deform it continuously all day long, but the moment a crossing is introduced and locked in, you get a knot, which is a topologically distinct object. The unknot and the trefoil knot are categorically different. You cannot āhalfwayā have a knot. Knot invariants are discrete, even though every local manipulation of the string is smooth.
Suppose the morally relevant feature of a conscious experience is something like a topological property of the neural dynamics: perhaps the structure of information integration, the geometry of recurrent loops, or the topology of attractors in the brainās state space. More concretely, if pain was, say, the degree of dissonance in the electromagnetic waves generated by the nervous system, then introducing a topological defect into the field could suddenly allow new levels of dissonance not possible without the defect.
If thatās the case, then the argument āmoving an electron by 10^-100 m cannot prevent the pains from being quantitatively comparableā would be analogous to arguing āstretching a rubber sphere by 10^-100 m cannot change its genus.ā For most configurations, thatās true. But at a critical configuration, that tiny stretch is exactly what punctures the sphere and changes the genus from 0 to 1. The transition is sharp and local in parameter space.
So overall, I think the burden of proof is on showing that pain intensity actually behaves like temperature (smoothly varying, phase-invariant) rather than like magnetism, surface tension, or genus (categorically structured, with critical thresholds). I think itās more likely to be the latter (and that the symmetry theory of valence will be key in finding the solution).
My intuition is that the conclusion āI would prefer warming up slightly cold patches of soil for sufficiently many nematodes over averting 1 trillion human-years of extreme tortureā should be a reductio ad absurdum for the argument, and maybe the two angles above show how one might escape such a conclusion.
A human body can be described by the state of all its fundamental particles.
I am not sure the state of a human body is fully defined by the state of its fundamental particles, but I used this to mean all of its physical properties.
The key issue is that continuous variation in underlying physical parameters does not entail continuous variation in the properties that emerge from them.
For my argument to work, it is enough for pain intensity to be quantitatively comparable for infinitesimally different physical parameters. The pain intensity does not have to be a continuous function of the physical parameters. I actually suspect physical parameters can only vary discretely, in agreement with quantum mechanics. So I believe both physical parameters and pain intensity vary in infinitesimally small jumps.
When you heat a ferromagnet continuously, nothing dramatic happens for a while. Then, at a specific critical temperature (the Curie temperature), ferromagnetism doesnāt just decrease, but it vanishes entirely. The property ābeing able to attract ironā is not something that fades smoothly to zero. It disappears at a sharp threshold, even though the underlying control parameter (temperature) was varied continuously.
This is not true. I wonder whether Claude hallucinated it. Spontaneous magnetisation (M) just below the Curie temperature is proportional to (āCurie temperatureāāātemperatureā)^āexponent (0.34 for iron)ā. So spontaneous magnetisation smoothly goes to 0 as the temperature approaches the Curie temperature. In any case, spontaneous magnetisation would be comparable across any 2 temperatures even if it abrupty dropped to 0 near the Curie temperature. The spontaneous magnetisation for a temperature at least as high as the Curie temperature is 0 times that for a temperature below it.
For example, steam can do mechanical work via expansion (it drives turbines); liquid water cannot.
The mechanism via which steam does mechanical work is fundamentally the same as that through which liquid water does mechanical work in hydropower. In both cases, molecules of water collide with turbines, and make them spin. For the case of steam, water vapour molecules are accelerated by temperature. For the case of hydropower, liquid water molecules are accelerate by gravity. In any case, the mechanical work done by steam and liquid water is quantitatively comparable.
The density of water also varies smoothly as it boils. It increases linearly with the vapour quality, which is the mass of water vapour as a fraction of all the mass. For a vapour quality of 0, there is saturated liquid water, and the density matches that of liquid water at the boiling point. For a vapour quality of 1, there is saturated water vapour, and the density matches that of water vapour at the boiling point.
In the example above, an infinitesimal change in a physical property (temperature) leads to an abrupt change in another physical property (density), but the underlying physical state does not change infinitesimally (at the boiling point, an infinitesimal change in vapour quality results in an infinitesimal change in density). In any case, a physical property varying abrupty for an infinitesimal change in the underlying physical state would not undermine my argument. The physical property in one state would have to be quantitatively incomparable with that on another state. The density of water at different states is quantitatively comparable.
Liquid water has surface tension (it forms droplets, menisci, capillary action); steam doesnāt.
Surface tension is technically not a property of liquid water or water vapour. It is a property of liquidāair interfaces, and it varies smoothly with temperature. The surface tension for the interface between liquid water and water vapour is different than that between liquid water and other gases.
Topological transformations
Are you practically arguing that some pain intensities are not quantitatively comparable, even if their underlying physical states only differ infinitesimally, because there are mathematical functions which are not continuous? I do not understand why the space of possible mathematical functions would provide any meaningful empirical evidence about pain intensities.
I think the burden of proof is on showing that pain intensity actually behaves like temperature
My core point is that infinitesimal changes in physical reality do not make pain intensities quantitatively incomrable. Physical reality is infinitesimally changing all the time, and personally experienced pain intensities seem very much quantitatively comparable. So I would say the burden of proof is on showing this is not the case.
I hope this helps clarify where Iām at!
Likewise. Thanks for the opportunity to clarify my position.
Nice response, thanks a lot! :) I might share some more thoughts soon (e.g., maybe the assumption that pain is a one-dimensional quantity could be doing some additional heavy lifting here; and I guess others have discussed problems with aggregationism, which may still apply even if all pains are comparable in the sense that you mean).
I strongly endorse expectationaltotalhedonisticutilitarianism. So I would say the pain of an individual has 3 relevant dimensions. Probability, duration, and hedonistic intensity. I personally only care about the product between these. However, I think my argument works even for more dimensions. I believe any pains are quantitatively comparable if the pains of any 2 infinitesimally different states are quantitatively comparable.
Thanks for writing this, Vasco! And thanks for inviting me to comment given that you expected me to disagree with the conclusion (which I do :)). Iām still confused about these questions but I think there are two analogies from physics/āmathematics that might apply here and cast doubt on the postās conclusions, namely, (1) phase transitions and (2) topological transformations.
NB: I recorded a voice note into Claude and then asked it to structure and clarify my thinking, which I then cleaned up.
Your argument, as I understand it, goes something like this:
A human body can be described by the state of all its fundamental particles.
For any two states that differ only infinitesimally, the pain intensities must be quantitatively comparable.
You can get from any state to any other state via a chain of infinitesimal changes.
Therefore, all pain intensities are quantitatively comparable.
I think (2) is doing a lot of heavy lifting here, and I donāt think itās obviously true. The key issue is that continuous variation in underlying physical parameters does not entail continuous variation in the properties that emerge from them. This happens for example in phase transitions and topology.
Phase transitions
When you heat a ferromagnet continuously, nothing dramatic happens for a while. Then, at a specific critical temperature (the Curie temperature), ferromagnetism doesnāt just decrease, but it vanishes entirely. The property ābeing able to attract ironā is not something that fades smoothly to zero. It disappears at a sharp threshold, even though the underlying control parameter (temperature) was varied continuously.
Similarly, when you cool certain materials, electrical resistance drops to exactly zero at a critical temperature (superconductivity). āVery low resistanceā and āzero resistanceā are not just quantitatively different. Superconductors exhibit qualitatively new phenomena (persistent currents, the Meissner effect, flux quantization) that materials with merely very low resistance simply do not have.
In our earlier exchange, I used the water/āsteam analogy, and you responded that we can still compare the temperature of water and steam. Thatās true, but I should have added that I think pain might not be analogous to temperature, but to some other property. Temperature is a property that varies smoothly across the phase boundary, but there are other properties that only exist in one phase. For example, steam can do mechanical work via expansion (it drives turbines); liquid water cannot. Liquid water has surface tension (it forms droplets, menisci, capillary action); steam doesnāt. These properties arenāt ālessā or āmoreā across the transition. Theyāre categorically present or absent.
So the question is: is pain intensity more like temperature (a quantity that varies smoothly across all physical states), or more like magnetism or surface tension (a property that can appear, disappear, or transform categorically /ā jump at critical thresholds)?
I think thereās good reason to suspect the latter. For example, neurons themselves exhibit all-or-nothing action potentials. Below a voltage threshold, nothing propagates. Above it, a full spike fires. Continuous variation in input produces a binary output. If certain pain experiences depend on whether particular neural cascades fire or not, then the inference from āinfinitesimal change in particle positionsā to āinfinitesimal change in pain intensityā breaks down at these thresholds.
Topological transformations
Consider a rubber sphere. You can stretch it, compress it, bend it, twist it however you like, and it remains topologically a sphere. But to turn it into a torus (a donut shape), you need to introduce a hole. The number of holes (the āgenusā) is an integer. It cannot change by 0.01. And yet this discrete invariant determines fundamental properties of the surface, like how many independent loops can exist on it.
Or consider a loop of string. You can deform it continuously all day long, but the moment a crossing is introduced and locked in, you get a knot, which is a topologically distinct object. The unknot and the trefoil knot are categorically different. You cannot āhalfwayā have a knot. Knot invariants are discrete, even though every local manipulation of the string is smooth.
Suppose the morally relevant feature of a conscious experience is something like a topological property of the neural dynamics: perhaps the structure of information integration, the geometry of recurrent loops, or the topology of attractors in the brainās state space. More concretely, if pain was, say, the degree of dissonance in the electromagnetic waves generated by the nervous system, then introducing a topological defect into the field could suddenly allow new levels of dissonance not possible without the defect.
If thatās the case, then the argument āmoving an electron by 10^-100 m cannot prevent the pains from being quantitatively comparableā would be analogous to arguing āstretching a rubber sphere by 10^-100 m cannot change its genus.ā For most configurations, thatās true. But at a critical configuration, that tiny stretch is exactly what punctures the sphere and changes the genus from 0 to 1. The transition is sharp and local in parameter space.
So overall, I think the burden of proof is on showing that pain intensity actually behaves like temperature (smoothly varying, phase-invariant) rather than like magnetism, surface tension, or genus (categorically structured, with critical thresholds). I think itās more likely to be the latter (and that the symmetry theory of valence will be key in finding the solution).
My intuition is that the conclusion āI would prefer warming up slightly cold patches of soil for sufficiently many nematodes over averting 1 trillion human-years of extreme tortureā should be a reductio ad absurdum for the argument, and maybe the two angles above show how one might escape such a conclusion.
I hope this helps clarify where Iām at!
Hi Alfredo. Thanks for sharing your thoughts.
I am not sure the state of a human body is fully defined by the state of its fundamental particles, but I used this to mean all of its physical properties.
For my argument to work, it is enough for pain intensity to be quantitatively comparable for infinitesimally different physical parameters. The pain intensity does not have to be a continuous function of the physical parameters. I actually suspect physical parameters can only vary discretely, in agreement with quantum mechanics. So I believe both physical parameters and pain intensity vary in infinitesimally small jumps.
This is not true. I wonder whether Claude hallucinated it. Spontaneous magnetisation (M) just below the Curie temperature is proportional to (āCurie temperatureāāātemperatureā)^āexponent (0.34 for iron)ā. So spontaneous magnetisation smoothly goes to 0 as the temperature approaches the Curie temperature. In any case, spontaneous magnetisation would be comparable across any 2 temperatures even if it abrupty dropped to 0 near the Curie temperature. The spontaneous magnetisation for a temperature at least as high as the Curie temperature is 0 times that for a temperature below it.
The mechanism via which steam does mechanical work is fundamentally the same as that through which liquid water does mechanical work in hydropower. In both cases, molecules of water collide with turbines, and make them spin. For the case of steam, water vapour molecules are accelerated by temperature. For the case of hydropower, liquid water molecules are accelerate by gravity. In any case, the mechanical work done by steam and liquid water is quantitatively comparable.
The density of water also varies smoothly as it boils. It increases linearly with the vapour quality, which is the mass of water vapour as a fraction of all the mass. For a vapour quality of 0, there is saturated liquid water, and the density matches that of liquid water at the boiling point. For a vapour quality of 1, there is saturated water vapour, and the density matches that of water vapour at the boiling point.
In the example above, an infinitesimal change in a physical property (temperature) leads to an abrupt change in another physical property (density), but the underlying physical state does not change infinitesimally (at the boiling point, an infinitesimal change in vapour quality results in an infinitesimal change in density). In any case, a physical property varying abrupty for an infinitesimal change in the underlying physical state would not undermine my argument. The physical property in one state would have to be quantitatively incomparable with that on another state. The density of water at different states is quantitatively comparable.
Surface tension is technically not a property of liquid water or water vapour. It is a property of liquidāair interfaces, and it varies smoothly with temperature. The surface tension for the interface between liquid water and water vapour is different than that between liquid water and other gases.
Are you practically arguing that some pain intensities are not quantitatively comparable, even if their underlying physical states only differ infinitesimally, because there are mathematical functions which are not continuous? I do not understand why the space of possible mathematical functions would provide any meaningful empirical evidence about pain intensities.
My core point is that infinitesimal changes in physical reality do not make pain intensities quantitatively incomrable. Physical reality is infinitesimally changing all the time, and personally experienced pain intensities seem very much quantitatively comparable. So I would say the burden of proof is on showing this is not the case.
Likewise. Thanks for the opportunity to clarify my position.
Nice response, thanks a lot! :) I might share some more thoughts soon (e.g., maybe the assumption that pain is a one-dimensional quantity could be doing some additional heavy lifting here; and I guess others have discussed problems with aggregationism, which may still apply even if all pains are comparable in the sense that you mean).
I strongly endorse expectationaltotal hedonistic utilitarianism. So I would say the pain of an individual has 3 relevant dimensions. Probability, duration, and hedonistic intensity. I personally only care about the product between these. However, I think my argument works even for more dimensions. I believe any pains are quantitatively comparable if the pains of any 2 infinitesimally different states are quantitatively comparable.