If the aim is to give all citizens an equal chance of getting the vaccine, in the name of impartiality, then this policy is no good.

One possible solution is to say that any leftover vaccine should be wasted. If Beta is selected by the lottery, then Beta—and Beta alone—should be vaccinated. Though there is also enough vaccine left over for Gamma, it would be unfair to vaccinate her too, for she was in the lottery and lost.

However, the idea that impartiality requires wasting potentially life-saving vaccine seems counterintuitive. The state has a duty to protect all of its citizens. Impartiality matters where it cannot protect all and must therefore choose which citizens to vaccinate, but it would be perverse if it were to discard vaccine simply because it cannot vaccinate everyone. If that were the preferred option, then, presumably, there would be no need for a lottery to begin with; the state might simply discard all of its vaccine and vaccinate nobody. This might be the fairest solution (Broome 1991, p. 95; cf. Lazenby 2014, p. 335–336), since it guarantees that all citizens get nothing. However, our rejection of this solution shows that we care not only about equality but also about the saving of lives (Piller 2017, p. 215).[7]

Thankfully, there is another possibility. Once it is realized that Beta and Gamma can be treated together, they could be given a single lottery ticket. Thus, we can increase everyone’s chance of getting vaccinated (from 33 percent to 50 percent) and avoid waste at the same time.

This proposal gives everyone the greatest equal chance of vaccination (Hirose 2007). While Beta and Gamma had a greater chance under option 1, this came at the expense of inequality, in the form of a much lower chance for Alpha. Note also that, while this particular example concerns only a two-against-one conflict, the same logic would apply in more extreme cases. For instance, suppose Alpha needed 500 mL of the vaccine, while ten other people each needed 50 mL. Again, giving everyone the greatest equal chance of receiving an effective dose of the vaccine would mean, in effect, tossing a coin between Alpha and the other ten.

It is not clear what Peterson’s recommendation would be here. First, it depends on how much priority was assigned to the worse off.[8] Option 1 gives Alpha only a one-in-three chance of survival, whereas Beta and Gamma each have a two-in-three chance of survival, because both of them can be rescued together. Option 3 would increase Alpha’s chances, from one in three to one in two, but both Beta and Gamma would see their chances fall, from two in three to one in two. Prioritarianism tells us that more weight, or value, should be given to the prospects of the worse off (Alpha). Thus, if the choice were simply between Alpha and Beta, prioritarianism would recommend reducing Beta’s chances of survival in order to increase Alpha’s (up to the point at which Alpha is as well off as Beta). However, whether it is worth reducing the chances of two people (Beta and Gamma) by one in six in order to increase Alpha’s chances by one in six depends on how much priority Alpha is given. If we give only very weak priority to Alpha, then her gain may not be enough to outweigh the gain to Beta and Gamma. Second, it is unclear whether (priority-weighted) chances are the only good to be considered in Peterson’s consequentialist framework, or whether they must be balanced against conventional utility when the best overall consequences are being determined. If the latter, this would be a further reason to favour policies saving more people.

Given the indeterminacy of Peterson’s proposal in such cases, the immediate discussion will focus primarily on McLachlan (though some of the later discussion is relevant to Peterson too). McLachlan does not explicitly discuss cases such as these, where there are differing levels of need. It is possible that he might consider need a relevant difference between individuals, thereby justifying differential chances. However, if this were so, then it might be justifiable to aim at maximizing the number of lives saved, and McLachlan clearly rejects this. He explicitly accepts that impartial treatment of all citizens might result in worse outcomes (2012, p. 317). Thus, it seems likely that he would favour option 3 over either option 1 (which gives some better chances than others) or option 2 (which, by being wasteful, is worse for everyone).

If this is McLachlan’s position, this is interesting, since this has not been a popular solution to the analogous “numbers problem” posed by John Taurek (1977), in which a rescuer must choose between saving one person or two others. While consequentialists take the solution to be obvious (save the greater number), most nonconsequentialists who have considered this problem also think that numbers matter in some way. Some have sought to argue for a policy of saving the greater number on nonconsequentialist grounds (Scanlon 1998, p. 229–241; Hirose 2004), while others have advocated weighted lotteries that give larger groups a greater chance of rescue (Timmermann 2004; Saunders 2009). There are some who defend positions close to this, though few, if any, hold that groups of unequal sizes must be given equal chances. Taurek (1977, p. 306) suggests that, when faced with a choice between saving one person or five others, then, other things being equal, he would give each an equal chance by tossing a coin. However, he does not argue that this is obligatory; since he thinks it permissible to save either group, it could be that he considers the situation to be like that facing Buridan’s ass. Other authors argue that tossing a coin is better than a weighted lottery (Hirose 2007; Huseby 2011), but they generally think that saving the greater number is better still (Hirose 2004; Huseby 2012). Broome (1998) argues that tossing a coin between groups of different sizes may be fair, because it gives everyone an equal chance of survival, but denies that this is what must be done all things considered, since sometimes (in his view) the extra value of saving more lives, without a lottery, outweighs the unfairness of doing so. Hence, if this is McLachlan’s position, it is not a popular one, even among nonconsequentialists.

While I cannot review all of the now-extensive literature on this “numbers problem” here, it should be noted that the various solutions proposed can be (and often are) defended as alternative interpretations of equal or impartial concern for all involved. For instance, Frances Kamm (1985) and Jens Timmermann (2004) have each defended proposals analogous to option 1 here. Though this proposal does mean that some will have a greater chance of being saved than others, it can be seen as giving each an equal “baseline chance” (Kamm 1985, p. 185). Circumstances may be such that, after Beta has been picked, it is still possible to save Gamma, but this does not necessarily justify depriving Gamma of her own independent chance. Scanlon (1998, p. 232) claims that Gamma could reasonably reject any procedure for vaccine allocation that effectively ignores her presence by treating the choice between Alpha on the one hand and Beta and Gamma on the other the same as a choice simply between Alpha and Beta.[9]

To settle on the best account of impartial treatment in such cases is beyond the scope of the present article. My aim is simply to point out that the requirements of impartiality are hotly contested. Moreover, one cannot simply assume that impartial treatment will result in people getting equal chances of vaccination (as McLachlan does) or equal chances of survival (as Peterson does). We might arrive at unequal chances without showing any partiality for particular individuals.

Allocate the first dose by lottery, giving each person a one-in-three chance of receiving it. Then allocate the second dose by lottery, between those still in need. This means that if either Beta or Gamma won the first lottery, they would no longer be in need and the second lottery would be fifty-fifty between the remaining two. However, if Alpha won the first lottery, she would still be in need, so the second lottery would also give each of the three a one-in-three chance to receive the second dose.

Alpha will survive only if she wins both lotteries, so her chance of survival is one in nine. Beta and Gamma are symmetrically situated, and each have an eleven-in-eighteen chance of survival.[10] In this case, the chances of Beta surviving are over five times greater than the chances of Alpha surviving, even though they each were given an equal chance to get each dose of drug that they needed.

One oddity of this policy is that it might give Alpha the second dose of the drug, even when she did not win the first, even though this is (by hypothesis) useless to her. Thus, this policy is wasteful, by which I mean not simply that it does not maximize the number of lives saved, but that it may give one (and only one) dose of vaccine to Alpha, though this will do no good. To illustrate this, suppose that Gamma wins the first dose. In this case, we may think that there is no point in holding a second lottery. Though Alpha and Beta are both still needy, the remaining dose is no use to Alpha, though it would save Beta. Hence, we might prefer a policy that avoids this waste, which I call option 5.

Allocate the first dose by lottery, giving each person a one-in-three chance of receiving it. If Alpha wins the first dose, then allocate the second dose by lottery, giving each person a one-in-three chance of receiving it. However, if Beta wins the first lottery, give the second dose to Gamma, since it is no use to Alpha. And, conversely, if Gamma wins the first lottery, give the second dose to Beta.

Again, Alpha gets the two doses needed only if she wins both lotteries, which is a one-in-nine chance. Here, however, Beta and Gamma have even better prospects, since there is no danger of wasting the second dose. Their chances of survival are now seven in nine, since Beta will certainly be saved either if she wins the first lottery (one in three) or if Gamma wins the first lottery (one in three) or if Alpha wins the first lottery but she (Beta) wins the second lottery (one in nine).

Compared to option 4, this option is what economists term a “Pareto improvement.” It is no worse for anyone—Alpha’s chances of survival are not reduced—but this option improves the prospects of both Beta and Gamma. It does this by eliminating the chance of wastefully giving the second dose to Alpha in cases where she did not win the first dose (this does not make Alpha worse off, in terms of health outcomes). Note, however, that this is not simply a maximizing strategy; while Beta and Gamma each enjoy a greater chance of survival than Alpha, they are not automatically saved. Furthermore, option 5 still involves some risk of the first dose being wasted, since Alpha may win that but not the second. Since this is still wasteful, we might prefer a policy that avoids this too.

Allocate the first dose by lottery, giving each person a one-in-three chance of receiving it. If Beta wins the first dose, then give the second to Gamma, and vice versa. So far, this is the same as option 5, but, if Alpha wins the first dose, then give her the second dose too, in order to avoid waste. (This is option 1 from the previous section.)

Here, Alpha has a one-in-three chance of survival, whereas Beta and Gamma each have a two-in-three chance of survival (because if either of them wins the first lottery, then, in effect, they both win). This is better for everyone than option 4 is; however, for Beta and Gamma it is worse than option 5. Even though it is more efficient, by reducing any chance of waste, their chances of survival are reduced from seven in nine to six in nine. However, this loss is necessary in order to improve Alpha’s chances of survival. Furthermore, Beta and Gamma are still twice as likely to survive as Alpha is. This itself might be thought objectionably unfair. There is, however, another policy option that gives all three an equal chance of survival.

Since giving the first dose to Beta will mean giving the second to Gamma, and vice versa, they can effectively “share” chances (cf. Hirose 2007, p. 50). Thus, allocate both doses together, giving a 50 percent chance to Alpha and a 50 percent chance to Beta and Gamma. (This is option 3 from the previous section.)

This way, everyone has a 50 percent chance of survival (or of receiving an effective dose of vaccine). Furthermore, no vaccine is ever wasted, unlike in options 4 and 5. However, this option is inefficient when judged on the expected consequences, for the expected number of lives lost is 1.5, and it can also be argued that it is unfair to Gamma, since her presence makes no difference to the procedure (Scanlon 1998, p. 232).

This is not an exhaustive list of options. Two others worth mentioning are (i) a policy that aims to maximize the total number of lives saved by giving the vaccine to Beta and Gamma without a lottery and (ii) a policy that gives the drug to no one, which would be perfectly equal but highly inefficient. Since these can be taken to represent opposing ideals—one giving absolute priority to efficiency over equality, and the other absolute priority to equality over efficieny—they are useful options to consider. I label the maximizing policy option 8 and the policy of leaving everyone to die option 9.

These six policies, along with their consequences, can be summarized as follows. For ease of comparison, I have expressed each person’s chance of survival in eighteenths, even though some fractions could be simplified (e.g., six eighteenths to one third).

One option is to say that Alpha should not enjoy any special privilege as a result of her occupation. She is no more likely to be exposed to infection than anyone else, so Peterson’s proposal that those at greater risk should have greater chances of getting the vaccine, in order to equalize their chances of survival, does not apply. Similarly, McLachlan’s suggestion that the state must protect those healthcare workers who assume risk in their occupation does not apply. Thus, it may seem that Alpha should not enjoy any greater chance of receiving the vaccine than anyone else, even though giving her a greater chance could result in more lives saved. This option looks, at first sight, as though it would treat others unfairly.

However, first appearances are deceptive here. Suppose that one refuses to give Alpha any special privilege and runs the lottery as before, giving each individual a 20 percent chance of survival. In this case, Alpha has a 20 percent chance of survival, but the others actually have a greater chance of survival. Since the other nine individuals are identically situated, it will suffice to consider only Beta. Beta, like Alpha, has a 20 percent chance of receiving one of the two initial doses of vaccine. However, Beta also has an additional chance of being saved because, if Beta does not receive one of the initial doses, but Alpha does, then Beta might receive one of the two additional doses that Alpha will produce.

There is an 80 percent chance that Beta will not get one of the initial doses. In two ninths of those cases, where Beta does not get a dose, Alpha does.[12] There is an almost 18 percent (sixteen-in-ninety) chance that Alpha will get a dose and not Beta. In these cases, there will then be two extra doses and eight people still in need. So, in these cases, Beta will now have a one-in-four (25 percent) chance of getting one of these extra doses. That means that Beta enjoys an extra four-in-ninety chance of survival. Therefore, her overall chances of survival are twenty-two in ninety, which is higher than Alpha’s eighteen-in-ninety chances because, self-evidently, Alpha can never be the one to benefit from her producing the extra vaccine.

This seems unfair. While each individual receives the same 20 percent chance of getting one of the initial vaccine doses, Beta has a greater chance of receiving a vaccine dose than Alpha, because Beta gets a second chance to benefit if Alpha survives. Refusing to give Alpha any extra chance not only reduces the overall good that can be done, but also consigns her to a lower chance of survival than anyone else. Even if our aim is merely to give everyone an equal chance of receiving an effective dose of vaccine, we might seek to “compensate” Alpha for this, by giving her a higher chance of getting one of the initial doses. Doing this has two benefits. First, we can give Alpha the same chances of survival as everyone else. Second, by making it more likely that Alpha survives—and hence more likely that the two additional doses of vaccine are produced—we make it more likely that more lives are saved.

Alpha is given a 25 percent chance of receiving one of the two initial doses of vaccine. The other nine have their chances of receiving one of these doses reduced accordingly (to 19.44 percent). However, while Beta has a lesser chance of getting one of the initial doses, she is more likely to benefit from a second chance, because it is more likely that Alpha will survive. In fact, Beta’s overall chances of survival also come to 25 percent, the same as Alpha.[13]

This option rectifies the inequality in option 10 by increasing Alpha’s chances of getting one of the initial vaccine doses. Further, because this also increases the probability that Alpha can produce additional vaccine, it actually increases everyone’s chances of survival. True, Beta’s chances are not increased to the same extent as Alpha’s. Beta sees an increase only from 24 percent to 25 percent, while Alpha’s chances increase from 20 percent to 25 percent. But this is because Beta already enjoyed a greater chance than Alpha in option 10 (24 percent as opposed to 20 percent), which is precisely what seemed unfair about it. Option 11 redresses this inequality without making Beta and the others worse off. Presumably, then, all ten individuals involved would prefer option 11 to option 10, since it increases their chances of survival.

I assume that both Peterson and McLachlan would prefer option 11 to option 10. Whether we are concerned with equalizing individuals’ chances of survival or their chances of getting an effective dose (which, given my simplifying assumptions, amount to the same thing here), option 11 results in equal chances. The lesson, however, is that we might have to weight the lottery, giving some more chance than others of winning the lottery, in order to equalize everyone’s chances of getting the vaccine. We cannot simply assume that an equiprobable lottery gives each person the same chance of receiving the vaccine when the outcome of the lottery also influences how much vaccine is available.

However, while option 11 is an improvement on option 10, it is not the best that we can do from the point of view of efficiency. Since giving one dose to Alpha will result in two additional doses, more than replacing what was used, it is possible to increase everyone’s chances still further.

Give the first dose to Alpha, without a lottery. Allocate the other of the initial doses, and the two extra doses produced by Alpha, by lottery, giving each of the other nine individuals an equal chance. Allocating three doses between nine people means that each has a one-in-three (33.33 percent) chance of receiving a dose of vaccine.

If we do this, then there is a further Pareto improvement: everyone’s chances of survival are increased. However, once again, Alpha enjoys a larger share of the benefit than the other nine. The result is that we depart from the equality of option 11. In this case, Alpha receives the vaccine for certain, which makes her much more likely to benefit than anyone else. The fact that Alpha’s survival is instrumentally useful does not give her any greater claim to the vaccine, though. Thus, while it may be rational for all involved to consent to Alpha receiving one of the initial doses, it is nonetheless unfair (Broome 1991). It is an unfairness that we should almost certainly tolerate, since it increases everyone’s chances of receiving the vaccine, so to insist on equality would represent a particularly harsh form of levelling down (Parfit 1997, p. 211). If we are prepared to compromise equality for the sake of efficiency by allocating the vaccine by lottery in the first place, rather than giving it to no one, then we ought also to prioritize efficiency here.

In fact, Peterson seems clearly committed to this conclusion, since he rejects equality as a moral ideal, on the grounds that it may require levelling down, and instead endorses a form of prioritarianism (2008, p. 324–325). According to prioritarianism, a benefit of given magnitude produces more moral value when given to someone who is worse off than someone who is better off. This diminishing marginal value of benefits favours an equal distribution of benefit where the total amount of benefit is fixed and benefits can be reallocated without cost. For example, the prioritarian will think a world where everybody has $10 better than a world where half have $5 and half have $15, because giving $5 to the poorer people produces more moral value than is lost when it is taken from the rich. However, the prioritarian denies that there is any gain to be had by making the rich poorer. If we were unable to make the poor any better off, but we could reduce everyone to having $5, then those who value equality as such seem committed to thinking that this would be in one respect good, since it would be more equal (Parfit 1997, p. 210–211). The prioritarian, in contrast, thinks that this would be an unmitigated loss.[14] Though we are presently concerned with distributing (chances of getting) a vaccine, rather than money, the same is true here. There is simply nothing to be gained from making the better off (Alpha) worse off, if we cannot thereby improve the lot of the worse off.

McLachlan’s attitude is harder to predict. On the one hand, McLachlan is clearly committed to the value of equality, even when it results in more deaths (McLachlan 2015, p. 193). On the other hand, his case for giving everyone equal chances is that the state ought to treat its citizens “the same in relevant respects unless there are relevant reasons for treating them differently” (McLachlan 2012, p. 317, emphasis added). When he introduces priority for frontline healthcare workers, he refers to there being “at least one relevant reason for treating some citizens differently” (McLachlan 2012, p. 318)—namely, the fact that their occupation puts them in danger. This reason does not extend to those whose work involves production of vaccines who, I assume, are at no greater risk of infection than anyone else. Nonetheless, it is possible that the case I am considering, in which giving Alpha priority benefits everyone else, represents another relevant reason to depart from equal chances. Further, he suggests that, “if all rational people could be expected to favour a particular policy [this] might be an indication that a policy is impartial” (McLachlan 2015, p. 194), though he suggests that this may be neither necessary nor sufficient to establish impartiality.

I would suggest that, if we find ourselves in these circumstances, we ought to favour option 12. If we take the perspective of those involved, then what they care about is maximizing their own chances of survival. They ought not to care what chances others have, except insofar as those chances affect their own chances. (Indeed, if anything, they ought to welcome more others surviving along with them.) It would not help Beta to reduce Alpha’s chances of survival if this did not increase Beta’s chances, and this is true a fortiori where Beta’s chances are actually lessened. To reduce everyone’s chances for the sake of equality would be to make a fetish of equality. The only reason to care about equality is that we are distributing a good, hence people should prefer inequality if it means more of that good for all.

This situation is similar to Rawls’s famous original position (Rawls 1999, p. 15–19). Here, Rawls assumes that parties are concerned only with their absolute position and not with how they stand relative to others. Thus, he proposes that they would reject strict egalitarianism in favour of the difference principle, which permits inequalities that benefit all (ibid, p. 65–73).[15] Rawls intends the difference principle to apply to the basic structure of society and only to certain goods (ibid, p. 6–10). Nonetheless, my proposal is an application of similar reasoning to the problem at hand. That is, I suggest that vaccine ought to be distributed equally unless an unequal distribution benefits everyone. This policy satisfies the requirement to treat everyone impartially. It explains why we should prefer allocating effective doses of vaccine by lottery to giving everyone an equal but ineffective share of the vaccine. And it also tells us that if prioritizing Alpha improves everyone’s chances of survival, this is what we should do.

Note that, while I have focused on what might be termed a “positive” case—where there is a reason to prioritize Alpha because she can produce more vaccine and thereby increase the number of people vaccinated—there is also a parallel “negative” case for prioritization, where leaving someone unvaccinated would increase danger to others. Some groups may be more likely to spread infection than others. For example, the homeless—because they are more likely to move around—may increase risk to others (Buccieri and Gaetz 2013, p. 189–190). Suppose we have five individuals, each of whom has an equal chance of being one of three who will be infected, but we have only one dose of vaccine. Allocating that vaccine by lottery gives each person a 20 percent chance of protection and a 48 percent chance of being infected without vaccination. But now change our assumptions. Suppose that if we were to give the vaccine to Delta, a homeless person, the spread of disease would be reduced and only two people would be infected. The other four would be denied the vaccine, but their chances of infection would be reduced to 40 percent.[16] Again, it would be rational for all to agree to this prioritization, since everyone’s chances of avoiding infection would be increased. To be sure, Delta may seem a less “worthy” candidate for prioritization than Alpha, because Delta exposes others to risk, rather than providing protection. The homeless, like many other at-risk groups, are stigmatized, and this may affect public attitudes towards such prioritization (Kaposy and Bandrauk 2012). However, statistically, the cases are equivalent. More people will contract infection if Alpha (in the first example) or Delta (in the second example) is not vaccinated. The case for prioritizing them has nothing to do with their moral worth or desert, but simply with the fact that giving them the vaccine improves everyone else’s chances.

The lesson, I suggest, is that equal consideration of everyone does not necessarily mean giving everyone equal chances. As pointed out above, giving everyone equal chances is compatible with giving everyone zero chance, but this would be equal neglect, rather than equal concern. If we are to show not only equal but also maximal concern for each person, then we ought to favour increasing each person’s chances of survival, whenever it is possible to do so consistent with similar concern for others.

It might be worried that this would inevitably lead to a form of consequentialism according to which we ought to show equal concern and respect for all by maximizing the number of lives saved (other things being equal).[17] This is not so. I believe that consequentialism is best understood as offering another interpretation of impartial concern for all. However, consequentialists focus on the good of all as a collective, rather than on the good of each.[18] Thus, they ignore the separateness of persons (cf. Rawls 1999, p. 23–24). If one focuses only on maximizing total prospects of survival, then it makes no difference whether we increase Alpha’s chances or Beta’s. The impartial consequentialist is indifferent between giving them each a 50 percent chance, on the one hand, and giving Alpha a 100 percent chance and Beta no chance at all, on the other. Moreover, consequentialists would prefer a world in which Alpha has a 90 percent chance and Beta a 20 percent chance, since it increases the overall good. However, the distribution of chances does matter to the individuals concerned. If Beta’s chances are reduced from 50 percent to 20 percent, it is no compensation to her that Alpha enjoys a greater increase, from 50 percent to 90 percent.

Thus, Beta may have reasonable grounds to reject a principle that treats this simply as an improvement. Perhaps there is a point at which Beta ought to accept a loss because what others have at stake is greater. For example, maybe Beta should accept her chances being reduced from 50 percent to 49 percent if we can thereby increase Alpha’s chances from 50 percent to 99 percent. But Beta is not required to be perfectly indifferent between her own chance to receive the vaccine and Alpha’s. Hence, we might reject consequentialism as failing to show due concern for each person.

A rejection of consequentialism should not, however, be confused with a rejection of efficiency. The difference between consequentialists and nonconsequentialists is a difference about why particular choices are right or wrong (McLachlan 2015, p. 193). In very many cases, they agree about what is right or wrong. Thus, we should not assume that any policy aiming to maximize the number of lives saved is necessarily consequentialist and reject it for that reason. Peterson (2008) demonstrates that not all consequentialists will favour maximizing the number of lives saved. Conversely, some nonconsequentialists may favour a policy that seeks to maximize the number of lives saved (Scanlon 1998). As long as everyone stands to benefit from the adoption of this policy, even if not necessarily benefiting equally, it may be that this is what would follow from a nonconsequentialist approach to morality, such as Scanlonian contractualism.