Arousal

Skin conductance captures activity of the sympathetic nervous system (Dawson, Schell, and Filion Reference Dawson, Schell, Filion, Cacioppo, Tassinary and Berntson2007). It measures the varying electrical properties of the skin in response to the increase of sweat secretion in the eccrine glands. With more sweat secretion, the conductance of electricity improves and skin conductance levels rise. This is interpreted as an increase in arousal. Increases in skin conductance have been reported in response to negative images (Lang et al. Reference Lang, Greenwald, Bradley and Hamm1993), negative news (Soroka, Fournier, and Nir Reference Soroka, Fournier and Nir2019; Soroka and McAdams Reference Soroka and Mcadams2015), and negative political ads (Daignault, Soroka, and Giasson Reference Daignault, Soroka and Giasson2013; Wang, Morey, and Srivastava Reference Wang, Morey and Srivastava2014), but such increases are also observed in response to positive stimuli such as a exposure to a preferred football team (Potter and Keene Reference Potter and Keene2012), political party (Petersen, Giessing, and Nielsen Reference Petersen, Giessing and Nielsen2015), or politician (Wagner et al. Reference Wagner, Deppe, Jacobs, Friesen, Smith and Hibbing2014).

Valence

The valence of affect can be measured by recording electromyographic (EMG) signals of specific muscles in the face (Tassinary, Cacioppo, and Vanman Reference Tassinary, Cacioppo, Vanman, Cacioppo, Tassinary and Berntson2007). To disentangle the experience of negative and positive affect, the activity of the corrugator and zygomaticus muscle groups, respectively, are recorded (Tassinary, Cacioppo, and Vanman Reference Tassinary, Cacioppo, Vanman, Cacioppo, Tassinary and Berntson2007). The corrugator ciculii is a muscle above the eyebrow that draws the brow down and pulls the brows together. Corrugator activity has been recorded in response to negative images (Lang et al. Reference Lang, Greenwald, Bradley and Hamm1993), negative words (Wexler et al. Reference Wexler, Warrenburg, Schwartz and Janer1992), and negative affective cues in language (Hietanen, Surakka, and Linnankoski Reference Hietanen, Surakka and Linnankoski1998). The zygomaticus major pulls the corners of the mouth up and back into a smile (Larsen, Norris, and Cacioppo Reference Larsen, Norris and Cacioppo2003). Zygomaticus activity increases in response to positively valenced images (Van Oyen Witvliet, and Vrana Reference Van Oyen Witvliet and Vrana1995) and videos (Cacioppo et al. Reference Cacioppo, Petty, Losch and Kim1986).

Attention

A fourth physiological measure that is sometimes used is heart rate variability. In some cases it is used to measure arousal, and in other cases it is used to measure (cognitive) attention (Lang, Newhagen, and Reeves Reference Lang, Newhagen and Reeves1996; Soroka, Fournier, and Nir Reference Soroka, Fournier and Nir2019; Soroka and McAdams Reference Soroka and Mcadams2015). However, any acceleration in heart rate that comes from arousal will be overwhelmed by the deceleration that comes with attention (Potter and Bolls Reference Potter and Bolls2012). We follow Soroka and colleagues (Soroka, Fournier, and Nir Reference Soroka, Fournier and Nir2019; Soroka and McAdams Reference Soroka and Mcadams2015) and employ heart rate variability as a measure of attention.

Sample

Our study was conducted at multiple locations in the Netherlands between August 2016 and June 2017. We used two different protocols. Table 1 describes the locations, specifies the protocols used, and notes the number of participants collected at each location. In all we have collected data for 397 Dutch adults. No statistical methods were used to predetermine sample size, but our sample size is more than three times larger than the median sample size reported in previous publications (e.g., Arceneaux, Dunaway, and Soroka Reference Arceneaux, Dunaway and Soroka2018; Mutz Reference Mutz2007; Mutz and Reeves Reference Mutz and Reeves2005; Renshon, Lee, and Tingley Reference Renshon, Lee and Tingley2015; Soroka, Fournier, and Nir Reference Soroka, Fournier and Nir2019; Soroka and McAdams Reference Soroka and Mcadams2015)—see Appendix A.1 for more details. Our study thus has an unusually large sample size for a study of its kind.

Table 1. Description of the Locations

To obtain sufficient variation on the theoretically relevant independent variables (e.g., political knowledge and political attitudes), we set up our lab at different lab-in-the-field locations. In Appendix A.4, we demonstrate that we have succeeded in obtaining sufficient variance on our key independent variables.

Design of the Study

Upon signing the informed consent form, participants completed a survey on a desktop computer (laboratory) or iPad 2 (lab-in-the-field). We asked about their political attitudes and socioeconomic background (see Appendix A.2 for details on rewards and procedures during the survey as well as item wording of the survey). Next, participants were connected to physiological measurement equipment by trained research assistants. Participants were also given noise-canceling headphones (Bose). The experiment started with a baseline measure of 30 seconds (Soroka and McAdams Reference Soroka and Mcadams2015). Afterwards, participants were randomly assigned to a treatment in the form of a video clip (between 50 and 60 seconds) about a specific political issue—namely, immigration (protocol 1 and 2)Footnote ¹, climate change (protocol 1), redistribution (protocol 1), and the European Union (protocol 2)—see Table 1 for an overview.Footnote ² We chose these issues because they differ in their salience, with immigration the most salient issue at the time of the study and climate, redistribution, and Europe considerably less salient (den Ridder et al. Reference Den Ridder, Dekker, Van Houwelingen and Schrijver2016).

The video clips were created by a professional editor, using a selection of clips from news broadcasts that illustrated these issues, without showing politicians, political parties, or other prominent persons. Per issue, we constructed two treatments: a “left-wing” message (liberal) and a “right-wing” message (conservative). To do this, a professional speech actor recorded a voice-over loosely based on real speeches from left-wing or right-wing parliamentarians. By using real speeches, we can guarantee a degree of external validity, without mentioning the source to the participant, which could bias our treatment effects. Table 2 provides snippets of all messages (see Appendix A.6 for transcripts, links to the videos, and other details of the treatments). In a pretest (N = 23), we confirmed the ideological slant of the messages (Appendix A.6).

Table 2. Treatments: Snippets of the Message

Note: Complete text of treatments and links to videos can be found in Appendix A.6.

We employ block-randomization whereby the order of the four issues was randomized and for each issue participants were randomly exposed to left-wing or right-wing rhetoric. This means that participants saw a total of four clips. The interstimulus intervals between the different messages were roughly 30–60 seconds, during which participants answered a set of filler questions. Note that we refrain from treating these periods as interstimulus intervals in the analyses because participants also answered questions during this period. As a consequence, their hands moved a lot, causing all sorts of unknown distortions in the measure of the physiological responses.

Survey Measures

In the survey before the treatment, we measured attitudes towards four issues: (1) immigration (three items, e.g., “The Dutch culture is threatened by refugees” [reverse coded]), (2) redistribution (two items, e.g., “Income inequality is too big in the Netherlands. People with the lowest incomes should get the biggest salary increase”), (3) the EU (three items, e.g., “I am in favor of more decision-making at the European level”), and (4) climate (three items, e.g., “There are more important things in life than protecting the environment” [reverse coded]). All variables were measured on a 9-point scale ranging from “totally disagree” (1) to “totally agree” (9)—see Appendix A.7 for item wording. Descriptive statistics for these and all other measures in this study are provided in Appendix A.3. After each treatment, respondents were asked again to fill out these questions. For our final analysis of the consequences of affective responses, we use the absolute difference between the pretreatment and posttreatment measure as the dependent variable. Attitude extremity on an issue was measured by taking the absolute distance between the participant’s placement on the scale from the scale’s middle point. We measured political knowledge using three multiple choice items, such as “How long is one term for a member of the Lower House” (correct answer = 4 years; see Appendix A.7 for other items and psychometric properties). We created an index by summing the correct answers.

For all four issues, we created an index of incongruence by contrasting the pretreatment attitudes with the video clip participants received. Consider immigration attitudes. A score from >0 to +4 means that the video clip participants received was incongruent with their immigration attitudes (left-wing attitude with right-wing clip or right-wing attitude with left-wing clip). The higher the score, the more incongruent the clip was with the attitude. Scores <0 to -4 indicate congruence between the video clip and the attitude (left-wing attitude and left-wing clip, etc.). Again, we assume that the message is more congruent for participants with more extreme attitudes. A score of “0” indicates that participants have a neutral immigration attitude, and so neither the left-wing nor the right-wing video clip is incongruent with their attitude.

Physiological Measures

We recorded physiological data using the Versatile Stimulus Response Registration Program 1998 (Vsrrp98) software on laptops (lab-in-the-field data collection) or stationary computers running Windows 7 (laboratory data collection). We assess arousal using skin conductance levels (SCL). These are measured by passing a small current through two electrodes placed on the skin (see panel A of Figure 1). By keeping the current constant, it is possible to measure the flow of the current—what we call skin conductance expressed in micro-Siemens (Dawson, Schell, and Filion Reference Dawson, Schell, Filion, Cacioppo, Tassinary and Berntson2007). For a description of the measure, see Appendix A.8.

Figure 1. Physiological Measures: SCL and EMG

We constructed our measure of change in skin conductance response $$ (\Delta \mathrm{SC}{L}_i) $$ by taking the difference between the logged mean SCL recorded while participants were exposed to treatment T and the logged mean SCL recorded during the baseline. To minimize the effects of extreme values, we follow Oxley et al. (Reference Oxley, Smith, Alford, Hibbing, Miller, Scalora, Hatemi and Hibbing2008) and take the average of the natural log of SCL during the image and the ISI (Equation 1 summarizes this approach). As such, we create a change-in-skin-conductance-level variable whereby higher values indicate that skin conductance levels increase during the exposure to the message.

$$ \varDelta SC{L}_i=\frac{\sum_{j=1}^{tim{e}_T}\mathit{\ln}\left[ SCL{(T)}_{\mathrm{ij}}\right]}{tim{e}_T}-\frac{\sum_{j=1}^{tim{e}_T} ln\left[ SCL{(Baseline)}_{ij}\right]}{tim{e}_T}\kern1.00em $$ (1)

The valence of emotions is measured using a facial electromyagram (EMG) (Tassinary, Cacioppo, and Vanman Reference Tassinary, Cacioppo, Vanman, Cacioppo, Tassinary and Berntson2007; see Appendix A.10 for more details).Footnote ³ To measure negative affect, we measure the activity of the corrugator supercilii muscle—above the eyebrow (see panel B of Figure 1). The corrugator has no overlapping muscle groups and has a very limited representation in the motor cortex and “tends to be bilateral innervated” (Larsen, Norris, and Cacioppo Reference Larsen, Norris and Cacioppo2003, 776–777). The measurement of the corrugator is therefore less subject to disruptions from the (voluntary) movement of other muscles.

To measure positive affect, we measure the activity of the zygomaticus major (Larsen, Norris, and Cacioppo Reference Larsen, Norris and Cacioppo2003). It is a difficult muscle to measure because it has greater contralateral innervation (Larsen, Norris, and Cacioppo Reference Larsen, Norris and Cacioppo2003), and the cheek—where the zygomaticus is located (see panel B of Figure 1)—is a particularly crowded area of the face with lots of muscles (Tassinary, Cacioppo, and Vanman Reference Tassinary, Cacioppo, Vanman, Cacioppo, Tassinary and Berntson2007). This makes measures of the zygomaticus susceptible to “cross talk” (Larsen, Norris, and Cacioppo Reference Larsen, Norris and Cacioppo2003, 777). Irrespective of the difficulties of measuring the zygomaticus, it is a unique measure to capture positive affect. Zygomaticus activity was only recorded in protocol 1 and not in protocol 2.

People do not constantly frown or laugh, at least not in response to the type of political messages we used during the experiment. The object of interest of EMG analyses is whether people frowned or laughed. To evaluate this, we first cleaned the data as follows: we extracted EMG per second and calculated the change between t and t − 1. There was a time trend in that data. We extracted the time trend by regressing change on time. The subsequent model predictions were subtracted from the transformed data. We subsequently decided on a cutoff value of 10 microvolts as a peak. We kept all increases of 10 microvolts and larger, and for each individual we summed these peaks and logged it to procure a normally distributed variable. We have experimented with several alternatives: using individual cutoff values based on within-individual deviations, sums of all changes, and the number of peaks. In most cases, correlations between the 10-microvolt cutoff point and the other variables were high, and the alternative operationalizations led to similar regression output (see Appendix C.2).Footnote ⁴

Like all other physiological measures, heart rate variability was registered with the VSRRP98 program (see Appendix A.9). The program contains an algorithm to extract peaks from the raw heartbeat data. We manually checked and corrected the algorithm where necessary. The program also calculates the root mean square of successive differences (RMSSD), which is a standard measure of heart rate variability—that is also used by Soroka, Fournier, and Nir (Reference Soroka, Fournier and Nir2019)—and is based on the standard deviation of the interbeat intervals (Blascovich et al. Reference Blascovich, Vanman, Mendes and Dickerson2014). As we do for skin conductance, we compare the mean heart rate variability during exposure to the message with the baseline. A positive value indicates an increase in heart rate variability compared with the baseline, while a negative value indicates a decrease in heart rate variability.

All physiological measures were visually inspected by the researchers as well as a student assistant blind to the expectations of our study. We cross-checked anomalies with the lab log. In the case of EMG, sometimes electrodes fell off during the experiment, and these data points were removed. In the case of heart rate there were some anomalies due to movement of the participant or improper placement of the measurement equipment. We also removed these data points. As a consequence, the number of observations will differ per analysis of physiological measures.

In a subset of protocol 1—during the cultural festival (see Table 1)—we asked respondents (N = 143) to self-report their levels of enthusiasm, anger, and anxiety on a 0–100 thermometer in response to the immigration treatment.Footnote ⁵ In this subset of our data, these measures do not correlate with the physiological measures.Footnote ⁶ We use these self-reported emotions in the final exploratory analysis concerning the effects of physiological responses (see Appendix A.11 for all correlations between physiology and self-reported emotions).

Method of Analysis

To evaluate our hypotheses, we pool the data across the different clips (N = 961 for arousal, N = 1,032 for negative affect, N = 1,012 for heart rate variability, and N = 429 for positive affect). We pool because of power reasons. Similar to earlier psychophysiological studies (e.g., Mutz Reference Mutz2007; Mutz and Reeves Reference Mutz and Reeves2005; Soroka, Fournier, and Nir Reference Soroka, Fournier and Nir2019; Soroka and McAdams Reference Soroka and Mcadams2015), we expected small-sized effects. A power analysis conducted after the data was collected and based on the regression procedure described below indicates that our achieved power in the pooled analysis of corrugator activity is 0.96. However, once we subset to specific issues, specific clips, or on independent variables, power drops dramatically to values below 0.8 (see Appendix A.1 for calculations). Therefore, we are reluctant to disaggregate our analyses to the individual clips or other subsets of the data.

For Hypotheses 1 and 2, we run one OLS regression analysis: our dependent variable is change in skin conductance and our main independent variables are attitude extremity and political knowledge. In this analysis, we control for the computer the respondent used, the temperature during the experiment (Venables and Mitchell Reference Venables and Mitchell1996), the order in which the treatment was received, the salience of the issue (for the respondent), gender, age, educational level, the percentage level of alcohol in blood, and dummy variables to pick up differences between treatments. We provide detailed information about each of the covariates in Appendix A.7. By using these covariates, we pick up any differences in the protocols as well as possible distortions due to the time and place of the specific data collection. We cluster our standard errors by individual to account for the interdependence in our observations. Formula 2 is used to evaluate hypotheses 1 and 2, with k reflecting the issue and Right-wing reflecting whether participant _i was assigned to the right-wing treatment on issue k (1) or the left-wing treatment on issue k (0).Footnote ⁷

$$ {\displaystyle \begin{array}{ccc}\Delta \mathrm{SC}{L}_{ik}={\beta}_0+{\beta}_1\ast Extremit{y}_{ik}+{\beta}_2\ast Knowledg{e}_i+{\beta}_3\ast Right- win{g}_{ik}+ controls& & \end{array}} $$ (2)

For the hypotheses 3–5, we add the incongruence variable and omit the treatment direction variable. This leads to formula 3. We use the change in corrugator activity, the zygomaticus activity, and heart-rate variability (RMSSD) as dependent variables.

$$ {\displaystyle \begin{array}{ccc}& \Delta Corrugato{r}_{ik}\divslash \Delta Zygomaticu{s}_{ik}\divslash \Delta RMSS{D}_{ik}& \\ {}& ={\beta}_0+{\beta}_1\ast Extremit{y}_{ik}+{\beta}_2\ast Knowledg{e}_i+{\beta}_3\ast Incongruenc{e}_{ik}+ controls\end{array}} $$ (3)

For the purposes of interpretation we have standardized all variables, except for the dichotomous variables.