2.1 Direct Questions and Strategic Misreporting

Direct questions concerning a sensitive topic generally elicit truthful responses from norm-compliers (i.e., $X_{i} = X^{*}_{i} = 0$ ). However, due to sensitivity concerns (e.g., social desirability bias or fears of the repercussions should a truthful answer be disclosed to third parties), norm-defiers often misreport their true status as $X_{i} = 0$ , thereby generating false negative measurements (Tourangeau and Yan Reference Tourangeau and Yan2007, 863). This is referred to as strategic misreporting (Ahlquist Reference Ahlquist2018). Letting $\theta = \text {Pr}(X_{i}=0|X_{i}^{*}=1)$ denote the probability with which norm-defiers strategically misreport for a direct question, the expected proportion of false negatives in the sample is $\theta \pi $ .

The direct question estimator of norm-defier prevalence is $\hat {\pi }^{\text {Direct}}=\frac {1}{N}\sum ^{N}_{i=1}X_{i}$ . Under the above assumptions, $\mathbb {E}(\hat {\pi }^{\text {Direct}}) = (1-\theta )\pi $ . Thus, as $\theta $ increases, $\mathbb {E}(\hat {\pi }^{\text {Direct}})$ decreases, inducing downward bias in the norm-defiance prevalence estimator.

2.2 List Experiments and Non-Strategic Misreporting

A list experiment is conventionally assumed to reduce strategic misreporting by asking about the sensitive item indirectly and thereby reducing sensitivity concerns among norm-defiers. A standard design randomly allocates respondents to either a list of J control items (treatment status $T_{i} = 0$ ) or a treatment list (treatment status $T_{i} = 1$ ) containing the J control items plus the sensitive item. In either case, respondents are asked only to report how many of the listed items they affirm, not which items they affirm. Let $Z_{ij}(T)$ be an indicator denoting whether respondent i affirms control item $j=\{1,\dots ,J\}$ under treatment status $T = \{0,1\}$ . Define $Y_{i}(0) = \sum _{j=1}^{J} Z_{ij}(0)$ and $Y_{i}(1) = \sum _{j=1}^{J} Z_{ij}(1) + X_{i}$ as respondent i’s potential reported item counts under the control and treatment conditions, respectively, and $Y_{i} =Y_{i}(T_{i})$ as their realized reported item count. Under this design, individual respondents’ answers to the sensitive item are masked from the researcher, or anyone else. Yet under the assumption of “no design effects” (i.e., $\sum _{j=1}^{J} Z_{ij}(0) =\sum _{j=1}^{J} Z_{ij}(1)$ ) and “no liars” (i.e., $X_{i}(1) = X^{*}_{i}$ ), the researcher can still obtain an unbiased estimate of norm-defier prevalence by taking the difference in means (DiM) of reported item counts for the treatment and control lists, $\hat {\pi }^{\text {List}} = \frac {1}{N_{1}}\sum ^{N}_{i=1}T_{i}Y_{i} -\frac {1}{N_{0}}\sum ^{N}_{i=1}(1-T_{i})Y_{i}$ , where $N_{1} = \sum ^{N}_{i=1}T_{i}$ is the size of the treatment group and $N_{0}=N-N_{1}$ is the size of the control group (Blair and Imai Reference Blair and Imai2012).

Even if list experiment masking eliminates strategic misreporting among norm-defiers, recent research proposes that the added complexity of the list question—which asks respondents to consider multiple items and to sum affirmed items before responding—may lead to increased nonstrategic misreporting (Ahlquist Reference Ahlquist2018; Kramon and Weghorst Reference Kramon and Weghorst2019; Riambau and Ostwald Reference Riambau and Ostwald2020). This occurs when respondents do not properly engage with the list question or make mistakes when answering it. For example, respondents are more likely to satisfice when answering more complex survey questions and do so by devoting less than optimal effort, performing some necessary cognitive steps roughly or skipping them altogether (Krosnick Reference Krosnick1991).

Formally, let the indicator $S_{i}^{*}$ capture whether respondent i is a list experiment nonstrategic misreporter. $S_{i}^{*} = 0$ when respondent i answers the list question via the process conventionally assumed, with potential responses that satisfy the no design effects and no liars assumptions. $S_{i}^{*} = 1$ when respondent i answers the list question via an alternative process prone to nonstrategic misreporting errors. Let $\lambda =\text {Pr}(S_{i}^{*}=1)$ denote the probability that a given respondent is a list experiment nonstrategic misreporter. We assume that the expected DiM among nonstrategic misreporters, which we define as $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) = \mathbb {E}(Y_{i}(1)|S_{i}^{*}=1) - \mathbb {E}(Y_{i}(0)|S_{i}^{*}=1)$ , is not driven by the true rate of norm-defiance among such respondents. Rather, it depends on the decision rule that nonstrategic misreporters use to pick their reported item count, and how the resulting reported item count varies as a function of whether they are asked about the longer treatment list or shorter control list.

Unlike strategic misreporting—which only leads to false negatives—a crucial feature of list experiment nonstrategic misreporting is that it plausibly leads to both false negatives among norm-defiers and false positives among norm-compliers. To see this, consider the example “uniform” nonstrategic misreporting scenario hypothesized in Ahlquist (Reference Ahlquist2018) and argued to be plausible in Blair et al. (Reference Blair, Chou and Imai2019). In this scenario, nonstrategic misreporters give an item count that is a random uniform draw from the response options available. This implies expected item counts of $\mathbb {E}(Y_{i}(0)|S_{i}^{*}=1) = \frac {J}{2}$ for the control list and $\mathbb {E}(Y_{i}(1)|S_{i}^{*}=1) = \frac {J+1}{2}$ for the treatment list, and an expected DiM among nonstrategic misreporters of $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) = 0.5$ . Among nonstrategic misreporters who are actual norm-defiers, this expected DiM is lower than the true norm-defier prevalence of one, leading to false negatives in expectation. Among nonstrategic misreporters who are actual norm-compliers, this expected DiM is higher than the true norm-defier prevalence of zero, leading to false positives in expectation.

This uniform process is just one possible example of a nonstrategic misreporting process. More generally, any such process that generates $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) < 1$ implies false negatives among norm-defiers (as would strategic misreporting), and any nonstrategic misreporting process generating $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}})> 0$ implies false positives among norm-compliers (unlike strategic misreporting). Thus, one need not assume a uniform nonstrategic misreporting process to be concerned that a list experiment may generate both false negatives and false positives: a range of nonstrategic misreporting processes can generate both types of error. As will be argued in the following section, this feature of nonstrategic misreporting means that existing list experiment validation approaches can mislead because they do not distinguish false from true positives and negatives.

Before proceeding, we note that list experiment nonstrategic misreporting generally biases the list prevalence estimate, the quantity of interest in much applied research. Ahlquist (Reference Ahlquist2018) and Blair et al. (Reference Blair, Chou and Imai2019) demonstrate the bias in DiM prevalence estimate for two specific types of nonstrategic misreporting process. Importantly, unlike with direct question strategic misreporting, the bias induced by list experiment nonstrategic misreporting can be either negative or positive. To see this, take the case where $S_{i}^{*}$ is independent of $X^{*}_{i}$ , so that the expected DiM among respondents for whom $S_{i}^{*} = 0$ is $\mathbb {E}(\hat {\pi }_{S^{*}=0}^{\text {List}}) = \pi $ . Then, $\mathbb {E}(\hat {\pi }^{\text {List}}) = (1-\lambda )\pi + \lambda \mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}})$ , which makes clear that for all $\lambda>0$ , the list prevalence estimator will be biased in expectation except in the special case where $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) = \pi $ . The bias will be positive when $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}})> \pi $ and negative when $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) < \pi $ . Since both $\lambda $ and $\mathbb {E}(\hat {\pi }_{S^{*}=1}^{\text {List}}) $ will usually be unobserved, both the magnitude and size of bias will be difficult to gauge in practical applications.

3.1 Existing Evidence on Nonstrategic Misreporting in List Experiments

Two recent studies use placebo tests to examine nonstrategic misreporting in list experiments. Riambau and Ostwald (Reference Riambau and Ostwald2020) run list experiments where the additional item on the treatment list has a known true sample prevalence of zero, but which yield DiMs that are positive and significant, consistent with nonstrategic misreporting where some respondents condition reported item count on list length. Kramon and Weghorst (Reference Kramon and Weghorst2019) compare respondents’ item counts for a list of manifestly nonsensitive topics to the counts implied by the same respondents’ answers to direct questions on the same topics. The counts should not differ as there should be no direct question strategic misreporting for the list question to ameliorate. But they do differ in 60% of cases (and more so among respondents with lower numeracy and literacy) suggesting that list experiment measures may differ from direct question ones not just by reducing strategic misreporting, but also because their “complexity and difficulty” (p. 4) induces more reporting errors.

Despite this evidence of list experiment nonstrategic misreporting, key questions remain for applied researchers choosing between list experiments and direct questions. First, Riambau and Ostwald (Reference Riambau and Ostwald2020) benchmark list prevalence estimates against true scores only, so cannot gauge the relative magnitude of list versus direct question misreporting error. Second, Kramon and Weghorst (Reference Kramon and Weghorst2019) compare list and direct question responses only, so cannot gauge the magnitude of misreporting errors for either relative to the truth. Third, neither study examines measurement of a sensitive topic, which is essential to assess whether any increase in nonstrategic misreporting induced by using a list experiment rather than direct question outweighs the reduction in strategic misreporting. The evidence we present below does all of these three things.

Alvarez et al. (Reference Alvarez, Atkeson, Levin and Li2019) identify likely survey satisficer respondents via screening questions and show that they respond differently to both direct questions and list experiments than do other respondents. However, in the absence of true scores on the sensitive item, they cannot establish whether these differences arise because satisficers misreport more or because the their true prevalence rate differs, nor whether list experiments induce more or less misreporting than direct questions in each group.

Others examine how problematic nonstrategic misreporting is for list experiment estimators. Building on Ahlquist (Reference Ahlquist2018), Blair et al. (Reference Blair, Chou and Imai2019) suggest a diagnostic test for list experiment measurement error (whether strategic or nonstrategic) that compares maximum likelihood (ML) and nonlinear least squares (NLS) estimates. They show that nonstrategic misreporting does bias list prevalence estimates, but find in simulation studies that the DiM prevalence estimator and NLS estimator are more robust to nonstrategic misreporting than are ML estimators, and that all estimators exhibit only mild biases for the scenarios they consider. They also develop new regression estimators that explicitly model a uniform nonstrategic misreporting process and a “top-biased” process (where nonstrategic misreporters always select the maximum item count available), although they recommend that, due to its “simplicity and robustness” (p. 473), basic DiM should still be used to estimate prevalence alone. These studies offer valuable guidance, but do not speak explicitly to the misreporting trade-off between list experiment and direct question. Moreover, the simulations used must make assumptions about the nature and frequency of nonstrategic misreporting. The validation evidence we present below offers more direct empirical evidence concerning the severity of nonstrategic misreporting error in list experiments in practice.

In sum, existing research suggests that nonstrategic misreporting does occur in practice in list experiments. However, for applied researchers considering whether the use of a list experiment in their survey will reduce overall misreporting on a sensitive topic, further evidence is required on the relative severity of list experiment nonstrategic misreporting and direct question misreporting in practice.Footnote ²

3.2 Existing Validation Approaches

The most common approach to list experiment validation in existing studies involves simple comparison of list and direct question prevalence estimates. This approach, which we call comparative prevalence validation, invokes a “more is better” assumption (Tourangeau and Yan Reference Tourangeau and Yan2007; Höglinger and Diekmann Reference Höglinger and Diekmann2017): the list experiment is judged to improve on the direct question when it estimates greater norm-defier prevalence. By this criterion, the list experiment significantly outperforms a direct question in 63% of 48 comparative validation studies covering a range of sensitive topics (Holbrook and Krosnick Reference Holbrook and Krosnick2010).

Population prevalence validation additionally compares direct and list experiment prevalence estimates against an observed true population benchmark and makes a “closer is better” assumption: if its prevalence estimate is closer to the population prevalence, the list experiment offers a better measure. For example, Rosenfeld, Imai, and Shapiro (Reference Rosenfeld, Imai and Shapiro2016) benchmark list and direct prevalence estimates of anti-abortion attitudes against actual population support for anti-abortion measures in a public referendum, and others benchmark election turnout estimates against official population turnout (e.g., Holbrook and Krosnick Reference Holbrook and Krosnick2010; Kuhn and Vivyan Reference Kuhn and Vivyan2018).

However, both comparative and population prevalence validation approaches may mislead in the presence of nonstrategic misreporting (Höglinger and Diekmann Reference Höglinger and Diekmann2017; Höglinger and Jann Reference Höglinger and Jann2018). Comparative prevalence validation assumes that list experiments only generate higher norm-defier prevalence estimates than direct questions due to reduced strategic misreporting causing reductions in false negative measurements. However, list experiment prevalence estimates may be higher than direct question estimates not because the list question reduces false negatives among norm-defiers, but because nonstrategic misreporting for the list question yields additional false positives among norm-compliers. A similar problem arises with population prevalence validation: compared to a direct question which underestimates population prevalence due to strategic misreporting, a list experiment subject to nonstrategic misreporting may move the norm-defier prevalence estimate closer to the population benchmark by increasing false positives among norm-compliers (Höglinger and Diekmann Reference Höglinger and Diekmann2017).Footnote ³ To properly assess whether list experiments reduce misreporting compared to direct questions, we need validation approaches that distinguish false from true negative and false from true positive responses (Höglinger and Jann Reference Höglinger and Jann2018).

5.1 Survey Instruments

We embedded the New Zealand list experiment in the 2017 New Zealand Election Study (NZES). The NZES collected responses from 3,455 respondents, sampled from the national electoral rolls. Respondents were contacted by mail beginning 4 days after the general election of September 23. Fieldwork continued until early March 2018, although approximately 97% of responses were received within two months of commencement. The London list experiment was fielded via an online YouGov survey of a sample of 3,189 Greater Londoners following the June 8, 2017 UK general election (fieldwork began on June 23 and ended on July 24, 2017). We surveyed Londoners, rather than Britons generally, to make collection of true turnout measures economically feasible (the official records necessary for this must be accessed physically at each local authority office). Further details on sampling and fieldwork for each survey are provided in online Appendix A.

Table 1 presents the list experiment and direct questions used to measure turnout in each survey. In both surveys, all respondents were randomized to either the control or treatment list (the latter being the list question in Table 1 with the item in parentheses included). List response options ranged from zero to four (control group) or five (treatment group), and a “don’t know” response was available.

Table 1 List experiment and direct questions for New Zealand and London surveys.

In designing the list experiments, we follow recent practice. Several design choices in particular merit discussion. First, in both the New Zealand and London designs, we include control activities which we expect most respondents to have undertaken (“Discussed the election with…”) and which we expect few respondents to have undertaken (“Worked or volunteered for one of the party campaigns” or “Put up a poster for a political party in my window or garden”). This follows Blair and Imai (Reference Blair and Imai2012) design advice and is intended to minimize ceiling and floor effects—where respondents affirm or negate all control items, so that their sensitive item response is no longer masked—which may undermine the ability of the list experiment to reduce strategic misreporting.

Second, we included only election-related control items in both list experiments. On the one hand, there is a risk that including election-related control items may prime respondents to become concerned about their general level of political engagement, increasing sensitivity of the turnout item and counteracting any sensitivity-reducing effect of list experiment masking. On the other hand, including control items on a different topic to the sensitive item may draw respondents’ attention to that item and enhance its sensitivity (Lax, Phillips, and Stollwerk Reference Lax, Phillips and Stollwerk2016). Furthermore, the inclusion of low-cost, high-prevalence, election-related activities among list control items may reduce the sensitivity of the turnout item by allowing respondents to indicate that they did at least partake in some election activities, even if they did not vote. On balance, our expectation is that this design choice should reduce the sensitivity of the turnout item and thereby enhance the ability of each list experiment to reduce strategic turnout misreporting compared to the direct question. It should also discourage nonstrategic misreporting for the list experiments, since coherent grouping of question topics reduces cognitive processing costs for respondents, making satisficing or mistakes less likely (Krosnick and Presser Reference Krosnick, Presser, Wright and Marsdent2010).

Third, while the New Zealand control items consist exclusively of “norm-compliant” election-related behaviors, we include two “norm-defiant” behaviors (“avoided watching the leaders debate” and “criticised a politician on social media”) among the four London control items. Norm-defiant control items were included in a list experiment on turnout with promising population prevalence validation results by Kuhn and Vivyan (Reference Kuhn and Vivyan2018). They reason that norm-defiant control items signal to respondents that it is recognized that some people do not like or engage with politics, thereby further reducing the potential discomfort of admitting nonvoting. To the extent that this holds, the London list experiment should be more effective than the New Zealand one at reducing strategic turnout misreporting among nonvoters. On the other hand, the inclusion of norm-compliant and -defiant items on a list may confuse respondents, which may result in greater list experiment nonstrategic misreporting in London compared to New Zealand.

Both surveys also include a standard direct turnout question (Table 1, bottom row). In the New Zealand survey, the direct question was asked of all respondents at least 41 questions after the list experiment (itself the second item on the survey). In case exposure to the turnout item in the list question primed list treatment group respondents in any way (Blair and Imai Reference Blair and Imai2012), we subset to direct question responses from list control group respondents in the main validation analysis below.Footnote ⁵

In the London survey, we have two separate direct measures of turnout based on the same question wording: a baseline (pretreatment) measure from a direct question that YouGov asked of panelists in the days immediately following the election and a measure from a direct question included in our survey for list control group respondents (asked immediately after the list question). For our main validation analysis below, we rely on the latter measure.Footnote ⁶ The “baseline” direct measure of turnout will be used later when testing for the effects of satisficing on list experiment misreporting error.

5.2 True Turnout Measures

Each survey respondents’ true turnout in the relevant general election was measured via manual inspection of marked electoral rolls. For New Zealand, true turnout measurements were collected by the NZES team. Of the 3,455 2017 NZES respondents, definitive measures of true turnout were obtained for 3,451 (99.9%): these respondents were successfully located and their turnout status clearly observed on the marked election rolls. Remaining respondents with nondefinitive true turnout measures are treated as missing. For London, we collected definitive true turnout measures for 2,595 respondents (82.4%). The rate of definitive true turnout measurements is lower than for the NZES, because, unlike the NZES, YouGov do not sample directly from the electoral register. The resulting sample may therefore contain respondents (a) who are not on the register or (b) whose name and address details recorded with YouGov contain errors preventing matching to the official register. The lower rate of definitive true turnout measurements in London is a concern for list experiment validation if respondents who do and do not have definitive true turnout scores differ systematically in how they answer list and direct turnout questions. We see little reason for this to be the case, and are reassured by the similarity between the London and New Zealand results below, given the latter sample contains almost no respondents with missing true turnout scores. Online Appendix A gives further details on true turnout measurement.