The Effects of Semantic Similarity and Emotion on False Memory
Production
Yingcheng He
Queen Mary School of Jiangxi Medical college, Nanchang University, Nanchang, 330031, China
Keywords: False Memory, Semantic Similarity, Emotional Valence.
Abstract: False memory is a long-term memory phenomenon when people report past events differently from the facts.
Scientists have been interested in the generation of false memory and numerous studies demonstrated that a
region in temporal pole called “semantic hub” of the brain is the origin of false memory induced by semantic
similarity among different concepts. According to this neural mechanism, auditorily-presented behavior task
and visually-presented retrieval task were conducted and the first hypothesis that semantic similarity promotes
false memory generation was confirmed. Additionally, this research aimed to compare the difference between
the influence caused by positive words and negative words on false memory. However, the result was not
consistent with the second hypothesis that negatively-valenced concepts induce more false memory than
positively-valenced ones. Therefore, the effect of emotion to memory distortion requires further investigation
while this paper may provide novel insight into the relationship between false memory and emotion.
1 INTRODUCTION
False memory is a long-term memory phenomenon
where one recalls something that did not happen or
recall it from a different way compared to the truth
(Henry, Roediger, Elizabeth 2009). There are
numerous factors influencing the generation of false
memory and one of the most significant is similarity
between new items and past events. In this condition,
people may incorrectly consider new items as old
things as they are very similar. Among various kinds
of similarity, in recent decades, scientists have
explored more about the relationship between
semantic similarity and false memory production.
Chadwick MJ et al. demonstrated that false memories
originate from a region known as the “semantic hub”
of the brain, which is a similarity-based neural code
in the temporal pole. Further, they found that the
degree of semantic similarity between different
events can be reflected by the extent of overlap
among neural representations of relevant concepts in
the neural code and this neural overlap predicts the
probability of false memory generation (Chadwick,
Anjum, Kumaran, Schacter, Spiers, Hassabis, 2016).
Another research indicates that in the recognition task
showing new words to participants, words of high-
similarity with old concepts had remarkably higher
likelihood to be improperly recalled as old compared
with low-similarity words, even after excluding out
the influence of lexical co-occurrence and associative
relatedness (Montefinese, Zannino, Ambrosini
2015). A 2016 study showes the neural mechanism of
false memory generation is both true and false
memories emerge. (Ye, Zhu, Zhuang, Lu, Chen, Xue
2016). In addition to the origin of false memory, the
effects of emotion on false memories are gaining
increased attention. This is usually reflected by the
impact of words’ valence on the strength of false
memories. For instance, it was reported that the
increase of false memories was more pronounced
when subjects were instructed to memorize and then
recognize negatively-valenced words compared to
remembering and recognizing positively-valenced
words (Brainerd, Holliday, Reyna, Yang, Toglia
2010). Furthermore, research revealed that words of
negative emotional valence tend to induce more false
memories due to its automatic neural processing
while positive ones often produce less false memories
because the related neural processing is more
controlled (Knott, Howe, Toffalini, Shah,
Humphreys 2018).
In this study, we conducted auditorily-presented
behavior task and visually-presented retrieval task
online and used words with distinctive emotional
valences and semantic similarity to investigate the
He, Y.
The Effects of Semantic Similarity and Emotion on False Memory Production.
DOI: 10.5220/0011290900003444
In Proceedings of the 2nd Conference on Artificial Intelligence and Healthcare (CAIH 2021), pages 225-229
ISBN: 978-989-758-594-4
Copyright
c
2022 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
225
false memory production and its related effects
caused by semantic similarity and emotion. We put
forwarded two hypotheses. One is that semantic
similarity can affect long-term memory and produce
false memories and the other is that concepts of
negative emotional valence produce more false
memory than that of positive ones.
2 METHODS AND MATERIALS
2.1 Collect Personal Information
We collected information of 30 subjects aged from 17
to 24, with the basic education level being high
school. Among the 30 subjects, 15 people are females
and 15 people are males. The information includes
gender, education background and age.
2.2 Behavioral Task: Verbal Memory
Task Presented Auditorily
Participants are native Chinese speakers and they
were instructed to memorize a set of 80 Chinese two-
character words (8 separate lists of 10 words each).
The words are broadcast in an audio file in sequence
and the time for each word is 2 seconds (includes the
time for broadcasting and the interval time). The total
time for memorizing is approximately 4 minutes.
These words were selected from the
Cornell/Cortland emotional list (Chang, Brainerd,
Toglia, Schmidt 2010) consisting of 32 DRM
(Deese–Roediger–McDermott) lists which are
divided into four groups of lists: 8 positively-
valenced/ high arousal lists and 8 positively-
valenced/ low arousal lists, 8 negatively-valenced/
high arousal lists and 8 negatively-valenced/ low
arousal lists. The mean arousal among all the high-
arousal lists is not significantly different and the
mean arousal among all the low-arousal lists is also
not. In our 8 lists, 4 of them contain words with
positive valence and 4 with negative valence.
Within each emotion set (positive or negative), there
are 2 lists contain words with high arousal and the
other 2 lists contain words with low arousal. We
provide English translations for presentation
purposes and recorded all the words in an audio file.
2.3 Distraction Task (Non-Mneumonic)
After encoding, participants were instructed to
complete a non-mneumonic task that involves
mathematical computations. The questions are 58-
25=? and 23+19=? Participants were given 30
seconds to write down the answers in the chat box.
Performance was measured using accuracy.
Following the distraction task, a retrieval period was
conducted.
2.4 Retrieval Task
During retrieval, participants were visually presented
with 120 words (40 old, 40 lures, 40 foils), each
presented one at a time for 2 second. The lures are
selected from Cornell/Cortland emotional list. For
each category of words (old, lure, foil), half were
positive and the other half were negative. Participants
were asked to respond in a table format (Table 1) to
determine whether they had seen the word during
encoding. If the answer is yes, they were supposed to
type Chinese character “是” in the table and Chinese
character “否” is corresponding to “No”.
Table 1: Table for subjects to write down answers.
The number Use the drop-down button to fill in "yes" or "no".
1
…
120
2.5 Data Analysis
We calculated the percent correct of studied words
(the number of “yes” for old/ the number of all the old
words tested (i.e. 40)) and that of critical lures (the
number of “no” for lures/ the number of all the lures
tested (i.e. 40)). Similarly, the percent correct of
negative/ positive studied words and that of negative/
positive lures were calculated. In addition, corrected
false memory is also computed by subtracting foils
judged as old from lures judged as old and corrected
true memory is computed by subtracting foils judged
as old from studied words judged as old. Further, we
calculated corrected false and true memory rates in
positive and negative sets.
(eg: positive corrected false memory rate =
percent correct of foils in positive set minus percent
correct of positive lures)
CAIH 2021 - Conference on Artificial Intelligence and Healthcare
226
(eg: positive corrected true memory rate = percent
correct of positive studied words plus percent correct
of positive lures minus one.)
3 RESULTS
3.1 The Effect of Semantic Similarity
on False Memory Generation
Compared with that of critical lures, the percent
correct of studied words is significantly higher
(p<0.05) (Figure 1A). Further, we compared the
percent correct of positive studied words and that of
positive lures and the result is consistent (p<0.05)
(Figure 1B). We also compared the percent correct
of negative studied words and that of negative lures.
Figure 1C shows that the percent correct of negative
studied words is significantly higher than that of
negative lures (p<0.05). The results above
demonstrate that semantic similarity promotes false
memory production.
Figure 1: Semantic similarity.
3.2 The Effect of Emotional Valence on
False Memory Production
We compared the corrected true memory rate and
false memory rate between positive words and
negative words. T test indicates that there is no
significant difference between the corrected false
memory rate of positive words and that of negative
words (p>0.05). Likewise, no significant distinction
is shown between corrected true memory rate of
positive words and negative words (p>0.05) but this
value (p=0.057) is close to the significance threshold
(Figure 2).
Figure 2: Positive and negative valences.
The Effects of Semantic Similarity and Emotion on False Memory Production
227
4 DISCUSSIONS
Memory is the ability of brain to encode, store and
retrieve information and is also a result of learning,
perception and attention. A true memory is important
for solving problems and recognizing items.
However, memory is not always reliable. False
memory, a recollection that is fake partially or in
whole but seems real in someone’s mind, often occur
in people’s life, attracting many psychologists and
neuroscientists. There are various studies
demonstrating that the generation of false memory is
related to neural overlap of neural representations of
related concepts. For instance, the similarity between
new items and past experiences increases the cortical
similarity, eventually leading to false memory (Wing,
Geib, Wang, Monge, Davis, Cabeza 2020).
Additionally, the same research revealed that the
false memory for a given concept’s lure tended to
reduce when high similarity in cortical region was
coexist with differentiated hippocampal patterns,
which suggests that hippocampus plays a crucial role
in discriminating similar concepts during encoding
and retrieval and its interaction with cortex
determines whether a similar lure will be incorrectly
recognized as old (Wing, Geib, Wang, Monge, Davis,
Cabeza 2020). Coane JH et al. found that false
identification of critical lures was significantly
greater after studying the word lists that have similar
characteristics with the critical lures, which indicates
that similarity at a taxonomic or categorical level
induces false memory (Coane, McBride, Termonen,
Cutting 2016). Our results show that semantic
similarity between different concepts increases false
memory production, which is demonstrated by the
higher percent correct of studied words than that of
critical lures. Specifically, the percent correct of
positive studied words is also higher than that of
positive critical lures and the same result is for
negative words. Therefore, our results are consistent
with previous studies.
However, we did not find a significant difference
between the influence of positively-valenced words
and that of negatively-valenced words in false
memory production. Our results indicate that there is
no significant distinction between positive and
negative corrected false memory rates. Besides, no
significant difference was identified between positive
and negative correct true memory rates, though the p
value is close to the significance threshold. We think
that this result may be attributed to the distinctive
effects of emotion on false memory depending on
whether the emotion is in the content of items to be
memorized or in the participants’ moods reflecting
the context during encoding. A previous study found
that negatively-valenced concepts induce memory
distortion and cause false memory while negatively-
valenced moods keep memory from being distorted.
Moreover, enduring negative moods promotes false
memory production (Bookbinder, Brainerd, 2016).
Therefore, in our experiment, presenting words with
negative emotion may foment negative moods in
subjects and this effect may counteract the influence
of negative concepts in increasing false memory. As
a result, no significant difference can be found
between false or true memory rates of positive and
negative words.
There are several limitations in our research,
among which the most important is latency caused by
network and personal affairs as our experiment was
conducted online. For instance, after encoding,
subjects are supposed to take the distraction test
immediately but due to the network he or she may not
be able to see the math questions until several
minutes, which greatly influences the memory
encoding. Also, retrieval task may be interrupted by
trifles happening around the subject’s environment
(eg. someone knocks at the door and the subject needs
to stop watching the recognition video to open the
door). Another disadvantage is that semantic
similarity across lists may disturb our research
exploring the effect of semantic similarity of each
single list on false memory generation. Additionally,
how to properly control variables when investigating
the influence of emotion in false memory production
remains elusive.
Based on the limitations above, we came up with
several ideas to be realized in our future research.
First of all, conducting the experiment offline and in
this way, subjects tend to be more controlled, which
can decrease disturbances and enhance seriousness.
Second, we will re-select the words for encoding and
retrieval and reduce the semantic similarity across
lists to as small as possible. Third, as previous
research also suggested the effect of stimulus
modalities on false memory, we may alter the
encoding and retrieval modalities to explore the
difference between the influence of auditory and
visual modalities in memory distortion.
5 CONCLUSIONS
In summary, we conducted auditorily-presented
encoding task and visually-presented retrieval task
using words with different emotions and
demonstrated that semantic similarity of similar
concepts promotes false memory generation.
CAIH 2021 - Conference on Artificial Intelligence and Healthcare
228
However, the enhancement effect of negatively
emotional words on false memory production was not
verified but this paper offers new ideas about the
correlation between emotion and false memory
generation and further investigation is required.
REFERENCES
Bookbinder SH, Brainerd CJ. Emotion and false memory:
The context-content paradox. (2016) Psychol Bull.
142(12):1315-1351.
Brainerd CJ, Holliday RE, Reyna VF, Yang Y, Toglia MP.
(2010) Developmental reversals in false memory:
Effects of emotional valence and arousal. J Exp Child
Psychol. 107(2):137-54.
Chadwick MJ, Anjum RS, Kumaran D, Schacter DL, Spiers
HJ, Hassabis D. (2016) Semantic representations in the
temporal pole predict false memories. Proc Natl Acad
Sci U S A. 113(36):10180-5.
Chang M, Brainerd CJ, Toglia MP, Schmidt SR. (2010)
Norms for emotion-false memory lists. Behav Res
Methods. 53(1):96-112.
Coane JH, McBride DM, Termonen ML, Cutting JC.
(2016) Categorical and associative relations increase
false memory relative to purely associative relations.
Mem Cognit. 44(1):37-49.
Henry L. Roediger III, Elizabeth J. (2009). False memory.
http://www.scholarpedia.org/article/False_memory
Knott LM, Howe ML, Toffalini E, Shah D, Humphreys L.
(2018) The role of attention in immediate emotional
false memory enhancement. Emotion. 18(8):1063-
1077.
Montefinese M, Zannino GD, Ambrosini E. (2015)
Semantic similarity between old and new items
produces false alarms in recognition memory. Psychol
Res. 79(5):785-94.
Wing EA, Geib BR, Wang WC, Monge Z, Davis SW,
Cabeza R. (2020) Cortical overlap and cortical-
hippocampal interactions predict subsequent true and
false Memory. J Neurosci. 40(9):1920-1930.
Ye Z, Zhu B, Zhuang L, Lu Z, Chen C, Xue G. (2016)
Neural global pattern similarity underlies true and false
memories. J Neurosci. 36(25):6792-802.
The Effects of Semantic Similarity and Emotion on False Memory Production
229
