Achieve Synergy in Group Decision Making PDF

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This article discusses how to achieve synergy in group decision-making. It explores the concept of a hidden profile paradigm, and how groups can achieve better decisions than their individual members could achieve. The article highlights the importance of discussion intensity and bias in processing information for synergy in group decision-making.

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How to achieve synergy in group decision making: Lessons to be learned from
the hidden profile paradigm

Article in European Review of Social Psychology · March 2012
DOI: 10.1080/10463283.2012.744440

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 EUROPEAN REVIEW OF SOCIAL PSYCHOLOGY
2012, 23, 305–343

How to achieve synergy in group decision making:
Lessons to be learned from the hidden profile paradigm
Stefan Schulz-Hardt1 & Andreas Mojzisch2
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1
Georg-Elias-Müller-Institut für Psychologie, Georg-August-University
Göttingen, Göttingen, Germany
2
Institute of Psychology, University of Hildesheim, Hildesheim, Germany

Based on over 25 years of research on hidden profiles and information sharing
in groups, and particularly our own work in this area, we outline a general
model of how groups can achieve better decisions in a hidden profile situation
than their individual members would have been capable of (i.e., synergy). At
its core the model defines intensity and bias as the two key parameters that
have to be optimised with regard to both the discussion of information and the
processing of information in order to ensure synergy in group decision making.
We review the empirical literature on information sharing and group decision
making in the hidden profile paradigm (with a particular focus on our own
studies) to illustrate how group decision quality can be enhanced by increasing
intensity and decreasing bias in the discussion and processing of information.
Finally we also outline why we think that the lessons learned from research
using the hidden profile paradigm can be generalised to group decision-making
research in general, and how these lessons can stimulate studies in other fields
of group decision-making and group performance research.

Keywords: Group performance; Hidden profile; Information pooling; Process
gain; Synergy; Biased sampling.

Important decisions with far-reaching consequences are often made by
groups rather than individuals. For example, the managerial board of an
organisation is responsible for strategic decisions affecting the whole
organisation, high-ranking personnel (e.g., in a university) are hired by
selection committees, and police investigations in particularly important

Correspondence should be addressed to Stefan Schulz-Hardt, Georg-August-Universität
Göttingen, Georg-Elias-Müller-Institut für Psychologie, Wirtschafts- und Sozialpsychologie,
Gosslerstrasse 14, D - 37073 Göttingen, Germany. E-mail: [email protected]

Ó 2012 European Association of Social Psychology
http://www.psypress.com/ersp http://dx.doi.org/10.1080/10463283.2012.744440
 306 SCHULZ-HARDT AND MOJZISCH

criminal cases are subjected to special commissions. One of the reasons for
the popularity of groups when it comes to making decisions is the belief that
using groups will pay off with regard to decision quality. Taking up the spirit
of Aristotle’s famous words that ‘‘the whole is more than the sum of its
parts’’, groups are often expected to achieve ‘‘synergy’’; that is, to yield a
surplus in decision quality that individual decision makers would not be
capable of (e.g., McGrath, 1984). However, the reality of group decision
making often falls short of these expectations. The aim of this paper is to
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shed some light on why this may be the case and, hence, how this deficit
might be overcome.

NECESSARY PRECONDITIONS FOR SYNERGY IN
GROUP DECISION MAKING
The above-mentioned question of whether and under what conditions
working in groups yields a group-specific surplus in performance is at the
heart of social psychological group performance research (for an overview,
see Schulz-Hardt & Brodbeck, 2012). The basic aim of this research is to
determine whether interaction and social interdependence in a group
facilitate or hinder performance, and to specify the particular cognitive,
motivational, and coordination processes that are responsible for this
facilitative or inhibiting effect of group interaction. To this end, group
performance is compared with a statistical baseline that indicates what
performance would be expected in the absence of any functional or
dysfunctional group processes. Often this baseline is determined by either
introducing nominal groups (i.e., groups where no interaction takes
place and all members generate their contributions to the group product
individually) or by measuring the real group members’ individual
contributions (e.g., their individual judgements or their individual propo-
sals) prior to the real group interaction. If group performance exceeds this
baseline, then a group-specific performance surplus has been identified (and
vice versa for group performance below the baseline).
Over time, such group-specific performance surplus has been discussed and
investigated under different labels such as, for example, ‘‘assembly bonus
effect’’ (Collins & Guetzkow, 1964) or ‘‘process gain’’ (Hackman & Morris,
1975). Recently Larson (2010) extended and integrated these earlier
approaches into a general framework of synergy in groups. Whereas so-called
weak synergy is said to occur if group performance exceeds the average
performance in a nominal group, strong synergy requires the group to perform
better than even the best individual member of a nominal group does.1

1
So far, ‘‘process gains’’ is the term most frequently used in the literature to denote a
performance surplus that is due to group-specific processes. However, the use of this term
 SYNERGY IN GROUP DECISION MAKING 307

With regard to group decision making, this approach implies that groups
realise synergy if (and only if) they make decisions that have a higher quality
than either the average or the best of their group members’ individual
decisions prior to group interaction—the former would constitute weak
synergy, whereas the latter would be a case of strong synergy. This is an
important implication, because it indicates that in many decision-making
situations groups will not have the potential to realise such synergy. For
example, let us assume that the group has to decide among several
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alternatives, and each alternative is characterised by certain advantages and
disadvantages. For the sake of simplicity, let us further assume that all
advantages and disadvantages have equal strength. (We know that this is
often not the case, but all of the following arguments could also be made
with advantages and disadvantages of different strength—only with the
reasoning becoming more complex.)
Obviously then, the best alternative is the one with the most advantages
and the least disadvantages, the second best alternative scores second best
on advantages and disadvantages, and so on. Typically, not all group
members know about all advantages and disadvantages of the various
alternatives individually. Whereas some pieces of information will be
known to all members of the group (such pieces of information are called
shared information), other pieces of information (so-called unshared
information) will be unique knowledge of a single group member. There
is, of course, also information that is known to some but not all members
of a group—once again, for the sake of simplicity, we will leave this
partially shared information aside. However, it would not change the
nature of our arguments if this type of information were taken into
account.

involves some problems. Similar to Larson’s concept of synergy, the conceptual idea is to
determine a plausible baseline of performance that occurs in the absence of (functional or
dysfunctional) group processes and then measure whether group performance exceeds this
baseline (which would indicate process gains) or falls below this baseline (showing process
losses). The baseline used to determine process losses and process gains is the so-called group
potential, a concept developed by Steiner (1972) in his influential book on productivity in
groups. The problem is that Steiner did not foresee the possibility of process gains; his analysis
only dealt with process losses. Consequently his idea of group potential was that it should
denote the maximum productivity possible when taking task demands and group member
resources into account. This implies that researchers who are (also) interested in the detection of
process gains either have to work with an artificially enhanced baseline, which makes the
detection of such process gains rather unlikely, or have to apply a more pragmatic group
potential, which (at least partially) departs from the original definition and meaning of the
concept. In turn, what might be called ‘‘process loss’’ in one analysis might be a ‘‘process gain’’
in another one. To avoid such problems we decided to apply the Larson (2010) synergy concept
throughout this paper.
 308 SCHULZ-HARDT AND MOJZISCH

It is the unshared information that makes group decision making an
attractive choice for someone who wants to increase decision quality:
Because different members bring different knowledge to the table, having a
group discuss and decide a decision problem should lead to a broader
knowledge base for the decision, and this should increase decision quality
(e.g., Hollenbeck et al., 1995).
Now, unless systematic asymmetries are present that make the
advantages (or disadvantages) of certain alternatives particularly unlikely
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to be shared among members, it is very likely that each group member has
individual information prior to discussion that is more or less representa-
tive of the overall information. In other words, not everybody knows
everything, but most group members should have individual information
that makes the best alternative look good (or even superior to all others)
right from the beginning, and the worst alternative should also appear to
be relatively weak from the start onwards. Such a situation is called a
manifest profile, because the rank-order of alternatives is evident from the
beginning (Lavery, Franz, Winquist, & Larson, 1999). The important
point is: Whenever information is distributed in this way, groups can
hardly realise synergy in group decision making. Discussing the issue in
the group might enlarge each member’s individual knowledge base, but
this will not have substantial impact on the final decision: Because it was
evident from the beginning which alternative was best (and, hence, at least
the large majority of group members should have preferred it from the
beginning), having a group discuss and decide the issue hardly has any
potential to increase decision quality (for a related point, see Hastie &
Kameda, 2005).
This reasoning directly implies that, if we expect group decision making
to lead to synergy, and if we want to check whether this really is the case
(or how such synergy can be facilitated), we have to look at situations
where the correct or best choice is not evident from the beginning. Such
situations are called hidden profiles (Stasser, 1988). In the next section we
will briefly describe these situations, and we will highlight the, more or
less, disappointing performance of groups when dealing with hidden
profiles. We will then outline a general model categorising the processes
that are necessary for solving hidden profiles and, hence, for the
realisation of synergy (and even strong synergy!) in group decision
making. In addition we will map the empirical hidden profile literature
onto these categories, with a particular focus on our own studies during
the last 10 years. In the final section we will draw implications from the
model and will discuss whether and to what extent these considerations
can be generalised to other types of group tasks like, for example, problem
solving.
 SYNERGY IN GROUP DECISION MAKING 309

HIDDEN PROFILES: THE (OFTEN MISSED) OPPORTUNITY TO
REALISE SYNERGY IN GROUP DECISION MAKING
The hidden profile paradigm
As previously outlined, systematic synergy in group decision making is only
possible if the correct choice (i.e., the best alternative) cannot be detected by
group members based on the individual information that they privately have
prior to discussing the issue in the group. This is exactly the case in the
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hidden profile paradigm, introduced by Stasser and Titus (1985). In a hidden
profile one of the decision alternatives is superior to the others when the full
information set (i.e., the total of the information available at the group level)
is taken into account. However, this superiority only becomes evident when
the group members’ unshared (i.e., uniquely held) information is pooled and
integrated into a revised appraisal of the alternatives. In the case of a hidden
profile, much of the information supporting the best alternative (i.e.,
advantages of this alternative and disadvantages of other alternatives) is
unshared, whereas the shared information either supports one or more
suboptimal alternatives or no alternative at all. Hence hidden profiles can be
solved only if group members exchange and integrate their unshared pieces
of information and thereby are able to detect the decisional implication of
the full information set.
An example of such a hidden profile information distribution is given in
Table 1; we have used this material in some of our own studies on group
decision making (e.g., Schulz-Hardt, Brodbeck, Mojzisch, Kerschreiter, &
Frey, 2006). The participants play the role of personnel managers in an
airline company that is looking to hire a new pilot for long-distance flights.
The material is constructed for use in three-person groups (although it can
easily be modified for other group sizes). When taking all information into
account, it is clear that Candidate C is vastly superior to Candidates A, B,
and D: Whereas Candidate C has seven advantages and only three
disadvantages, Candidates A, B, and D each have only four advantages,
but six disadvantages. As we have mentioned above, we operate with the
simplifying assumption that the different advantages and disadvantages are
(almost) equal in strength. Therefore in empirical hidden profile studies
extensive pretests are necessary to make sure that this assumption is met and
that participants do, on average, perceive similarity in importance and
reliability between the different pieces of information.
However, whereas all of the advantages of Candidates A, B, and D as
well as all the disadvantages of Candidate C are shared, all disadvantages of
Candidates A, B, and D as well as most advantages of Candidate C are
unshared (and each group member has the same amount of unshared
information). As a consequence each group member individually knows the
 310 SCHULZ-HARDT AND MOJZISCH

four advantages of A, B, and D, but only two of the disadvantages of each
of these candidates. In contrast, each group member is aware of all three
disadvantages of Candidate C prior to discussion, but knows only three of
this candidate’s seven advantages (the one shared advantage plus two of the
six unshared advantages). Hence for each group member Candidate C
should appear as the weakest candidate prior to discussion (and, hence,
group members should favour A, B, or D), although this candidate is, in
fact, the best choice based on all information. As outlined earlier, the correct
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choice cannot be identified prior to discussion. And, as we can see from
Table 1, this information distribution bears a large potential for synergy,
because by choosing Candidate C the groups can make a vastly superior
decision compared to what should be the outcome without information
exchange in the group (namely a decision for Candidate A, B, or D).

The failure of groups to solve hidden profiles
Since Stasser and Titus’ seminal study published in 1985, many empirical
investigations of group decision making in hidden profiles situations have
been conducted. So far, these empirical investigations have been —with one
very recent exception (Stasser, Abele, & Vaughan Parsons, 2012)—
exclusively laboratory experiments. This focus does not neglect the
importance of hidden profiles in the field, but for practical reasons
investigating hidden profiles in field settings is almost impossible: Detecting
them would require that the researcher knows the whole set of decision-
relevant cognitions of all group members prior to the first group meeting,
and it is hard to see how that could be realised in the field. In contrast, in a
laboratory setting the researcher has perfect control over the decision-
relevant information available to group members and, thus, has the ability
to induce any information distribution of interest.
The typical procedure in these laboratory experiments is to invite
participants to the lab and provide each of them with general instructions as
well as individual information about a decision case. Usually university
students serve as participants in these experiments, but there are also studies
with a practitioner sample such as, for example, medical teams working on
medical disease diagnosis (e.g., Larson, Christensen, Franz, & Abbott,
1998). There are typically two (Winquist & Larson, 1998), three (e.g., Stasser
& Titus, 1985), or four (e.g., Schulz-Hardt et al., 2006) decision alternatives.
After participants have studied their individual materials and have evaluated
the different decision alternatives based on this information, the information
materials are collected by the experimenter, which means that participants
discuss the decision case from memory. Although this might, at first glance,
appear to be an artificial constraint, a closer look reveals that this procedure
is not that ecologically invalid, because group members hardly ever have a
 SYNERGY IN GROUP DECISION MAKING 311

written excerpt of all their decision-relevant knowledge with them when
discussing and deciding an issue in a group. Even in cases where written (or
electronically stored) materials about the decision case exist (e.g., the
candidate information files in an appointment committee), and hence group
members can flip through these materials during discussion, it is often the
private (unshared) knowledge of the group members that has a particular
impact on the final decision (e.g., ‘‘I know that XY just bought a house in
Aston, so it is highly unlikely that he will move over to London’’).
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Prior to group discussion, participants usually receive further instruc-
tions. In particular participants are made aware of the fact that the
individual information sets that they have received are not identical:
Whereas some pieces of information are shared among them, other parts of
the individual information differ among members. Furthermore, it is
typically emphasised that the decision case features a superior alternative
that can be found on the basis of all the information that is available to
group members as a whole, and that the participants’ task is to identify this
superior alternative. At least in our own experiments, it is also standard to
have a financial incentive for groups to detect this superior alternative.
Hence, unlike in decision-making groups in practice that often lack the
above-mentioned features, preconditions for the realisation of synergy in
group decision making are almost optimal in these experiments: There is no
deception involved, full transparency about the requirements of the
situation is given, and there are no side-bets that might motivate group
members to favour suboptimal alternatives (e.g., they have no external
incentive for ‘‘pushing through’’ their own candidate in a personnel selection
task)—the only external incentives given are in favour of cooperatively
trying to find the best alternative.
In spite of these almost ideal conditions, more than 25 years of research
on hidden profiles have shown that groups actually fare pretty badly at
detecting and solving hidden profiles. For example, in the seminal Stasser
and Titus (1985) study, 83% of the groups chose the best alternative in the
manifest profile condition2, but only 18% did so in the hidden profile
conditions. Similarly, in the Schulz-Hardt et al. (2006) study that used the
case material from our example in Table 1, all groups in the manifest profile
condition made the correct decision, whereas only 35% of the groups in the
hidden profile conditions picked the best alternative; although, as we have
seen, this alternative is vastly superior to any of its competitors. These two
studies are no outliers: As systematic reviews of the hidden profile literature
(e.g., Brodbeck, Kerschreiter, Mojzisch, & Schulz-Hardt, 2007) as well as a

2
In this condition participants were given the full information set right from the beginning.
However, we still label such a condition ‘‘manifest profile’’, because the defining feature (initial
information set is representative of the overall information set) is necessarily true in such a case.
 312 SCHULZ-HARDT AND MOJZISCH

TABLE 1
An example of a hidden profile task

Candidate A Candidate B
– can anticipate dangerous situations – keeps calm in a crisis
– is able to see complex connections – known to be 100% reliable
– has excellent spatial vision – good at assessing weather conditions
– has very good leadership qualities – has excellent computer skills
– is sometimes not good at taking – can be grumpy
criticism – can be uncooperative
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– can be unorganised – has a relatively weak memory for
– is regarded as a show-off numbers
– is regarded as being not open to new – makes nasty remarks about his
ideas colleagues
– is unfriendly – is regarded as pretentious
– eats unhealthily – sometimes adopts the wrong tone
when communicating

Candidate C Candidate D
– can make correct decisions quickly – responds to unexpected events
– handles stress very well adequately
– creates a positive atmosphere with his – can concentrate very well
crew – solves problems extremely well
– is very conscientious – takes responsibility seriously
– understands complicated technology – is regarded as arrogant
– puts concern for others above – has relatively weak leadership skills
everything – is regarded as a ‘‘know-it-all’’
– has excellent attention skills – has a hot temper
– has difficulty communicating ideas – is considered moody
– is regarded as egocentric – is regarded as a loner
– is not very willing to further his
education

The decision case deals with an airline looking to fill the position of a pilot for long-distance
flights; the four Candidates A, B, C, and D are characterised by the attributes listed; shared
information is given in bold.

recent meta-analysis of hidden profile studies (Lu, Yuan, & McLeod, 2012)
consistently show, groups typically fail to solve hidden profiles.
To illustrate this failure let us take a closer look at the results from one of
our own hidden profile studies (Greitemeyer, Schulz-Hardt, Brodbeck, &
Frey, 2006). In this study three-person groups worked on four subsequent
decision cases. Three of these cases had a hidden profile distribution of
information, whereas one of them was a manifest profile. Each of the cases
comprised three decision alternatives, forming a clear rank-order in decision
quality. Whereas in the manifest profile case this rank-order was already
present in the group members’ individual information sets (i.e., the
alternative that was best based on all information also had the best relation
 SYNERGY IN GROUP DECISION MAKING 313

of advantages and disadvantages in each group member’s individual
information set), the members’ individual information sets in the hidden
profile cases reversed this rank-order. In other words, in the hidden profile
cases the particular alternative that was best based on all information
initially appeared to be the least suited to each group member (vice versa for
the worst alternative).
Now, as the results of this study show, groups had no difficulty in
detecting this rank-order when dealing with a manifest profile distribution of
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information: The vast majority of groups (89%) chose the best alternative,
whereas only a small proportion of groups chose the second best (7%) or the
worst alternative (4%). The opposite happened in the hidden profile cases.
Most of the groups chose the worst alternative (87%)—that is, the one that
appeared to be superior in the group members’ initial individual materials—
and only very few groups decided for the second best (6%) or the best
alternative (7%). In other words: Groups are able to realise a high decision
quality in situations where their individual members would already realise a
high decision quality (manifest profile). Ironically, however, they fail to do
so in the very situation where they have the opportunity to achieve synergy
by realising a surplus in decision quality compared to what would have been
possible without group interaction.
To further illustrate this point we have reanalysed the data published in
our Greitemeyer et al. (2006) study. For these purposes we have calculated
the baselines for the tests of weak and strong synergy, and we have done that
separately for the manifest profile case and for the hidden profile cases. As
already outlined, strong synergy occurs only if the group decision is better
than the best individual decision that any of the group members has initially
made. With regard to this, all groups contained at least one member who
favoured the best alternative prior to discussion. As a consequence there was
no room for strong synergy (ceiling effect). This picture was almost the same
for weak synergy: For weak synergy to occur, the group decisions have to be
better than the average individual decisions. In the manifest profile case
90% of the group members already chose the best alternative prior to
discussion, 5% chose the second best, and another 5% chose the worst.
Thus, once again we can see that in a manifest profile hardly anything can be
gained from having a group decide the issue—and hardly anything was
gained, because the real group decisions were almost identical with this
latter baseline (as illustrated in Figure 1a).
This is completely different in the case of a hidden profile. As can be seen
in Figure 1b, here a very high potential for weak synergy was present: Prior
to discussion, 88% of the group members favoured the worst option, 4%
favoured the second best, and 8% favoured the best. Hence average
individual decision quality was low, as would be expected given the
insufficient and misleading individual information. Even for strong synergy
 314 SCHULZ-HARDT AND MOJZISCH
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Figure 1 (a) Individual decision quality prior to discussion vs group decision quality in the
manifest profile case (Greitemeyer, Schulz-Hardt, Brodbeck, & Frey, 2006). (b) Individual
decision quality prior to discussion vs group decision quality in the hidden profile cases
(Greitemeyer, Schulz-Hardt, Brodbeck & Frey, 2006).

the potential was high: In about three out of four cases all three members
initially favoured the worst option, which means that strong synergy would
occur if the second best or best alternative is chosen by these groups.
Furthermore, in the 7% of the cases where the best individual decision was
for the second best option, a group choice of the best alternative would also
have yielded strong synergy (and only for the 17% of the groups containing
one member who initially preferred the best option, no strong synergy was
possible). However, as the comparison with the real group choices in
Figure 1b shows, both types of synergy failed to materialise, because group
decision quality was more or less at the level of the average individual
 SYNERGY IN GROUP DECISION MAKING 315

decisions—although groups theoretically had much more information than
their individual members initially had, and although that additional
information would have allowed them to detect the best option.
Taken together, this reanalysis shows that groups reach a fairly high
decision quality in situations where—in terms of decision quality—nothing
can be gained from having groups as decision makers. In contrast, in the
very situation where they have the potential to achieve synergy and
thereby make group decision making pay off in terms of decision quality,
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they typically fail to do so (for a more extensive discussion of this issue,
see Mojzisch & Schulz-Hardt, 2011). As a consequence, if we want to
continue using groups as a tool for increasing decision quality, we have to
find out what particular processes hinder groups from solving hidden
profiles and, in turn, how synergy in group decision making can be
facilitated.
In two earlier publications (Brodbeck et al., 2007; Mojzisch & Schulz-
Hardt, 2006) we have already suggested a model that tries to give
answers to these questions. However, some of our recent studies have led
to the necessity to substantially revise and further develop this model,
particularly by shifting the focus from biases in group information
processing to the intensity of group information processing. In the next
section we will outline our new, revised model, and we will describe
hidden profile studies supporting and illustrating the claims made in this
new model.

HURDLES FOR SYNERGY IN GROUP IN DECISION MAKING: A
GENERAL MODEL AND EMPIRICAL EVIDENCE
A general categorisation scheme
As outlined in the previous sections, a true potential for synergy in group
decision making arises only if the exchange of information in a group
changes the decisional implication of the information available to group
members. From this boundary condition we derive the general proposition
that the realisation of such synergy requires that decision-relevant
information is (a) discussed in the group and (b) individually processed by
group members. Discussion encompasses the introduction of information in
the group (i.e., mentioning information for the first time) and its repetition
by the same or other group members (i.e., something that was introduced
before is taken up at a later point in the discussion). By processing we mean
the encoding, storage, interpretation, and evaluation of information that is
discussed in the group. The necessity of both processes for the realisation of
synergy is hardly surprising in itself, but since most research on hidden
profiles has only addressed the discussion of information, without taking
 316 SCHULZ-HARDT AND MOJZISCH

into account how and to what extent the information discussed is processed
by the group members, we felt that this point has to be emphasised.
Furthermore, it can be derived that both the discussion of information
and the processing of the information discussed have to be characterised by
two qualities: a sufficient intensity and a sufficient lack of bias: Only if a
sufficient amount of information is exchanged, and only if the group
members process the information discussed in the group sufficiently to
realise its implications, do group members have a chance to detect the
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superiority of an alternative that initially did not appear to be that strong.
At the same time, if biases cause the group to discuss too little information
in favour of this particular alternative, or cause group members to evaluate
this information too negatively, the hidden profile will also not be solved
(what we particularly mean by ‘‘bias’’ and what would be an unbiased
discussion or processing will be specified in the corresponding sections
below). Once again, this proposition is rather straightforward, but due to
the fact that empirical hidden profile research has been far more been
concerned with biases (in particular, with discussion biases) than with the
intensity of the discussion and processing of information, it is important to
emphasise that both qualities are necessary.
The combination of the two processes discussion and processing with the
two characteristics intensity and bias gives a 2 6 2 matrix which is
illustrated in Figure 2 and which is the basic organising principle of our
model. The processes in each of the four cells have to be positively
manifested (i.e., sufficient intensity and lack of bias in both discussion and
processing of the information discussed) in order to allow groups to solve
hidden profiles. In contrast, a negative manifestation of any of the processes
in any of the four cells (i.e., insufficient intensity, insufficient processing,
biased discussion, biased processing) can be sufficient to completely hinder
groups from solving hidden profiles. Unfortunately the ‘‘default mode’’ of
both how groups exchange information and how information from group

Figure 2. Classification scheme for impairments to the solution of hidden profiles.
 SYNERGY IN GROUP DECISION MAKING 317

discussions is processed individually works against the solution of hidden
profiles. In other words, it is rather the rule than the exception that the
processes in each of the four cells of Figure 2 have negative manifestations.
In the following we will illustrate this unfortunate situation for each of the
four cells by referring to exemplary hidden profile research, with a particular
focus on our own studies.

Discussion bias
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As already outlined, hidden profile research so far has prioritised group
discussion at the expense of processing of the information discussed, and it
has been far more concerned with biases than with the general intensity of
group discussion and, to a lesser extent, individual information processing.
Hence most previous hidden profile studies have addressed biases in group
discussions as a reason for the failure of groups to solve hidden profiles.
Generally, we speak of a discussion bias if the mentioning and/or
repetition of information is not representative of the overall information set
available to the group members. For example, if in a personnel selection case
60% of the available pieces of information are positive (i.e., advantages of
particular candidates) and 40% are negative (i.e., disadvantages), and if then
70% of the pieces of information that are introduced into discussion are
negative, we would call this a bias in favour of negative information.
At least for the first 10 years since the initial Stasser and Titus (1985)
study, research on information pooling and hidden profiles in groups almost
exclusively dealt with one particular discussion bias: the bias in favour of
shared information. As we have seen in our exemplary decision case from
Table 1, solving a hidden profile requires the group to exchange and
integrate their members’ unshared information, because in a hidden profile a
large portion of the information in favour of the best alternative is—by
definition—unshared. Now, the most robust and well-replicated finding in
the group information pooling literature is that groups discuss more shared
than unshared information (for a summary, see the meta-analysis by
Lu et al., 2012). Specifically, this discussion bias means that more shared
than unshared information is introduced into group discussion and, once
introduced, shared information is also repeated more often than unshared
information, with the latter being true both for self-repetitions (i.e., the same
member who introduced the piece of information also repeats it) as well as
for repetitions by other group members (e.g., Larson, Foster-Fishman, &
Keys, 1994). To put it crudely, group discussions focus on what everybody
has already known prior to discussion.
This bias stems from stochastic rather than psychological processes: The
group will only fail to discuss a shared piece of information if all group
members independently forget to mention or are unwilling to mention this
 318 SCHULZ-HARDT AND MOJZISCH

particular piece of information. In contrast, if an unshared piece of
information is not mentioned by the one group member who holds it, there
is nobody who can compensate for this neglect. Thus, as long as the
probability of mentioning any given piece of information is not 0 or 1, a
stochastic bias in favour of shared information is inevitable (Stasser & Titus,
1987).3
Importantly, the critical information for solving a hidden profile (i.e.,
advantages of the best and disadvantages of the other alternatives) is not
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only predominantly unshared, but is also predominantly inconsistent with
the group members’ initial preferences. Because in a hidden profile the best
alternative is, by definition, not evident from the group members’ individual
information, most or all members will favour other alternatives prior to
discussion. Thus the advantages of the best alternative will be inconsistent
with the members’ initial decision preferences, as will be the disadvantages
of the particular alternative that a group member initially favours. In our
example from the previous section (Table 1), group members can be
expected to favour either A, B, or D prior to discussion. Thus most of the
pieces of information that are critical for choosing C (the best alternative)—
the advantages of C as well as the disadvantages of A, B, and D—will be
preference-inconsistent.
Interestingly, in their seminal study Stasser and Titus (1985) had already
predicted that group discussions would be biased not only in favour of
shared information, but also in favour of preference-consistent information.
However, it took more than a decade before the first experimental test of
this idea was published (Dennis, 1996). In his experiment six-person groups
that either worked face-to-face or used computer-mediated communication
discussed which of three students should be given admission to the
university. Information was distributed as a hidden profile. Results showed
the already well-known bias in favour of shared information, but when
analysing the unshared information separately Dennis showed that,
independent of the communication mode, members mentioned more
information supporting their initial preferences than neutral information
3
For the repetition of shared versus unshared information this bias seems to be less inevitable,
because once an unshared piece of information is introduced, all group members have the
possibility of repeating it. Some researchers have thus tried to explain this part of the discussion
bias in favour of shared information with psychological concepts, particularly referring to social
validation: Because the veracity of shared information can be confirmed by other group
members, it appears more credible and, in consequence, gets repeated more often (e.g.,
Wittenbaum et al., 1999). We will not go into the details of this reasoning because, according to
some critical replications that we conducted, the evidence for this approach is based on a
methodological shortcoming of the original studies and when controlling for this shortcoming
no evidence for a social validation explanation of biased repetitions favouring shared
information can be found (Mojzisch, Kerschreiter, Faulmüller, Vogelgesang, & Schulz-Hardt,
2012).
 SYNERGY IN GROUP DECISION MAKING 319

or information contradicting their initial preferences. The shared informa-
tion had to be left out of this analysis, because in a hidden profile sharedness
and preference-consistency of information are, at least partially, confounded
(i.e., a large part of the shared pieces of information is also preference-
consistent).
To avoid this problem and hence to demonstrate that there is a general
discussion bias in favour of preference-consistent information (independent
of whether information is shared or unshared), in a very recent study
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(Faulmüller, Mojzisch, Kerschreiter, & Schulz-Hardt, 2012) we used a non-
hidden profile information distribution (all alternatives were designed to be
equally attractive). The second aim of this study was to show that—in
contrast to the discussion bias in favour of shared information—the
discussion bias in favour of preference-consistent information has psycho-
logical roots. In two experiments participants exchanged information with a
partner in order to prepare a collective personnel decision. Because the
partner was either a bogus partner in a written information exchange
(participants received standardised written messages prepared by the
experimenter) or a confederate of the experimenter in a face-to-face
discussion, we had full experimental control over the partner’s communica-
tion behaviour. In each of the two experiments we manipulated whether the
partner favoured the same or a different job candidate than the participant,
and whether or not the partner indicated that s/he understood why the
participant favoured her/his preferred candidate. To illustrate, if a
participant in the experimental condition with ‘‘congruent preferences and
understanding’’ had a preference for candidate A, the bogus partner said, ‘‘I,
too, believe A is the better candidate, and, like you, I would choose him.
And, given the information you just passed on to me, I also understand why
you prefer him.’’ In contrast, in the experimental condition with ‘‘congruent
preferences and non-understanding’’, the bogus partner said, ‘‘I, too, believe
A is the better candidate. But, given the information you just passed on to
me, I don’t understand why you prefer him.’’ Analyses of the written
messages transferred to the partner (Experiment 1) or the videotapes of the
discussions (Experiment 2) allowed us to measure to what extent the
participant mentioned preference-consistent versus preference-inconsistent
information about the job candidates. Across both experiments there was a
clear predominance of preference-consistent information being mentioned.
Furthermore, whereas the partner’s preference (similar or dissimilar to the
participant’s preference) hardly affected this predominance, preference-
consistent information sharing was particularly strong when the partner said
that she did not understand why the participant held her or his preference,
as compared to when the partner stated that s/he understood this preference.
Figure 3 illustrates this pattern for the results of Experiment 2 (the face-to-
face discussions).
 320 SCHULZ-HARDT AND MOJZISCH
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Figure 3. Preference-consistent information sharing (number of preference-consistent pieces of
information minus number of preference-inconsistent pieces of information communicated by
the participants) dependent on preference congruity and preference understanding (Faulmüller,
Mojzisch, Kerschreiter & Schulz-Hardt, Expt. 2, 2012).

These findings inform us about possible motivational underpinnings of
the discussion bias in favour of preference-consistent information. Whereas
a motivation to convince the discussion partner does not seem to be the
driving force here (in this case we would have expected a particularly strong
bias if the partner’s preference is incongruent with the participant’s
preference), a motivation to be understood by the partner could be an
underlying motive of this bias: As Stasser and Titus (1985) had already
assumed, group members might implicitly take an ‘‘advocacy role’’ during
discussion; that is, their conversation behaviour is driven by the attempt to
explain to the other group members why they hold a particular preference—
and explaining a preference means mentioning information that is consistent
with this preference.
In addition, one of our other recent experiments (Mojzisch, Grouneva,
& Schulz-Hardt, 2010) hints at the possibility that cognitive factors might
also be responsible for the preference-consistent discussion bias: As we will
outline below in the section on biased information processing, people have
a general tendency to attribute a higher quality to preference-consistent as
compared to preference-inconsistent information. Hence, if people simply
want to communicate the best information (in terms of credibility,
reliability, and information strength), they should predominantly mention
preference-consistent information. In other words, group members might
 SYNERGY IN GROUP DECISION MAKING 321

discuss in a preference-consistent manner without intending to do so. The
Mojzisch et al. (2010) study provides some data in accordance with this
interpretation. In this study participants first received information about
two decision alternatives and were asked to indicate their preference. Next
they were asked to evaluate the quality of each piece of information.
Thereafter partici