MEASURING AND MODELING PERSUASION

The standard approach to measuring persuasion in the small-group literature evaluates changes in a discussion participant's self-reported preferences from before to after a discussion event (for example, Grönlund, Herne and Setälä Reference Grönlund, Herne and Setälä2015; Schkade, Sunstein and Hastie Reference Schkade, Sunstein and Hastie2010; Westwood Reference Westwood2015). In a basic small-group design, the researcher typically administers a survey to each participant before exposure to the group to measure their pre-treatment preferences on an item or topic, which we will label $O_i^0 $. Next, the researcher randomizes each participant's assignment to a small group. This randomization varies the composition of the group to which each participant is exposed. For example, randomization will vary the distribution of ideological ideal points within a group, so in small groups they will randomly assign each participant to a group that is on average either liberal or conservative (or anything in between), and that is either diverse in ideology or homogeneous. The groups are invited to have a discussion, and afterwards the researcher will measure the respondents' post-treatment preferences, $O_i^1 $.

In the basic design, the researcher will conduct a statistical test to see if there is a relationship between group exposure and the difference between the pre-treatment and post-treatment response, $(O_i^1 -O_i^0 )$. Farrar et al. (Reference Farrar2009, 619) is an exemplar of current practices, which models preference change in response to exposure to a small-group discussion as:

(1a)$$O_i^1 = \beta _0 + \beta _1O_i^0 + \beta _2H_i + \beta _3Site_i + {{\epsilon}\hskip 1pt}_i$$

(1b)$$H_i = \displaystyle{1 \over {n_i-1}}\mathop \sum \limits_j O_j^0, \; \; \; j\in \lcub {J_i\;:\;{\rm j}\;{\rm is}\;{\rm seated}\;{\rm at}\;i^{\prime} {\rm s}\;{\rm table},j\ne i} \rcub $$

where the i ^th respondent's post-treatment preference on a given topic $(O_i^1 )$ is modeled as a function of her own pre-treatment preference $(O_i^0 )$, the average (H _i) of the pre-treatment preferences of her (n _i − 1) discussion partners (indexed by j ∈ J _i), and separate intercepts for each location (Site _i) at which the discussions were held. Farrar et al. (Reference Farrar2009) model preference change as the difference in pre-post survey responses by subtracting $\beta _1O_i^0 $ from both sides of Equation 1.Footnote ²

In the Farrar et al. (Reference Farrar2009) study, as in our own application, the respondent is randomly assigned to discussion groups so the average of the pre-treatment preferences of her discussion partners (H _i) is also random, and under the normal assumptions for identifying a causal effect in a randomized control trial that we describe in more detail below, β ₂ identifies the causal effect on the respondent's change in response to the survey item from the pre-test to the post-test, $(O_i^1 -\beta _1O_i^0 )$, that comes from exposure to a discussion group with a given composition of participants (see also Gastil et al. Reference Gastil, Black and Moscovitz2008; Klar Reference Klar2014).Footnote ³

The difference in pre- and post-survey responses, however, does not map onto persuasion as a construct because the pre-test and post-test responses each contain a stochastic component related to measurement error (Achen Reference Achen1975; Ansolabehere, Rodden and Snyder Reference Ansolabehere, Rodden and Snyder2008; Prior Reference Prior2010), in addition to a systematic component that captures respondents' preferences at a given time. Only a change in the systematic component that results from some intervention, such as interpersonal interactions within a discussion, should count as a valid measure of persuasion; random noise should not.Footnote ⁴

To formalize the systematic component for preference change, for simplicity we assume a continuous, normally distributed opinion response at time t, $O_i^t $, and decompose the opinion response as:

(2)$$O_i^t = \beta _0 + \theta _i^t + \zeta _i^t + {{\epsilon}\hskip 1pt} _i^t, \; \; \; t\in \lcub {0,1} \rcub $$

where $\theta _i^t $ is the respondent's latent, left–right ‘ideal point’ that structures preferences across a range of issues (Hinich and Munger Reference Hinich and Munger1994),Footnote ⁵ $\zeta _i^t $ is a topic-specific preference that remains after netting out latent preferences, and ${{\epsilon}\hskip 1pt} _i^t $ is the idiosyncratic component from measurement error that represents instability in the individual's opinion response (Lauderdale, Hanretty and Vivyan Reference Lauderdale, Hanretty and Vivyan2018), all evaluated at time t; t = 0 is the pre-test and t = 1 is the post-test value.Footnote ⁶ If $\theta _i^t $ and $\zeta _i^t $ are invariant or fixed over time, then opinion change is driven only by the idiosyncratic component and is essentially noise.

The statistical task is to separate out systematic preference change in $\theta _i^t $ and $\zeta _i^t $ from random noise using a measurement strategy, and then to model the two systematic components directly. To derive a model of preference change over time from first principles, we can take the difference in Equation 2 between time t = 1 and t = 0:

(3a)$$O_i^1 = \beta _0^1 + \theta _i^1 + \zeta _i^1 + {{\epsilon}\hskip 1pt} _i^1 $$

(3b)$$\beta _1(O_i^0 = \beta _0^0 + \theta _i^0 + \zeta _i^0 + {{\epsilon}\hskip 1pt} _i^0 ).$$

Subtracting Equation 3a from Equation 3b and rearranging yields:

(4)$$O_i^1 = \beta _0 + \beta _1O_i^0 + {\rm \Delta} \theta _i + {\rm \Delta} \zeta _i + {{\epsilon}\hskip 1pt} _i$$

where $\beta _0 = \beta _0^1 -\beta _1\beta _0^0 $ and ${{\epsilon}\hskip 1pt} _i = {{\epsilon}\hskip 1pt} _i^1 -\beta _1{{\epsilon}\hskip 1pt} _i^0 $. With this derivation we have identified two new quantities, ${\rm \Delta} \theta _i = \theta _i^1 -\beta _1\theta _i^0 $ which is the change in the respondent's pre- to post-discussion preferences in the latent preference space, and ${\rm \Delta} \zeta _i = \zeta _i^1 -\beta _1\zeta _i^0 $ which is the change in the respondent's topic-specific preference for the outcome represented by O _i after accounting for changes in latent preferences. This derivation allows us to focus on these more substantively interesting preference changes, rather than only on the noisily measured changes in the survey response itself. We define measured persuasion as the change in each of these systematic components of the respondent's expressed preference.

Consider the two systematic components of preference change in turn. First, one can consider latent preferences to be a heuristic, such as left–right ideology, that enables individuals to make sense of and engage in policy debates involving complex matters even with limited information (Eatwell Reference Eatwell, Eatwell and Wright1993; Hinich and Munger Reference Hinich and Munger1994). In this interpretation, Δθ _i captures changes in the latent structuring of their preferences that organizes their views across a range of policies. In the American context, ideology largely reduces to a single, latent dimension (Poole and Rosenthal Reference Poole and Rosenthal1997). For example, in the context of our application on US fiscal policy that we describe below, as an empirical matter all preferences load exclusively on a single latent dimension captured by θ.

Secondly, the structure of preferences within specific policy topics can be complex (Feldman and Johnson Reference Feldman and Johnson2014; Treier and Hillygus Reference Treier and Hillygus2009), and particularly at the elite level or within deliberative communication (Gutmann and Thompson Reference Gutmann and Thompson1996, 56; Habermas Reference Habermas1984, 99), reasoning about policy topics is not strictly constrained by ideology or to any other single latent dimension (see Tausanovitch and Warshaw Reference Tausanovitch and Warshaw2017). Such an assumption would be overly restrictive and indeed a gross oversimplification of human cognition. For example, in the town hall event we study, participants were provided policy reading material and expert testimony to inform discussions, and so had the capacity to give reasons and exchange rationales that go beyond a heuristic defined by ideology. In this view, the Δζ _i measure of topic-specific persuasion captures the amount of persuasion that occurs ‘outside’ of the latent scale.

Thus, within a small-group event, persuasive processes can operate at these two different levels. Note that this partitioning between Δθ _i and Δζ _i does not create a hierarchy among latent and topic-specific reasoning. In the statistical model, the relative amount of each can vary freely across individuals.

As is common practice (for example, Farrar et al. Reference Farrar2009), we allow the scale of the response space to vary over time by multiplying both sides of Equation 3b by β ₁. For example, β ₁ <0 implies a plenary shift in preferences toward moderation and β ₁ >0 implies a plenary shift toward extremity. Note that in the case of both Δθ _i and Δζ _i, the change in systematic preferences is based on the underlying preference space rescaled by β ₁. One can fix the scales across the two time periods by setting β ₁ = 1, which is equivalent to modeling the difference ($O_i^1 -O_i^0 $) as an outcome (such as in Westwood Reference Westwood2015).

In general, including an outcome response variable measured pre-treatment, such as $O_i^0 $, on the right-hand side will lead to endogeneity bias since many of the individual-level determinants of an outcome in the pre-treatment period also determine the outcome in the post-treatment period. To see why in the case of modeling preference change, define $\omega _i^t = \theta _i^t + \zeta _i^t $, and note that $cov(\omega _i^0, \omega _i^1 )\ne 0$, since $\theta _i^1 = \theta _i^0 + {\rm \Delta} \theta _i$ and so $\theta _i^0 $ is contained in both $\omega _i^0 $ and $\omega _i^1 $. In the statistical model below we correct for this potential bias by including $\theta _i^0 $ in the outcome equations. In essence, we guard against endogeneity bias under the assumption that the latent preference scale is a strong predictor of both pre- and post-discussion preferences, and that the remaining variation in preferences $O_i^0 $ and $O_i^1 $ is random once a respondent's ideal point is accounted for.Footnote ⁷ Thus we estimate the following equation:

(5)$$O_i^1 = \beta _0 + \beta _1O_i^0 + \beta _2\theta _i^0 + {\rm \Delta} \theta _i + {\rm \Delta} \zeta _i + {{\epsilon}\hskip 1pt} _i$$

This model differs from the standard practice for modeling persuasion (for example, Farrar et al. Reference Farrar2009) in three important ways. First, our model includes pre-test preferences $O_i^0 $ in a way that does not induce endogenous variable bias.

Secondly, our model focuses on the change in the respondent's latent and topic-specific preferences, represented by Δθ _i and Δζ _i, rather than the raw opinion change $(O_i^1 -O_i^0 )$ that is at best a noisy measure of persuasion. That is, in the model below, the components of measured persuasion Δθ _i and Δζ _i serve as the outcomes of interest, which we model directly.Footnote ⁸ These two components are similar to factor scores in that they both measure quantities that are unobserved directly in the data.

Thirdly, modeling the $\theta _i^0 $, Δθ _i and Δζ _i parameters jointly with the structural parameters β correctly propagates the uncertainty that comes from estimating these parameters using the statistical model. That is, the estimates of the β parameters are the marginal distributions having integrated over the sample space underlying $\theta _i^0 $, Δθ _i and Δζ _i, a technique known as the ‘method of composition’ (Treier and Jackman Reference Treier and Jackman2013). As Treier and Jackman (Reference Treier and Jackman2013) note, the method of composition accounts for the estimation uncertainty in each of the random-effect parameters. This is in contrast to using estimated factors scores as right-hand-side variables, as if the factor scores correctly recovered each random-effect parameter, which causes errors in variables bias in a regression.Footnote ⁹

A research design that would enable this statistical strategy to measure the systematic component of preference change has two main requirements. First, the respondent must express preferences on three or more topics in both the pre- and post-discussion surveys in order to identify the underlying latent preference space in Δθ _i. If multiple outcomes do not exist, then only Δζ _i is identified. Secondly, the standard assumptions in evaluating randomized control trials must be met (Angrist, Imbens and Rubin Reference Angrist, Imbens and Rubin1996; Gerber and Green Reference Gerber and Green2012) in order to identify the effect of group composition rather than confounds to each group's discussion. We discuss these assumptions below.

THE OBOE TOWN HALLS

We apply our measurement strategy in a test of small-group persuasion using a dataset from a randomized, large-scale deliberative field experiment. On 26 June 2010, nearly 3,000 individuals in nineteen cities convened in town hall meetings to discuss America's long-term fiscal future.Footnote ¹⁰ The event, entitled ‘Our Budget, Our Economy’ (OBOE), brought together diverse citizen-deliberators, armed with background reading material, to discuss and prioritize policy options that would help put the nation's budget on a more sustainable long-term fiscal path. To recruit participants, the event organizer, AmericaSpeaks, worked with hundreds of local groups in each of the nineteen cities, from all walks of life, to create a group of participants that closely mirrors the demographic composition of each community (see Appendix Section A.1 for a description of the event, recruitment and the respondents' characteristics).Footnote ¹¹ In addition, AmericaSpeaks worked with over thirty national organizations that research and advocate budget policies, both liberal and conservative, to develop technical background reading material that was factual, balanced and that represented the views of diverse perspectives.

On the day of the event, participants were randomly assigned to small-group discussion tables; the randomization occurred within each site.Footnote ¹² They spent the entire day reading the materials, watching some instructional videos and discussing their policy views with others seated at their table. Given the diversity of the participants in the town halls, randomization served two purposes. First, randomizing participants to small-group discussions helped to assure that many participants were exposed to the views of co-discussants who were very different from themselves. In the absence of pre-determined seating assignments, participants are likely to seek out co-discussants who are like themselves (Fowler et al. Reference Fowler2011), or to sit with other participants with whom they arrived at the event, which in turn would minimize the diversity of viewpoints available at each table. Randomization washes out any existing social ties among participants and diversifies the views to which participants are exposed. Since the groups were small in number, typically ten participants, sampling variability under randomization assured that the composition of preferences would vary across tables, ranging from homogeneous to heterogeneous groups.

Secondly, random assignment allows us to identify the causal effects of exposure to different group compositions (Farrar et al. Reference Farrar2009) and therefore enables us to identify our measure of persuasion as a function of pre-discussion viewpoints. In the present case, the mix of pre-discussion viewpoints among participants at a given table is exogenous to the analysis. One might believe a better measure of persuasion would rely on the arguments actually made in the course of the discussion, say from a transcript of the session (for example, Karpowitz and Mendelberg Reference Karpowitz and Mendelberg2007; Westwood Reference Westwood2015). This measurement strategy, however, cannot test for causal effects as the arguments offered during a discussion occur post-treatment; that is, since arguments are not randomly assigned, a statistical test based on arguments will lack internal validity.Footnote ¹³ Instead, we rely on the composition of pre-test ideal points of the other participants at the respondent's table as an instrument of exposure to viewpoints during the discussion, since we can take the pre-test ideal points of the discussion partners as an exogenous and randomly assigned encouragement to create the mix of arguments made in the discussion under an encouragement design (as in Farrar et al. Reference Farrar2009). To connect the group compositions to persuasion from discussion, our strategy must assume that there is a larger mix of conservative arguments made at a discussion where most of the participants have conservative pre-discussion ideal points compared to tables where most of the participants have liberal ideal points, and vice versa.

The group context in which deliberation occurs can affect the nature of discussion. In the OBOE deliberation, the discussion groups were typically not homogeneous; the discussion focused extensively on a single topic; the participants had access to balanced, factual reading material; and AmericaSpeaks assigned a moderator to each table. The moderator did not participate substantively in the discussion and was trained by the event organizers in techniques to ensure that everyone at the table had the chance to speak, to encourage everyone to participate, and to enforce a set of rules (written on cards located at the center of each table) that were designed to make each table a ‘neutral, safe space’ for expressing diverse views. We expect this careful design to induce deliberative exchanges within the small groups (Barabas Reference Barabas2004; Gastil et al. Reference Gastil, Black and Moscovitz2008; Gerber et al. Reference Gerber2016; Grönlund, Herne and Setälä Reference Grönlund, Herne and Setälä2015; Luskin, Fishkin and Hahn Reference Luskin, Fishkin and Hahn2007), and so our findings might well depart from those of non-deliberative small-group studies (see Isenberg Reference Isenberg1986).

DATA AND MODEL

The statistical model tests for the presence of persuasion within the small groups regarding various policy proposals considered at the event. At each of the nineteen town halls, we asked participants to complete a short survey as they arrived, before the event began, and to complete another survey at the conclusion of the event. We refer to the former as the pre-test survey, and the latter as the post-test survey. A total of 2,793 participants, seated at 339 tables across nineteen sites, filled out one or the other or (for the vast majority) both of these surveys.Footnote ¹⁴

The pre- and post-test surveys each contained a block of items asking participants their policy preferences on a set of proposals. The block of six questions is preceded with ‘Here are several things the government could do to cut the budget deficit. Please tell us what you think about each approach to reducing the deficit.’ The response categories each have a five-point scale: ‘Strongly disagree’, ‘Disagree’, ‘Neither’, ‘Agree’ or ‘Strongly agree.’ The items are (labels for items shown below in bold font were not in the survey):

• Q1: Tax Rich Raise income taxes on the very wealthy – individuals making $250,000 or more and households making $500,000 or more.

• Q2: Cut Programs Cut discretionary federal programs and services by 5 per cent across the board.

• Q3: Cut Entitlements Cut the growth of spending on entitlement programs such as social security and Medicare benefits.

• Q4: Cut Defense Cut the spending on national defense and the military.

• Q5: Tax Both Raise taxes on the middle class as well as the wealthy.

• Q6: Federal Sales Tax Create a new federal consumption tax, which would be like a federal sales tax that would be on top of any state and local sales tax.

In the American context, the first four items have a clear left–right orientation: to solve the deficit, liberals prefer to tax the rich and cut defense; conservatives prefer to cut discretionary programs and entitlements. The remaining two items that advocate taxing the middle class and a federal sales tax cut across liberal–conservative ideology. The statistical model uses the pre- and post-test values of these items; an indicator of whether the pre-test is missing (9 per cent of pre-tests are missing),Footnote ¹⁵ a variable indicating a unique table identification number (among 339 tables total), and dummy variables indicating the site (out of the nineteen sites, omitting one site) for each participant. The Appendix Section A.2 provides summary statistics for all of the variables.

Statistical Model

Our statistical model estimates the effect of small-group composition on persuasion, exploiting the random assignment to groups and a measurement model. The full statistical model is given in Appendix Section A.7. In this section we ‘walk through’ the elements of the likelihood function in order to show how we measure persuasion, and how the parameters and functional form specifications allow us to test a variety of substantive hypotheses regarding persuasion that are found in the literature on small-group dynamics. The likelihood equation for a single categorical outcome is summarized in Equation 6a, which is a non-linear implementation of Equation 5.

(6a)$$O_{ik}^1 \sim {\rm Ordered}\,{\rm Logit(}\beta _{1{\rm k}}{\rm O}_{{\rm ik}}^0 + \beta _{2k}\theta _i^0 + \beta _{3{\rm k}}{\rm Sit}{\rm e}_i + \omega _{ik}{\rm )},$$

(6b)$$\omega _{ik} = {\rm \Delta} \theta _i + {\rm \Delta} \zeta _{ik}.$$

We estimate this model simultaneously for each of six policy preference items. In this equation, i indexes N participants (each i is a potential ‘persuadee’) and k indexes K = 6 policies, which are labeled Q1 to Q6 above. The post-test policy preferences for each item and for each individual, $O_{ik}^1 $, are modeled as a function of her pre-test policy preference ${\rm O}_{ik}^0 $, her pre-test left–right ideal point $\theta _i^0 $, an indicator of the Site_i (city) of her event, and a random effect ω _ik that varies across individuals and policies. We describe each of these four elements in turn, noting for now that our main interest will focus on ω _ik.

The first component ($O_{ik}^0 $) is the respondent's pre-treatment response on the respective policy preference survey item. Including the pre-treatment opinion on the right-hand side ensures that the structural parameters in the model estimate the individual's change in preference that occurs between the pre- and post-test surveys (Farrar et al. Reference Farrar2009). As we describe above, including the pre-treatment outcome on the right-hand side and estimating the β _1k parameter allows the scale of the post-treatment outcome to vary. Since $O_{ik}^0 $ is categorical, we include a set of dummy variables indicating each of the first four response categories for the pre-test item (omitting the fifth category), and hence ${\rm O}_{{\rm ik}}^0 $ is a matrix and β _1k is a vector. Using these dummy variables enables us to relax an assumption that each response category predicts the post-test response equally and in the same direction, and also allows the degree of scale compression and expansion to vary across the response options.

For the second component, we include $\theta _i^0 $ in the likelihood function to capture the endogenous dependence between the pre- and post-test responses on the outcome, which corrects for any endogenous variable bias that comes from including the pre-test item in the outcome equation (see Skrondal and Rabe-Hesketh, Reference Skrondal and Rabe-Hesketh2004, 107–8). We use pre-test responses to the tax rich, cut programs, cut entitlements and cut defense (Q1 to Q4) items to estimate each participant's pre-treatment latent ideal point preference scale, since these items have a clear liberal–conservative orientation.Footnote ¹⁶ We estimate each participant's latent ideal point $\theta _i^0 $ dynamically within the model, as in a structural equation model, and hence the estimation uncertainty inherent in $\theta _i^0 $ is included in the likelihood.

For the third component we condition on the Site or city in which the participants' event took place. Since randomization took place within sites these fixed effects allow us to control for any site-specific influences.

The fourth component of the likelihood function is a random effect, ω _ik, that varies across individuals and policies.Footnote ¹⁷ ω _ik measures the amount of dependence among the participants’ preference changes in communication with each other (Anselin Reference Anselin1988), for both the latent preferences (Δθ _i) and the topic-specific preferences (Δζ _i) and hence represents the amount of a respondent's systematic preference change that is due to exposure to the discussion. In our application, since participants are randomly assigned to tables, we can state that any relationship between group composition and respondents' preferences we observe is caused by interpersonal interactions, rather than due to confounding, omitted variables or homophily.Footnote ¹⁸

Because we estimate this model for multiple items simultaneously, and since the policy items contain an underlying latent structure, we are able to decompose ω _ik into two components, shown in Equation 6b as a random effect that varies across individuals, Δθ _i, and a second random effect that varies across both individuals and policies Δζ _ik. Δθ _i is a random-effect parameter nested jointly within the full set of policy items and hence captures a systematic shift in preferences along the underlying latent, liberal–conservative dimension that structures preferences across topics. Δζ _ik is specific to each policy item and captures dependence in the preference changes among participants seated at a table for that item, net of the latent component.

Since we define persuasion as the component of pre-post preference change that is due to interpersonal interactions, our interests lie in modeling variation across individuals and policies in ω _ik and hence variation in Δθ _i and Δζ _ik. We model these two dimensions separately. We define Δθ _i in Equation 7a as a normally distributed random effect with conditional mean ${\rm \Delta} \theta _i^* $ and variance equal to one.Footnote ¹⁹

(7a)$${\rm \Delta} \theta _i\sim \phi ({\rm \Delta} \theta _i^{^\ast}, 1),$$

(7b)$$\eqalign{ {\rm \Delta} \theta _i^{^\ast} & = \alpha _1H_i + \lpar {\delta_1\cdot {\rm Libera}{\rm l}_i + \delta_2 + \delta_3\cdot {\rm Conservativ}{\rm e}_i} \rpar \cdot H_i^2 \cr &\quad + \lpar {\gamma_1\cdot {\rm Libera}{\rm l}_i + \gamma_2 + \gamma_3\cdot {\rm Conservativ}{\rm e}_i} \rpar \cdot S_i \cr& \quad + \kappa _1\cdot {\rm Libera}{\rm l}_i + \kappa _2\cdot {\rm Conservativ}{\rm e}_i.} $$

We model the conditional mean for Δθ _i in Equation 7b as a function of the latent ideal points of others seated at the respondent's discussion table (H and S, defined next) as well as the respondent's own ideology (liberal, moderate or conservative). Equation 7b contains four distinct variables. To create the Liberal_i and Conservative_i variables, we retrieve the pre-treatment ideal point for each participant and trichotomize this scale into three equally sized groups. H _i is defined in Equation 8a as the estimated mean of the pre-discussion ideal points of the discussants seated at i's table, excluding i's own ideal point. S _i is the variance of the ideal points of the other discussants at i's table, again not including i's own ideal point. These functions of ideal point estimates, H _i and S _i, are estimated dynamically within the structural equation model.

(8a)$$H_i = {\rm mean}\,{\rm (}\theta _{ij}^0 {\rm )},$$

(8b)$$S_i = {\rm mean([}\theta _{ij}^0 {\rm ]}^2{\rm )}-{\rm mean}(\theta _{ij}^0 )^2,$$

(8c)$$\theta _{ij}^0 \in \lcub {\theta_j^0 \;:\;j\;{\rm is}\;{\rm seated}\;{\rm at}\;i^{\prime} {\rm s}\;{\rm table},j\ne i} \rcub .$$

In Equation 8c, j indexes i's discussion partners, and the two mean functions are:

(9a)$${\rm mean(}\theta _{ij}^0 {\rm )} = \mathop \sum \limits_j (\theta _{ij}^0 )/(N_i^- ),$$

(9b)$${\rm mean}\,{\rm ([}\theta _{ij}^0 {\rm ]}^2{\rm )} = \mathop \sum \limits_j ([\theta _{ij}^0 ]^2)/(N_i^- ).$$

$$N_{i}^{-}\, {\rm is\, the\, number\, of\, participants\, sitting\, at}\, i\, {\rm s\, table,\, not\, including}\, i$$

The parameterization and functional form of Equation 7b are designed to test substantive hypotheses from the literature on small-group dynamics. We have labeled each set of parameters with a different Greek letter (α, δ or γ) to indicate the hypothesis for each set of parameters tests. The parameter α ₁ estimates the degree to which person i's preferences depend on the ideal point composition of others seated at her table, which is the instrument for discussion using the pre-treatment ideological orientation of the participants seated at the respondent's table (Farrar et al. Reference Farrar2009; Gastil et al. Reference Gastil, Black and Moscovitz2008; Klar Reference Klar2014). As Farrar et al. (Reference Farrar2009) notes, since respondents’ ideological ideal points are measured pre-treatment, we can take these as exogenous, and since group compositions are randomly assigned, we can take effects of this exposure to this measure of group composition to be causal.

The signs for the parameters δ ₁ and δ ₃ test whether polarization (Furnham, Simmons and McClelland Reference Furnham, Simmons and McClelland2000; Isenberg Reference Isenberg1986; Schkade, Sunstein and Hastie Reference Schkade, Sunstein and Hastie2010; Sunstein Reference Sunstein2002; Sunstein Reference Sunstein2008) is evident in the respondents' latent-space persuasion, separately for liberals and conservatives; we include δ ₂ (corresponding to moderates) for completeness and we do not have expectations for its sign. To state expectations for the signs of δ ₁ and δ ₃, note that we code the policy-preference items so that high values indicate a conservative response and low values indicate liberal, so higher scores on the latent ideal point scale indicate a conservative leaning. If liberals become more liberal, as the table becomes more liberal, then under a law of group polarization δ ₁ should be negative as this would indicate that as a liberal respondent's table becomes more liberal, her latent preferences will become polarized and even more liberal (see the hypothetical curve in the left panel of Figure 1). The patterns should be symmetric for conservatives and so under polarization δ ₃ should be positive. If polarization is not evident, then these parameters will not differ from zero. We note that the empirical deliberation literature proposes that structured deliberation inoculates groups from polarization (Barabas Reference Barabas2004; Gerber et al. Reference Gerber2016; Grönlund, Herne and Setälä Reference Grönlund, Herne and Setälä2015; Klar Reference Klar2014; Luskin, Fishkin and Hahn Reference Luskin, Fishkin and Hahn2007), and hence do not expect small-group polarization to emerge in this context.

Figure 1. Latent persuasion: no evidence of polarization

Note: If the ‘law’ of small-group polarization held true, then we would expect to see liberals becoming even more liberal as the table grew more liberal (a concave pattern) and vice versa for conservatives (a convex pattern). Instead we observe a linear relationship or diminishing returns, which is consistent with a mechanism of persuasive arguments within cross-cutting discourse. The confidence bands indicate 95 per cent highest posterior density intervals.

The parameters γ ₁, γ ₂ and γ ₃ test whether the dispersion of ideal points at a table – a pre-treatment measure of the extent of disagreement among the discussion participants – affects preference change separately for liberals, moderates and conservatives. While we do not have strong priors regarding the direction of this dynamic, it is possible that as the group becomes more divided (as the standard deviation of ideal points increases) participants will tend to selectively attend to the arguments that match their predispositions (see, for example, Bolsen, Druckman and Cook Reference Bolsen, Druckman and Cook2014; Edwards and Smith Reference Edwards and Smith1996; McGarty et al. Reference McGarty1994; Nyhan and Reier Reference Nyhan and Reifler2010; Tabor and Lodge Reference Tabor and Lodge2006) and hence increase the within-group polarization. In this case, γ ₁ should be negative, γ ₃, should be positive, and we have no prior expectations for γ ₂.

The second, policy-specific component of persuasion, Δζ _ik, is defined in Equation 10a as a normally distributed random effect with mean ${\rm \Delta} \zeta _{ik}^* $ and variance one. ${\rm \Delta} \zeta _{ik}^* $ is a function of the respondent's own ideology and the policy-specific random effects Δζ _jk of the other participants who are seated at i's table. Nesting this random effect within the participants of a given table enables us to assess the extent of dependence in the preference changes on the specific policy topic among table co-discussants, after netting out the covariates in the model as well as Δθ _i. Methodologically, this random effect accommodates remaining spatial dependence within clusters (Congdon Reference Congdon2003, chapter 7).

(10a)$${\rm \Delta} \zeta _{ik}\sim \phi ({\rm \Delta} \zeta _{ik}^{^\ast}, 1),$$

(10b)$${\rm \Delta} \zeta _{ik}^{^\ast} = \lpar {\rho_{1k}\cdot {\rm Libera}{\rm l}_i + \rho_{2k} + \rho_{3k}\cdot {\rm Conservativ}{\rm e}_i} \rpar \cdot {\rm mean}\,{\rm (\Delta} \zeta _{ijk}{\rm )}.$$

(10c)$${\rm \Delta} \zeta _{ijk}\in \lcub {{\rm \Delta} \zeta_{\,jk}\;:\;j\;{\rm is}\;{\rm seated}\;{\rm at}\;i^{\prime} {\rm s}\;{\rm table},j\ne i} \rcub ,$$

where

(11)$${\rm mean}\,{\rm (\Delta} \zeta _{ijk}{\rm )} = \mathop \sum \limits_j ({\rm \Delta} \zeta _{ijk})/(N_i^- ).$$

The parameters ρ _1k, ρ _2k and ρ _3k estimate the degree of dependence on each policy preference item among table participants for liberals, moderates and conservatives (respectively) after netting out each respondent's pre-treatment preference, her own ideal point, both before and after the discussion. If a ρ _2k is positive and significant, this indicates that if everyone else at the table has a shift in their expected post-test preference on policy k, then person i also can be expected to have a shift in the same direction on issue k; conversely, if everyone else's preferences stay put, so does person i's. (Negative rhos are very unusual in this type of model.) If this dependence is net of ideology, then ρ ₁ and ρ ₃ should test to zero.

We assert that the two components of ω _ik (Δθ _i and Δζ _ik) capture spatial dependence that comes from the respondents' exposure to her co-discussants. In particular, Δθ _i measures the extent to which the respondent's preferences change along a latent ideological dimension that results from exposure to discussion groups of varying preference compositions; Δζ _ik measures the extent to which a respondent's post-discussion preferences are dependent on her co-discussant's post-discussion preferences on that specific topic for any other reasons. In both of these ways, the model measures dependence that comes from interpersonal interactions.

These twelve structural parameters, α ₁, δ, γ, κ, and ρ capture the effects of exposure to small-group discussion partners on persuasion within the small group, with each set of parameters evaluating the specific mechanisms for persuasion for both latent persuasion, measured by Δθ _i, and for topic-specific persuasion for each policy, measured by Δζ _ik.