Quantifying the effect of sentiment on information diffusion in social media


Submitted 19 June 2015
Accepted 15 September 2015
Published 30 September 2015

Corresponding author
Emilio Ferrara, ferrarae@isi.edu,
emilio.ferrara@gmail.com

Academic editor
Ciro Cattuto

Additional Information and
Declarations can be found on
page 11

DOI 10.7717/peerj-cs.26

Copyright
2015 Ferrara and Yang

Distributed under
Creative Commons CC-BY 4.0

OPEN ACCESS

Quantifying the effect of sentiment on
information diffusion in social media
Emilio Ferrara1 ,2 and Zeyao Yang1

1 Information Sciences Institute, University of Southern California, Marina Del Rey, CA,
United States

2 School of Informatics and Computing, Indiana University, Bloomington, IN, United States

ABSTRACT
Social media has become the main vehicle of information production and
consumption online. Millions of users every day log on their Facebook or Twitter
accounts to get updates and news, read about their topics of interest, and become
exposed to new opportunities and interactions. Although recent studies suggest that
the contents users produce will affect the emotions of their readers, we still lack a
rigorous understanding of the role and effects of contents sentiment on the dynamics
of information diffusion. This work aims at quantifying the effect of sentiment on
information diffusion, to understand: (i) whether positive conversations spread
faster and/or broader than negative ones (or vice-versa); (ii) what kind of emotions
are more typical of popular conversations on social media; and, (iii) what type of
sentiment is expressed in conversations characterized by different temporal
dynamics. Our findings show that, at the level of contents, negative messages spread
faster than positive ones, but positive ones reach larger audiences, suggesting that
people are more inclined to share and favorite positive contents, the so-called
positive bias. As for the entire conversations, we highlight how different temporal
dynamics exhibit different sentiment patterns: for example, positive sentiment builds
up for highly-anticipated events, while unexpected events are mainly characterized
by negative sentiment. Our contribution represents a step forward to understand
how the emotions expressed in short texts correlate with their spreading in online
social ecosystems, and may help to craft effective policies and strategies for content
generation and diffusion.

Subjects Data Mining and Machine Learning, Data Science, Network Science and Online Social
Networks
Keywords Computational social science, Social networks, Social media, Sentiment analysis,
Information diffusion

INTRODUCTION
The emerging field of computational social science has been focusing on studying the

characteristics of techno-social systems (Lazer et al., 2009; Vespignani, 2009; Kaplan &

Haenlein, 2010; Asur & Huberman, 2010; Cheng et al., 2014) to understand the effects

of technologically-mediated communication on our society (Gilbert & Karahalios,

2009; Ferrara, 2012; Tang, Lou & Kleinberg, 2012; De Meo et al., 2014; Backstrom &

Kleinberg, 2014). Research on information diffusion focused on the complex dynamics

that characterize social media discussions (Java et al., 2007; Huberman, Romero & Wu,

2009; Bakshy et al., 2012; Ferrara et al., 2013a) to understand their role as central fora

How to cite this article Ferrara and Yang (2015), Quantifying the effect of sentiment on information diffusion in social media. PeerJ
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to debate social issues (Conover et al., 2013b; Conover et al., 2013a; Varol et al., 2014),

to leverage their ability to enhance situational, social, and political awareness (Sakaki,

Okazaki & Matsuo, 2010; Centola, 2010; Centola, 2011; Bond et al., 2012; Ratkiewicz et

al., 2011; Metaxas & Mustafaraj, 2012; Ferrara et al., 2014), or to study susceptibility to

influence and social contagion (Aral, Muchnik & Sundararajan, 2009; Aral & Walker, 2012;

Myers, Zhu & Leskovec, 2012; Anderson et al., 2012; Lerman & Ghosh, 2010; Ugander et al.,

2012; Weng & Menczer, 2013; Weng, Menczer & Ahn, 2014). The amount of information

that generated and shared through online platforms like Facebook and Twitter yields

unprecedented opportunities to millions of individuals every day (Kwak et al., 2010; Gomez

Rodriguez, Leskovec & Schölkopf, 2013; Ferrara et al., 2013b). Yet, how understanding of the

role of the sentiment and emotions conveyed through the content produced and consumed

on these platforms is shallow.

In this work we are concerned in particular with quantifying the effect of sentiment on

information diffusion in social networks. Although recent studies suggest that emotions

are passed via online interactions (Harris & Paradice, 2007; Mei et al., 2007; Golder & Macy,

2011; Choudhury, Counts & Gamon, 2012; Kramer, Guillory & Hancock, 2014; Ferrara &

Yang, 2015; Beasley & Mason, 2015), and that many characteristics of the content may affect

information diffusion (e.g., language-related features (Nagarajan, Purohit & Sheth, 2010),

hashtag inclusion (Suh et al., 2010), network structure (Recuero, Araujo & Zago, 2011), user

metadata (Ferrara et al., 2014)), little work has been devoted to quantifying the extent to

which sentiment drives information diffusion in online social media. Some studies sug-

gested that content conveying positive emotions could acquire more attention (Kissler et

al., 2007; Bayer, Sommer & Schacht, 2012; Stieglitz & Dang-Xuan, 2013) and trigger higher

levels of arousal (Berger, 2011), which can further affect feedback and reciprocity (Dang-

Xuan & Stieglitz, 2012) and social sharing behavior (Berger & Milkman, 2012).

In this study, we take Twitter as scenario, and we explore the complex dynamics

intertwining sentiment and information diffusion. We start by focusing on content

spreading, exploring what effects sentiment has on the diffusion speed and on content

popularity. We then shift our attention to entire conversations, categorizing them into

different classes depending on their temporal evolution: we highlight how different types

of discussion dynamics exhibit different types of sentiment evolution. Our study timely

furthers our understanding of the intricate dynamics intertwining information diffusion

and emotions on social media.

MATERIALS AND METHODS
Sentiment analysis
Sentiment analysis was proven an effective tool to analyze social media streams, especially

for predictive purposes (Pang & Lee, 2008; Bollen, Mao & Zeng, 2011; Bollen, Mao & Pepe,

2011; Le, Ferrara & Flammini, 2015). A number of sentiment analysis methods have been

proposed to date to capture content sentiment, and some have been specifically designed

for short, informal texts (Akkaya, Wiebe & Mihalcea, 2009; Paltoglou & Thelwall, 2010;

Hutto & Gilbert, 2014). To attach a sentiment score to the tweets in our dataset, we here

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adopt a SentiStrength, a promising sentiment analysis algorithm that, if compared to other

tools, provides several advantages: first, it is optimized to annotate short, informal texts,

like tweets, that contain abbreviations, slang, and the like. SentiStrength also employs

additional linguistic rules for negations, amplifications, booster words, emoticons,

spelling corrections, etc. Research applications of SentiStrength to MySpace data found it

particularly effective at capturing positive and negative emotions with, respectively, 60.6%

and 72.8% accuracy (Thelwall et al., 2010; Thelwall, Buckley & Paltoglou, 2011; Stieglitz &

Dang-Xuan, 2013).

The algorithm assigns to each tweet t a positive S+(t) and negative S−(t) sentiment

score, both ranging between 1 (neutral) and 5 (strongly positive/negative). Starting from

the sentiment scores, we capture the polarity of each tweet t with one single measure, the

polarity score S(t), defined as the difference between positive and negative sentiment scores:

S(t) = S+(t) − S−(t). (1)

The above-defined score ranges between −4 and +4. The former score indicates an

extremely negative tweet, and occurs when S+(t) = 1 and S−(t) = 5. Vice-versa, the latter

identifies an extremely positive tweet labeled with S+(t) = 5 and S−(t) = 1. In the case

S+(t) = S−(t)—positive and negative sentiment scores for a tweet t are the same— the

polarity S(t) = 0 of tweet t is considered as neutral.

We decided to focus on the polarity score (rather than the two dimensions of

sentiment separately) because previous studies highlighted the fact that measuring

the overall sentiment is easier and more accurate than trying to capture the intensity

of sentiment—this is especially true for short texts like tweets, due to the paucity of

information conveyed in up to 140 characters (Thelwall et al., 2010; Thelwall, Buckley &

Paltoglou, 2011; Stieglitz & Dang-Xuan, 2013; Ferrara & Yang, 2015).

Data
The dataset adopted in this study contains a sample of all public tweets produced during

September 2014. From the Twitter gardenhose (a roughly 10% sample of the social stream

that we process and store at Indiana University) we extracted all tweets in English that do

not contain URLs or media content (photos, videos, etc.) produced in that month. This

choice is dictated by the fact that we can hardly computationally capture the sentiment

or emotions conveyed by multimedia content, and processing content from external

resources (such as webpages, etc.) would be computationally hard. This dataset comprises

of 19,766,112 tweets (more than six times larger than the Facebook experiment (Kramer,

Guillory & Hancock, 2014)) produced by 8,130,481 distinct users. All tweets are processed

by SentiStrength and attached with sentiment scores (positive and negative) and with the

polarity score calculated as described before. We identify three classes of tweets’ sentiment:

negative (polarity score S ≤ −1), neutral (S = 0), and positive (S ≥ 1). Negative, neutral,

and positive tweets account for, respectively, 21.59%, 42.46% and 35.95% of the total.

The distribution of polarity scores is captured by Fig. 1: we can see it is peaked around

neutral tweets, accounting for over two-fifths of the total, while overall the distribution is

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Figure 1 Distribution of polarity scores computed for our dataset. The polarity score S is the dif-
ference between positive and negative sentiment scores as calculated by SentiStrength. The dataset
(N = 19,766,112 tweets, by M = 8,130,481 different users) contains 42.46% of neutral (S = 0), 35.95%
of positive (S ≥ 1), and 21.59% of negative (S ≤ −1) tweets, respectively.

slightly skewed toward positiveness. We can also observe that extreme values of positive

and negative tweets are comparably represented: for example, there are slightly above

446 thousand tweets with polarity score S = +3, and about 592 thousands with opposite

polarity of S = −3.

RESULTS
The role of sentiment on information diffusion
Here we are concerned with studying the relation between content sentiment and

information diffusion. Figure 2 shows the effect of content sentiment on the information

diffusion dynamics and on content popularity. We measure three aspects of information

diffusion, as function of tweets polarity scores: Fig. 2A shows the average number of

retweets collected by the original posts as function of the polarity expressed therein;

similarly, Fig. 2B shows the average number of times the original tweet has been favorited;

Fig. 2C illustrates the speed of information diffusion, as reflected by the average number

of seconds that occur between the original tweet and the first retweet. Both Figs. 2A and

2C focus only on tweets that have been retweeted at least once. Figure 2B considers only

tweets that have been favorited at least once. Note that a large fraction of tweets are never

retweeted (79.01% in our dataset) or favorited (87.68%): Fig. 2A is based on the 4,147,519

tweets that have been retweeted at least once (RT ≥ 1), Fig. 2B reports on the 2,434,523

tweets that have favorited at least once, and Fig. 2C is comprised of the 1,619,195 tweets for

which we have observed the first retweet in our dataset (so that we can compute the time

between the original tweet and the first retweet). Note that the retweet count is extracted

from the tweet metadata, instead of being calculated as the number of times we observe

a retweet of each tweet in our dataset, in order to avoid the bias due to the sampling rate

of the Twitter gardenhose. For this reason, the average number of retweets reported in

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Figure 2 The effect of sentiment on information diffusion. (A) the average number of retweets, (B) the average number of favorites, and (C) the
average number of seconds passed before the first retweet, as a function of the polarity score of the given tweet. The number on the points represent
the amount of tweets with such polarity score in our sample. Bars represent standard errors.

Fig. 2A seems pretty high (above 100 for all classes of polarity scores): by capturing

the “true” number of retweets we well reflect the known broad distributions of content

popularity of social media, skewing the values of the means toward larger figures. The

very same reasoning applies for the number of favorites. Due to the high skewness of the

distributions of number of retweets, number of favorites, and time before first retweet,

we performed the same analysis as above on median values rather than averages. The

same trends hold true: particularly interesting, average and median seconds before the

first retweet are substantially identical. The results for the average and median number of

retweets and favorites are also comparable, factoring out some small fluctuations.

Two important considerations emerge from the analysis of Fig. 2: (i) positive tweets

spread broader than neutral ones, and collect more favorites, but interestingly negative

posts do not spread any more or less than neutral ones, neither get more or less favorited.

This suggests the hypothesis of observing the presence of positivity bias (Garcia, Garas &

Schweitzer, 2012) (or Pollyanna hypothesis (Boucher & Osgood, 1969)), that is the tendency

of individuals to favor positive rather than neutral or negative items, and choose what

information to favor or rebroadcast further accordingly to this bias. (ii) Negative content

spread much faster than positive ones, albeit not significantly faster than neutral ones.

This suggests that positive tweets require more time to be rebroadcasted, while negative

or neutral posts generally achieve their first retweet twice as fast. Interestingly, previous

studies on information cascades showed that all retweets after the first take increasingly less

time, which means that popular content benefit from a feedback loop that speeds up the

diffusion more and more as a consequence of the increasing popularity (Kwak et al., 2010).

Conversations’ dynamics and sentiment evolution
To investigate how sentiment correlates with content popularity, we now only consider

active and exclusive discussions occurred on Twitter in September 2014. Each topic of

discussion is here identified by its most common hashtag. Active discussions are defined

as those with more than 200 tweets (in our dataset, which is roughly a 10% sample of the

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Figure 3 Dynamical classes of popularity capturing four different types of Twitter conversa-
tions. (A) shows the Gaussian Mixture Model employed to discover the four classes. The y and x
axes represent, respectively, the proportion of tweets occurring before and after the peak of popularity
of a given discussion. Different colors represent different classes: anticipatory discussions (blue dots),
unexpected events (green), symmetric discussions (red), transient events (black). (B) shows the BIC
scores of different number of mixture components for the GMM (the lower the BIC the better the GMM
captures the data). The star identifies the optimal number of mixtures, four, best captured by the full
model.

public tweets), and exclusive ones are defined as those whose hashtag never appeared in the

previous (August 2014) and the next (October 2014) month.

Inspired by previous studies that aimed at finding how many types of different

conversations occur on Twitter (Kwak et al., 2010; Lehmann et al., 2012), we characterize

our discussions according to three features: the proportion pb of tweets produced within

the conversation before its peak, the proportion pd of tweets produced during the peak,

and finally the proportion pa of tweets produced after the peak. The peak of popularity

of the conversation is simply the day which exhibits the maximum number of tweets

with that given hashtag. We use the Expectation Maximization (EM) algorithm to learn

an optimal Gaussian Mixture Model (GMM) in the (pb,pa) space. To determine the

appropriate number of components (i.e., the number of types of conversations), we adopt

three GMM models (spherical, diagonal, and full) and perform a 5-fold cross-validation

using the Bayesian Information Criterion (BIC) as quality measure. We vary the number of

components from 1 to 6. Figure 3B shows the BIC scores for different number of mixtures:

the lower the BIC score, the better. The outcome of this process determines that the

optimal number of components is four, in agreement with previous studies (Lehmann

et al., 2012), as captured the best by the full GMM model. In Fig. 3A we show the optimal

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Figure 4 Example of four types of Twitter conversations reflecting the respective dynamical classes
in our dataset. (A) shows one example of anticipatory discussion (#TENNvsOU); (B) an unexpected
event (#MileyPor40Principales); (C) a symmetric discussion (#PrayForRise); and (D) a transient event
(#KDWBmeetEd).

GMM that identifies the four classes of conversation: the two dimensions represent the

proportion pb of tweets occurring before (y axis) and pa after (x axis) the peak of popularity

of each conversation.

The four classes correspond to: (i) anticipatory discussions (blue dots), (ii) unexpected

events (green), (iii) symmetric discussions (red), and (iv) transient events (black). Antici-

patory conversations (blue) exhibit most of the activity before and during the peak. These

discussions build up over time registering an anticipatory behavior of the audience, and

quickly fade out after the peak. The complementary behavior is exhibited by discussions

around unexpected events (green dots): the peak is reached suddenly as a reaction to some

exogenous event, and the discussion quickly decays afterwards. Symmetric discussions

(red dots) are characterized by a balanced number of tweets produced before, during,

and after the peak time. Finally, transient discussions (black dots) are typically bursty

but short events that gather a lot of attention, yet immediately phase away afterwards.

According to this classification, out of 1,522 active and exclusive conversations (hashtags)

observed in September 2014, we obtained 64 hashtags of class A (anticipatory), 156 of class

B (unexpected), 56 of class C (symmetric), and 1,246 of class D (transient), respectively.

Figure 4 shows examples representing the four dynamical classes of conversations

registered in our dataset. The conversation lengths are all set to 7 days, and centered at

the peak day (time window 0).

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Figure 4A represents an example of anticipatory discussion: the event captured (#TEN-

NvsOU) is the football game Tennessee Volunteers vs. Oklahoma Sooners of Sept. 13, 2014.

The anticipatory nature of the discussion is captured by the increasing amount of tweets

generated before the peak (time window 0) and by the drastic drop afterwards. Figure 4B

shows an example (#MileyPor40Principales) of discussion around an unexpected event,

namely the release by Los 40 Principales of an exclusive interview to Miley Cyrus, on Sept.

10, 2014. There is no activity before the peak point, that is reached immediately the day

of the news release, and after that the volume of discussion decreases rapidly. Figure 4C

represents the discussion of a symmetric event: #PrayForRise was a hashtag adopted to

support RiSe, the singer of the K-pop band Ladies’ Code, who was involved in a car accident

that eventually caused her death. The symmetric activity of the discussion perfectly reflects

the events1: the discussion starts the day of the accident, on September 3, 2014, and peaks

1 Wikipedia: Ladies’ Code— http://en.
wikipedia.org/wiki/Ladies%27 Code.

the day of RiSe’s death (after four days from the accident, on September 7, 2014), but

the fans’ conversation stays alive to commemorate her for several days afterwards. Lastly,

Fig. 4D shows one example (#KDWBmeetEd) of transient event, namely the radio station

KDWB announcing a lottery drawing of the tickets for Ed Sheeran’s concert, on Sept. 15,

2014. The hype is momentarily and the discussion fades away immediately after the lottery

is concluded.

Figure 5 shows the evolution of sentiment for the four classes of Twitter conversations:

it can be useful to remind the average proportions of neutral (42.46%), positive

(35.95%), and negative (21.59%) sentiments in our dataset, to compare them against

the distributions for popular discussions. Also worth noting, although each discussion

is hard-cast in a class (anticipatory, unexpected, symmetric, or transient), sometimes

spurious content might appear before or after the peak, causing the presence of some small

amount of tweets where ideally we would not expect any (for example, some tweets appear

after the peak of an anticipatory discussion). We grayed out the bars in Figs. 5A, 5B and

5D, to represent non-significant amounts of tweets that are present only as byproduct

of averaging across all conversations belonging to each specific class. These intervals

therefore do not convey any statistically significant information and are disregarded.

(A) For anticipatory events, the amount of positive sentiment grows steadily until the

peak time, while the negative sentiment is somewhat constant throughout the entire

anticipatory phase. Notably, the amount of negative content is much below the dataset

average, fluctuating between 9% and 12% (almost half of the dataset average), while

the positive content is well above average, ranging between 40% and 44%. This suggests

that, in general, anticipatory popular conversations are emotionally positive. (B) The

class of unexpected events intuitively carries more negative sentiment, that stays constant

throughout the entire discussion period to levels of the dataset average. (C) Symmetric

popular discussions are characterized by a steadily decreasing negative emotions, that goes

from about 23% (above dataset’s average) at the inception of the discussions, to around

12% toward the end of the conversations. Complementary behavior happens for positive

emotions, that start around 35% (equal to the dataset average) and steadily grow up to

45% toward the end. This suggests that in symmetric conversations there is a general

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Figure 5 Evolution of positive and negative sentiment for different types of Twitter conversations. The
four panels show the average distribution of tweet proportion, and the average positive (S ≥ 1) and
negative (S ≤ −1) tweet proportions, for the four classes respectively: (A) anticipatory discussion;
(B) unexpected event; (C) symmetric discussion; and, (D) transient discussion.

shift of emotions toward positiveness over time. (D) Finally, transient events, due to their

short-lived lengths, represent more the average discussions, although they exhibit lower

levels of negative sentiments (around 15%) and higher levels of positive ones (around

40%) with respect to the dataset’s averages.

DISCUSSION
The ability to computationally annotate at scale the emotional value of short pieces of text,

like tweets, allowed us to investigate the role that emotions and sentiment expressed into

social media content plays with respect to the diffusion of such information.

Our first finding in this study sheds light on how sentiment correlates with the speed

and the reach of the diffusion process: tweets with negative emotional valence spread faster

than neutral and positive ones. In particular, the time that passes between the publication

of the original post and the first retweet is almost twice as much, on average, for positive

tweets than for negative ones. This might be interpreted in a number of ways, the most

likely being that content that conveys negative sentiments trigger stronger reactions in the

readers, some of which might be more prone to share that piece of information with higher

chance than any neutral or positive content. However, the positivity bias (or Pollyanna

effect) (Garcia, Garas & Schweitzer, 2012; Boucher & Osgood, 1969) rapidly kicks in when

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we analyze how many times the tweets become retweeted or favorited: individuals online

clearly tend to prefer positive tweets, which are favorited as much as five times more than

negative or neutral ones; the same holds true for the amount of retweets collected by

positive posts, which is up to 2.5 times more than negative or neutral ones. These insights

provide some clear directives in terms of best practices to produce popular content: if one

aims at triggering a quick reaction, negative sentiments outperform neutral or positive

emotions. This is the reason why, for example, in cases of emergencies and disasters,

misinformation and fear spread so fast in online environments (Ferrara et al., 2014).

However, if one aims at long-lasting diffusion, then positive content ensures wide reach

and the most preferences.

The second part of our study focuses on entire conversations, and investigates

how different sentiment patterns emerge from discussions characterized by different

temporal signatures (Kwak et al., 2010; Lehmann et al., 2012): we discover that, in general,

highly-anticipated events are characterized by positive sentiment, while unexpected events

are often harbingers of negative emotions; yet, transient events, whose duration is very

brief, represent the norm on social media like Twitter and are not characterized by any

particular emotional valence. These results might sound unsurprising, yet they have not

been observed before: common sense would suggest, for example, that unprecedented

conversations often relate to unexpected events, such as disasters, emergencies, etc.,

that canalize vast negative emotions from the audience, including fear, sorrow, grief,

etc. (Sakaki, Okazaki & Matsuo, 2010). Anticipated conversations instead characterize

events that will occur in the foreseeable future, such as a political election, a sport

match, a movie release, an entertainment event, or a recurring festivity: such events

are generally positively received, yet the attention toward them quickly phases out after

their happening (Lehmann et al., 2012; Mestyán, Yasseri & Kertész, 2013; Le, Ferrara &

Flammini, 2015). Elections and sport events might represent special cases, as they might

open up room for debate, “flames”, polarized opinions, etc. (Ratkiewicz et al., 2011; Bond

et al., 2012) (such characteristics have indeed been exploited to make predictions (Asur &

Huberman, 2010; Metaxas & Mustafaraj, 2012; Le, Ferrara & Flammini, 2015)).

The findings of this paper have very practical consequences that are relevant both for

economic and social impact: understanding the dynamics of information diffusion and

the effect of sentiment on such phenomena becomes crucial if one, for example, wants to

craft a policy to effectively communicate with an audience. The applications range from

advertisement and marketing, to public policy and emergency management. Recent events,

going for tragic episodes of terrorism, to the emergence of pandemics like Ebola, have

highlighted once again how central social media are in the timely diffusion of information,

yet how dangerous they can be when they are abused or misused to spread misinformation

or fear. Our contribution pushes forward previous studies on sentiment and information

diffusion (Dang-Xuan & Stieglitz, 2012) and furthers our understanding of how the

emotions expressed in a short piece of text might correlated with its spreading in online

social ecosystems, helping to craft effective information diffusion strategies that account

for the emotional valence of the content.

Ferrara and Yang (2015), PeerJ Comput. Sci., DOI 10.7717/peerj-cs.26 10/15

https://peerj.com/computer-science/
http://dx.doi.org/10.7717/peerj-cs.26


ACKNOWLEDGEMENTS
EF is grateful to Filippo Menczer, YY Ahn, Sune Lehmann, and Johan Bollen for interesting

discussions, and to Alessandro Flammini and Lorenzo Coviello for their precious feedback

on the project and extensive comments on the manuscript.

ADDITIONAL INFORMATION AND DECLARATIONS

Funding
EF was partly supported by ONR grant no. N15A-020-0053. ZY was partly supported by

NSF grant no. IIS-0811994. The funders had no role in study design, data collection and

analysis, decision to publish, or preparation of the manuscript.

Grant Disclosures
The following grant information was disclosed by the authors:

ONR: N15A-020-0053.

NSF: IIS-0811994.

Competing Interests
The authors declare there are no competing interests.

Author Contributions
• Emilio Ferrara conceived and designed the experiments, performed the experiments,

analyzed the data, contributed reagents/materials/analysis tools, wrote the paper,

prepared figures and/or tables, performed the computation work, reviewed drafts of

the paper.

• Zeyao Yang performed the experiments, analyzed the data, prepared figures and/or

tables, performed the computation work.

Data Availability
The following information was supplied regarding data availability:

Data was collected through the public Twitter API (https://dev.twitter.com/overview/

api). To comply with Twitter terms of service, data cannot be publicly shared. Interested

future researchers may reproduce the experiments by following the procedure described

in the paper. Anonymized data may be available upon request from Dr. Emilio Ferrara

(ferrarae@isi.edu).

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	Quantifying the effect of sentiment on information diffusion in social media
	Introduction
	Materials and Methods
	Sentiment analysis
	Data

	Results
	The role of sentiment on information diffusion
	Conversations' dynamics and sentiment evolution

	Discussion
	Acknowledgements
	References