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Eureka effect

April 11, 2024

The eureka effect (also known as the Aha! moment or eureka moment) refers to the common human experience of suddenly understanding a previously incomprehensible problem or concept. Some research describes the Aha! effect (also known as insight or epiphany) as a memory advantage,[1][2] but conflicting results exist as to where exactly it occurs in the brain, and it is difficult to predict under what circumstances one can predict an Aha! moment.

A 16th century woodcut of Archimedes' eureka moment

Insight is a psychological term that attempts to describe the process in problem solving when a previously unsolvable puzzle becomes suddenly clear and obvious. Often this transition from not understanding to spontaneous comprehension is accompanied by an exclamation of joy or satisfaction, an Aha! moment.[citation needed] A person utilizing insight to solve a problem is able to give accurate, discrete, all-or-nothing type responses, whereas individuals not using the insight process are more likely to produce partial, incomplete responses.[3]

A recent theoretical account of the Aha! moment started with four defining attributes of this experience. First, the Aha! moment appears suddenly; second, the solution to a problem can be processed smoothly, or fluently; third, the Aha! moment elicits positive affect; fourth, a person experiencing the Aha! moment is convinced that a solution is true. These four attributes are not separate but can be combined because the experience of processing fluency, especially when it occurs surprisingly (for example, because it is sudden), elicits both positive affect and judged truth.[4][5]

Insight can be conceptualized as a two phase process. The first phase of an Aha! experience requires the problem solver to come upon an impasse, where they become stuck and even though they may seemingly have explored all the possibilities, are still unable to retrieve or generate a solution. The second phase occurs suddenly and unexpectedly. After a break in mental fixation or re-evaluating the problem, the answer is retrieved.[6] Some research suggest that insight problems are difficult to solve because of our mental fixation on the inappropriate aspects of the problem content.[7] In order to solve insight problems, one must "think outside the box". It is this elaborate rehearsal that may cause people to have better memory for Aha! moments. Insight is believed to occur with a break in mental fixation, allowing the solution to appear transparent and obvious.

History and etymology edit

The effect is named from a story about ancient Greek polymath Archimedes. In the story, Archimedes was asked (c. 250 BC) by the local king to determine whether a crown was pure gold. During a subsequent trip to a public bath, Archimedes noted that water was displaced when his body sank into the bath, and particularly that the volume of water displaced equaled the volume of his body immersed in the water. Having discovered how to measure the volume of an irregular object, and conceiving of a method to solve the king's problem, Archimedes allegedly leaped out and ran home naked, shouting εὕρηκα (eureka, "I have found it!"). This story is now thought to be fictional, because it was first mentioned by the Roman writer Vitruvius nearly 200 years after the date of the alleged event, and because the method described by Vitruvius would not have worked.[8] However, Archimedes certainly did important, original work in hydrostatics, notably in his On Floating Bodies.

Research edit

Initial research edit

Research on the Aha! moment dates back more than 100 years, to the Gestalt psychologists' first experiments on chimpanzee cognition.[9] In his 1921 book,[9] Wolfgang Köhler described the first instance of insightful thinking in animals: One of his chimpanzees, Sultan, was presented with the task of reaching a banana that had been strung up high on the ceiling so that it was impossible to reach by jumping. After several failed attempts to reach the banana, Sultan sulked in the corner for a while, then suddenly jumped up and stacked a few boxes upon each other, climbed them and thus was able to grab the banana. This observation was interpreted as insightful thinking. Köhler's work was continued by Karl Duncker and Max Wertheimer.

The Eureka effect was later also described by Pamela Auble, Jeffrey Franks and Salvatore Soraci in 1979. The subject would be presented with an initially confusing sentence such as "The haystack was important because the cloth ripped". After a certain period of time of non-comprehension by the reader, the cue word (parachute) would be presented, the reader could comprehend the sentence, and this resulted in better recall on memory tests.[2] Subjects spend a considerable amount of time attempting to solve the problem, and initially it was hypothesized that elaboration towards comprehension may play a role in increased recall. There was no evidence that elaboration had any effect for recall. It was found that both "easy" and "hard" sentences that resulted in an Aha! effect had significantly better recall rates than sentences that subjects were able to comprehend immediately. In fact equal recall rates were obtained for both "easy" and "hard" sentences which were initially noncomprehensible. It seems to be this noncomprehension to comprehension which results in better recall. The essence of the aha feeling underlining insight problem solving was systemically investigated by Danek et al.[10] and Shen and his colleagues.[11] Recently an attempt has been made in trying to understand the neurobiological basis of Eureka moment.[12]

How people solve insight problems edit

Currently there are two theories for how people arrive at the solution for insight problems. The first is the progress monitoring theory.[13] The person will analyze the distance from their current state to the goal state. Once a person realizes that they cannot solve the problem while on their current path, they will seek alternative solutions. In insight problems this usually occurs late in the puzzle. The second way that people attempt to solve these puzzles is the representational change theory.[14] The problem solver initially has a low probability for success because they use inappropriate knowledge as they set unnecessary constraints on the problem. Once the person relaxes his or her constraints, they can bring previously unavailable knowledge into working memory to solve the problem. The person also utilizes chunk decomposition, where he or she will separate meaningful chunks into their component pieces. Both constraint relaxation and chunk decomposition allow for a change in representation, that is, a change in the distribution of activation across working memory, at which point they may exclaim, "Aha!" Currently both theories have support, with the progress monitoring theory being more suited to multiple step problems, and the representational change theory more suited to single step problems.[15]

The Eureka effect on memory occurs only when there is an initial confusion.[16] When subjects were presented with a clue word before the confusing sentence was presented, there was no effect on recall. If the clue was provided after the sentence was presented, an increase in recall occurred.

Memory edit

It had been determined that recall is greater for items that were generated by the subject versus if the subject was presented with the stimuli.[2] There seems to be a memory advantage for instances where people are able to produce an answer themselves, recall was higher when Aha! reactions occurred.[2] They tested sentences that were initially hard to understand, but when presented with a cued word, the comprehension became more apparent. Other evidence was found indicating that effort in processing visual stimuli was recalled more frequently than the stimuli that were simply presented.[17] This study was done using connect-the-dots or verbal instruction to produce either a nonsense or real image. It is believed that effort made to comprehend something when encoding induces activation of alternative cues that later participate in recall.[18]

Cerebral lateralization edit

See also: Lateralization of brain function

Functional magnetic resonance imaging and electroencephalogram studies[19] have found that problem solving requiring insight involves increased activity in the right cerebral hemisphere as compared with problem solving not requiring insight. In particular, increased activity was found in the right hemisphere anterior superior temporal gyrus.

Sleep edit

Some unconscious processing may take place while a person is asleep, and there are several cases of scientific discoveries coming to people in their dreams. Friedrich August Kekulé von Stradonitz claimed that the ring structure of benzene came to him in a dream where a snake was eating its own tail.[20] Studies have shown increased performance at insight problems if the subjects slept during a break between receiving the problem and solving it. Sleep may function to restructure problems, and allow new insights to be reached.[21] Henri Poincaré stated that he valued sleep as a time for "unconscious thought" that helped him break through problems.[citation needed]

Other theories edit

Professor Stellan Ohlsson believes that at the beginning of the problem-solving process, some salient features of the problem are incorporated into a mental representation of the problem. In the first step of solving the problem, it is considered in the light of previous experience. Eventually, an impasse is reached, where all approaches to the problem have failed, and the person becomes frustrated. Ohlsson believes that this impasse drives unconscious processes which change the mental representation of a problem, and cause novel solutions to occur.[20]

General procedure for conducting ERP and EEG studies edit

When studying insight, or the Aha! effect, ERP or EEG general methods are used. Initially a baseline measurement is taken, which generally asks the subject to simply remember an answer to a question. Following this, subjects are asked to focus on the screen while a logogriph is shown, and then they are given time with a blank screen to get the answer, once they do they are required to press a key. After which the answer appears on the screen. The subjects are then asked to press one key to indicate that they thought of the correct answer and another to indicate if they got the answer wrong, finally, not to press a key at all if they were unsure or did not know the answer.

Evidence in EEG studies edit

Resting-state neural activity has a standing influence on cognitive strategies used when solving problems, particularly in the case of deriving solutions by methodical search or by sudden insight.[3] The two cognitive strategies used involve both search and analysis of current state of a problem, to the goal state of that problem, while insight problems are a sudden awareness of the solution to a problem.[3]

Subjects studied were first recorded on the base-line resting state of thinking. After being tested using the method described in the General Procedure for Conducting ERP and EEG Studies, the ratio of insight versus non-insight solution were made to determine whether an individual is classified as a high insight (HI) or a low insight (LI) individual. Discriminating between HI and LI individuals were important as both groups use different cognitive strategies to solve anagram problems used in this study.[3] Right hemisphere activation is believed to be involved in Aha! effects,[22] so it comes as no surprise that HI individuals would show greater activation in the right hemisphere than the left hemisphere when compared to the LI individuals. Evidence was found to support this idea, there was greater activation in HI subjects at the right dorsal-frontal (low-alpha band), right inferior-frontal (beta and gamma bands) and the right parietal (gamma band) areas.[3] As for LI subjects, left inferior-frontal and left anterior-temporal areas were active (low-alpha band).

There were also differences in attention between individuals of HI and LI. It has been suggested that individuals who are highly creative exhibit diffuse attention, thus allowing them a greater range of environmental stimuli.[23] It was found that individuals who displayed HI would have less resting state occipital alpha-band activity, meaning there would be less inhibition of the visual system.[3] Individuals that were less creative were found to focus their attention, thus causing them to sample less of their environment.[23] Although, LI individuals were shown to have more occipital beta activity, consistent with heightened focused attention.[3]

Evidence in ERP studies edit

Source localization is hard in ERP studies, and it may be difficult to distinguish signals of insight from signals of the existing cognitive skills it builds on or the unwarranted mental fixation it breaks, but the following conclusions have been offered.

One study found that "Aha" answers produced more negative ERP results, N380 in the ACC, than the "No-Aha" answers, 250–500 ms, after an answer was produced.[7] The authors suspected that this N380 in the ACC is a sign of breaking the mental set, and reflects the Aha! effect. Another study was done showed that an Aha! effect elicited an N320 in the central-posterior region.[24] A third study, by Qiu and Zhang (2008), found that there was a N350 in the posterior cingulate cortex for successful guessing, not in the anterior cingulate cortex. The posterior cingulate cortex seems to play a more non-executive function in monitoring and inhibiting the mind set and cognitive function.[6]

Another significant finding of this study was a late positive component (LPC) in successful guessing and then recognition of the answer at 600 and 700 ms, post-stimulus, in the parahippocampal gyrus (BA34). The data suggests that the parahippocampus is involved in searching for a correct answer by manipulating it in working memory, and integrating relationships. The parahippocampal gyrus may reflect the formation of novel associations while solving insight problems.

A fourth ERP study is fairly similar, but this study claims to have anterior cingulate cortex activation at N380, which may be responsible for the mediation of breaking the mental set. Other areas of interest were prefrontal cortex (PFC), the posterior parietal cortex, and the medial temporal lobe. If subjects failed to solve the riddle, and then were shown the correct answer, they displayed the feeling of insight, which was reflected on the electroencephalogram recordings.

Evidence in fMRI studies edit

A study with the goal of recording the activity that occurs in the brain during an Aha! moment using fMRIs was conducted in 2003 by Jing Luo and Kazuhisa Niki. Participants in this study were presented with a series of Japanese riddles, and asked to rate their impressions toward each question using the following scale: (1) I can understand this question very well and know the answer; (2) I can understand this question very well and feel it is interesting, but I do not know the answer; or (3) I cannot understand this question and do not know the answer.[25] This scale allowed the researchers to only look at participants who would experience an Aha! moment upon viewing the answer to the riddle. In previous studies on insight, researchers have found that participants reported feelings of insight when they viewed the answer to an unsolved riddle or problem.[25] Luo and Niki had the goal of recording these feelings of insight in their participants using fMRIs. This method allowed the researchers to directly observe the activity that was occurring in the participant's brains during an Aha! moment.

An example of a Japanese riddle used in the study: The thing that can move heavy logs, but cannot move a small nailA river.[25]

Participants were given 3 minutes to respond to each riddle, before the answer to the riddle was revealed. If the participant experienced an Aha! moment upon viewing the correct answer, any brain activity would be recorded on the fMRI.[25] The fMRI results for this study showed that when participants were given the answer to an unsolved riddle, the activity in their right hippocampus increased significantly during these Aha! moments. This increased activity in the right hippocampus may be attributed to the formation of new associations between old nodes.[25] These new associations will in turn strengthen memory for the riddles and their solutions.

Although various studies using EEGs, ERPs, and fMRI's report activation in a variety of areas in the brain during Aha! moments, this activity occurs predominantly in the right hemisphere. More details on the neural basis of insight see a recent review named "New advances in the neural correlates of insight: A decade in review of the insightful brain[26]"

Insight problems and problems with insight edit

Insight problems edit

The Nine Dot Problem edit

 
The Nine Dot Problem with solution. Most individuals fail to draw lines beyond the dots that compose the square, and are unable to solve this puzzle.

The Nine Dot Problem is a classic spatial problem used by psychologists to study insight. The problem consists of a 3 × 3 square created by 9 black dots. The task is to connect all 9 dots using exactly 4 straight lines, without retracing or removing one's pen from the paper. Kershaw & Ohlsson[27] report that in a laboratory setting with a time limit of 2 or 3 minutes, the expected solution rate is 0%.

The difficulty with the Nine Dot Problem is that it requires respondents to look beyond the conventional figure-ground relationships that create subtle, illusory spatial constraints and (literally) "think outside of the box". Breaking the spatial constraints shows a shift in attention in working memory and utilizing new knowledge factors to solve the puzzle.

Verbal riddles edit

Verbal riddles are becoming popular problems in insight research.

Example: "A man was washing windows on a high-rise building when he fell from the 40-foot ladder to the concrete path below. Amazingly, he was unhurt. Why? [Answer] He slipped from the bottom rung!"

Matchstick arithmetic edit

A subset of matchstick puzzles, matchstick arithmetic, which was developed and used by G. Knoblich,[28] involves matchsticks that are arranged to show a simple but incorrect math equation in Roman numerals. The task is to correct the equation by moving only one matchstick.

 
Two examples of matchstick arithmetic problems

Anagrams edit

Anagrams involve manipulating the order of a given set of letters in order to create one or many words. The original set of letters may be a word itself, or simply a jumble.

Example: Santa can be transformed to spell Satan.

Rebus puzzles edit

Rebus puzzles, also called "wordies", involve verbal and visual cues that force the respondent to restructure and "read between the lines" (almost literally) to solve the puzzle.

Some examples:

  1. Puzzle: you just me [Answer: just between you and me]
  2. Puzzle: PUNISHMENT [Answer: capital punishment]
  3. Puzzle:
 i i i 
 OOOOO

[Answer: circles under the eyes]

Remote Associates Test (RAT) edit

Main article: Remote Associates Test

The Remote Associates Test (known as the RAT) was developed by Martha Mednick in 1962[29] to test creativity. However, it has recently been utilized in insight research.

The test consists of presenting participants with a set of words, such as lick, mine, and shaker. The task is to identify the word that connects these three seemingly unrelated ones. In this example, the answer is salt. The link between words is associative, and does not follow rules of logic, concept formation or problem solving, and thus requires the respondent to work outside of these common heuristical constraints.

Performance on the RAT is known to correlate with performance on other standard insight problems.[30]

The Eight Coin Problem edit

In this problem a set of 8 coins is arranged on a table in a certain configuration, and the subject is told to move 2 coins so that all coins touch exactly three others. The difficulty in this problem comes from thinking of the problem in a purely 2-dimensional way, when a 3-dimensional approach is the only way to solve the problem.[31]

Problems with insight edit

Insight research is problematic because of the ambiguity and lack of agreement among psychologists of its definition.[32] This could largely be explained by the phenomenological nature of insight, and the difficulty in catalyzing its occurrence, as well as the ways in which it is experimentally "triggered".

 
Example of a puzzle that requires an insight from the solver. Asked what goes in the blank square, and told that it is not the number six, the solver must realise that the image represents a gear stick and the answer is "R" for "Reverse".[33]

The pool of insight problems currently employed by psychologists is small and tepid, and due to its heterogeneity and often high difficulty level, is not conducive of validity or reliability.

One of the biggest issues surrounding insight problems is that for most participants, they are simply too difficult. For many problems, this difficulty revolves around the requisite restructuring or re-conceptualization of the problem or possible solutions, for example, drawing lines beyond the square composed of dots in the Nine-Dot Problem.

Furthermore, there are issues related to the taxonomy of insight problems. Puzzles and problems that are utilized in experiments to elicit insight may be classified in two ways. "Pure" insight problems are those that necessitate the use of insight, whereas "hybrid" insight problems are those that can be solved by other methods, such as the trial and error.[34] As Weisberg (1996) points out, the existence of hybrid problems in insight research poses a significant threat to any evidence gleaned from studies that employ them. While the phenomenological experience of insight can help to differentiate insight-solving from non-insight solving (by asking the respondent to describe how they solved the problem, for example), the risk that non-insight solving has been mistaken for insight solving still exists. Likewise, issues surrounding the validity of insight evidence is also threatened by the characteristically small sample sizes. Experimenters may recruit an initially adequate sample size, but because of the level of difficulty inherent to insight problems, only a small fraction of any sample will successfully solve the puzzle or task given to them; placing serious limits on usable data. In the case of studies using hybrid problems, the final sample is at even greater risk of being very small by way of having to exclude whatever percentage of respondents solved their given puzzle without utilizing insight.

The Aha! effect and scientific discovery edit

There are several examples of scientific discoveries being made after a sudden flash of insight. One of the key insights in developing his special theory of relativity came to Albert Einstein while talking to his friend Michele Besso:

I started the conversation with him in the following way: "Recently I have been working on a difficult problem. Today I come here to battle against that problem with you." We discussed every aspect of this problem. Then suddenly I understood where the key to this problem lay. Next day I came back to him again and said to him, without even saying hello, "Thank you. I've completely solved the problem."[35]

However, Einstein has said that the whole idea of special relativity did not come to him as a sudden, single eureka moment,[36] and that he was "led to it by steps arising from the individual laws derived from experience".[36] Similarly, Carl Friedrich Gauss said after a eureka moment: "I have the result, only I do not yet know how to get to it."[36][37]

Sir Alec Jeffreys had a eureka moment in his lab in Leicester after looking at the X-ray film image of a DNA experiment at 9:05 am on Monday 10 September 1984, which unexpectedly showed both similarities and differences between the DNA of different members of his technician's family.[38][39] Within about half an hour, he realized the scope of DNA profiling, which uses variations in the genetic code to identify individuals. The method has become important in forensic science to assist detective work, and in resolving paternity and immigration disputes.[38] It can also be applied to non-human species, such as in wildlife population genetics studies. Before his methods were commercialised in 1987, Jeffreys' laboratory was the only centre carrying out DNA fingerprinting in the world.[citation needed]

See also edit

Notes edit

  1. ^ Danek AH, Fraps T, von Müller A, Grothe B, Ollinger M (September 2013). "Aha! experiences leave a mark: facilitated recall of insight solutions". Psychological Research. 77 (5): 659–69. doi:10.1007/s00426-012-0454-8. PMID 23007629. S2CID 26161927.
  2. ^ a b c d Auble P, Franks J, Soraci S (1979). "Effort toward comprehension: Elaboration or aha!?". Memory & Cognition. 7 (6): 426–434. doi:10.3758/bf03198259.
  3. ^ a b c d e f g Kounios J, Fleck JI, Green DL, Payne L, Stevenson JL, Bowden EM, Jung-Beeman M (January 2008). "The origins of insight in resting-state brain activity". Neuropsychologia. 46 (1): 281–91. doi:10.1016/j.neuropsychologia.2007.07.013. PMC 2293274. PMID 17765273.
  4. ^ Topolinski S, Reber R (2010). "Gaining insight into the "Aha"-experience". Current Directions in Psychological Science. 19 (6): 402–405. doi:10.1177/0963721410388803. S2CID 145057045.
  5. ^ Wray H (2011). "Aha! The 23-Across Phenomenon". APS Observer. 24: 1.
  6. ^ a b Qiu & Zhang (2008) "Aha! Effects in a Guessing Chinese Logograph Task: An Event-Related Potential Study. Chinese Science Bulletin. 53 (3), 384–391.
  7. ^ a b Mai XQ, Luo J, Wu JH, Luo YJ (August 2004). ""Aha!" effects in a guessing riddle task: an event-related potential study". Human Brain Mapping. 22 (4): 261–70. doi:10.1002/hbm.20030. PMC 6871977. PMID 15202104.
  8. ^ Fact or Fiction?: Archimedes Coined the Term "Eureka!" in the Bath, Scientific American
  9. ^ a b Köhler W (1921). Intelligenzprüfungen am Menschenaffen. Berlin: Springer.
  10. ^ Danek AH, Fraps T, von Müller A, Grothe B, Öllinger M (2014). "It's a kind of magic-what self-reports can reveal about the phenomenology of insight problem solving". Frontiers in Psychology. 5: 1408. doi:10.3389/fpsyg.2014.01408. PMC 4258999. PMID 25538658.
  11. ^ Shen W, Yuan Y, Liu C, Luo J (May 2016). "In search of the 'Aha!' experience: Elucidating the emotionality of insight problem-solving". British Journal of Psychology. 107 (2): 281–98. doi:10.1111/bjop.12142. PMID 26184903.
  12. ^ What causes Eureka Moment in the brain; South Asia Monitor, 12 December 2021
  13. ^ MacGregor JN, Ormerod TC, Chronicle EP (January 2001). "Information processing and insight: a process model of performance on the nine-dot and related problems". Journal of Experimental Psychology: Learning, Memory, and Cognition. 27 (1): 176–201. doi:10.1037/0278-7393.27.1.176. PMID 11204097.
  14. ^ Knoblich G, Ohlsson S, Raney GE (October 2001). "An eye movement study of insight problem solving". Memory & Cognition. 29 (7): 1000–9. doi:10.3758/bf03195762. PMID 11820744.
  15. ^ Jones G (September 2003). "Testing two cognitive theories of insight" (PDF). Journal of Experimental Psychology: Learning, Memory, and Cognition. 29 (5): 1017–27. doi:10.1037/0278-7393.29.5.1017. PMID 14516232.
  16. ^ Wills TW, Estow S, Soraci SA, Garcia J (July 2006). "The aha effect in groups and other dynamic learning contexts". The Journal of General Psychology. 133 (3): 221–36. doi:10.3200/genp.133.3.221-236. PMID 16937892. S2CID 45391625.
  17. ^ Peynircioglu, F (1989). "The generation effect with pictures and nonsense figures". Acta Psychologica. 70 (2): 153–160. doi:10.1016/0001-6918(89)90018-8.
  18. ^ Wills TW, Soraci SA, Chechile RA, Taylor HA (September 2000). ""Aha" effects in the generation of pictures". Memory & Cognition. 28 (6): 939–48. doi:10.3758/bf03209341. PMID 11105519.
  19. ^ Jung-Beeman M, Bowden EM, Haberman J, Frymiare JL, Arambel-Liu S, Greenblatt R, Reber PJ, Kounios J (April 2004). "Neural activity when people solve verbal problems with insight". PLOS Biology. 2 (4) (published 2004): E97. doi:10.1371/journal.pbio.0020097. PMC 387268. PMID 15094802.  
  20. ^ a b Scientific American Mind, October/November 2006
  21. ^ Wagner, U. et al. (2004) Sleep Inspires Insight, Nature 427, pp. 352–355.
  22. ^ Bowden EM, Jung-Beeman M, Fleck J, Kounios J (July 2005). "New approaches to demystifying insight". Trends in Cognitive Sciences. 9 (7): 322–8. doi:10.1016/j.tics.2005.05.012. PMID 15953756. S2CID 11774793.
  23. ^ a b Friedman RS, Förster J (February 2005). "Effects of motivational cues on perceptual asymmetry: implications for creativity and analytical problem solving". Journal of Personality and Social Psychology. 88 (2): 263–75. doi:10.1037/0022-3514.88.2.263. PMID 15841858. S2CID 946372.
  24. ^ Zhang Q, Qiu J, Cao G (2004). "A review and hypothesis about the cognitive mechanism of insight". Psychology Science. 27: 1435–1437.
  25. ^ a b c d e Luo J, Niki K (2003). "Function of hippocampus in "insight" of problem solving". Hippocampus. 13 (3): 316–23. CiteSeerX 10.1.1.669.2884. doi:10.1002/hipo.10069. PMID 12722972. S2CID 22095620.
  26. ^ Shen W, Luo J, Liu C, Yuan Y (2013). "New advances in the neural correlates of insight: A decade in review of the insightful brain". Chinese Science Bulletin. 58 (13): 1497–1511. doi:10.1007/s11434-012-5565-5.
  27. ^ Kershaw TC, Ohlsson S (January 2004). "Multiple causes of difficulty in insight: the case of the nine-dot problem". Journal of Experimental Psychology: Learning, Memory, and Cognition. 30 (1): 3–13. doi:10.1037/0278-7393.30.1.3. PMID 14736292.
  28. ^ Knoblich G, Ohlsson S, Haider H, Rhenius D (1999). "Constraint, Relaxation and Chunk Decomposition in Insight Problem Solving". Journal of Experimental Psychology: Learning, Memory, and Cognition. 25 (6): 1534–1555. doi:10.1037/0278-7393.25.6.1534.
  29. ^ Mednick, M (1963). "Research Creativity in Psychology Graduate Students". Journal of Consulting Psychology. 27 (3): 265–266. doi:10.1037/h0042429. PMID 13934390.
  30. ^ Ollinger M, Jones G, Knoblich G (2008). "Investigating the effect of mental set on insight problem solving" (PDF). Experimental Psychology. 55 (4): 269–82. doi:10.1027/1618-3169.55.4.269. PMID 18683624.
  31. ^ Ormerod TC, MacGregor JN, Chronicle EP (July 2002). "Dynamics and constraints in insight problem solving". Journal of Experimental Psychology: Learning, Memory, and Cognition. 28 (4): 791–9. doi:10.1037/0278-7393.28.4.791. PMID 12109769. S2CID 16912630.
  32. ^ MacGregor JN, Cunningham JB (February 2008). "Rebus puzzles as insight problems". Behavior Research Methods. 40 (1): 263–8. doi:10.3758/brm.40.1.263. PMID 18411549.
  33. ^ "Can you work out what goes in the blank square? It's not 6". indy100. 10 December 2016. Retrieved 16 September 2020.
  34. ^ Chronicle EP, MacGregor JN, Ormerod TC (January 2004). "What makes an insight problem? The roles of heuristics, goal conception, and solution recoding in knowledge-lean problems". Journal of Experimental Psychology: Learning, Memory, and Cognition. 30 (1): 14–27. CiteSeerX 10.1.1.122.5917. doi:10.1037/0278-7393.30.1.14. PMID 14736293.
  35. ^ Einstein A (August 1982). "How I created the theory of relativity" (PDF). Physics Today. 35 (8): 45–47. doi:10.1063/1.2915203.
  36. ^ a b c Moszkowski A (1972). Conversations with Einstein. London: Sidgwick & Jackson. pp. 96–97. ISBN 978-0-283-97924-8.
  37. ^ Dunnington GW, Gray J, Dohse FE (2004). Carl Friedrich Gauss: Titan of Science. The Mathematical Association of America. p. 418. ISBN 978-0-88385-547-8.
  38. ^ a b "Desert Island Discs with Alec Jeffreys". Desert Island Discs. 2007-12-09. BBC. Radio 4.
  39. ^ Newton G (2004-02-04). . Wellcome Trust. Archived from the original on 21 July 2011. Retrieved 23 December 2007.

April 11, 2024
eureka, effect, eureka, effect, also, known, moment, eureka, moment, refers, common, human, experience, suddenly, understanding, previously, incomprehensible, problem, concept, some, research, describes, effect, also, known, insight, epiphany, memory, advantag. The eureka effect also known as the Aha moment or eureka moment refers to the common human experience of suddenly understanding a previously incomprehensible problem or concept Some research describes the Aha effect also known as insight or epiphany as a memory advantage 1 2 but conflicting results exist as to where exactly it occurs in the brain and it is difficult to predict under what circumstances one can predict an Aha moment A 16th century woodcut of Archimedes eureka momentInsight is a psychological term that attempts to describe the process in problem solving when a previously unsolvable puzzle becomes suddenly clear and obvious Often this transition from not understanding to spontaneous comprehension is accompanied by an exclamation of joy or satisfaction an Aha moment citation needed A person utilizing insight to solve a problem is able to give accurate discrete all or nothing type responses whereas individuals not using the insight process are more likely to produce partial incomplete responses 3 A recent theoretical account of the Aha moment started with four defining attributes of this experience First the Aha moment appears suddenly second the solution to a problem can be processed smoothly or fluently third the Aha moment elicits positive affect fourth a person experiencing the Aha moment is convinced that a solution is true These four attributes are not separate but can be combined because the experience of processing fluency especially when it occurs surprisingly for example because it is sudden elicits both positive affect and judged truth 4 5 Insight can be conceptualized as a two phase process The first phase of an Aha experience requires the problem solver to come upon an impasse where they become stuck and even though they may seemingly have explored all the possibilities are still unable to retrieve or generate a solution The second phase occurs suddenly and unexpectedly After a break in mental fixation or re evaluating the problem the answer is retrieved 6 Some research suggest that insight problems are difficult to solve because of our mental fixation on the inappropriate aspects of the problem content 7 In order to solve insight problems one must think outside the box It is this elaborate rehearsal that may cause people to have better memory for Aha moments Insight is believed to occur with a break in mental fixation allowing the solution to appear transparent and obvious Contents 1 History and etymology 2 Research 2 1 Initial research 2 2 How people solve insight problems 2 3 Memory 2 4 Cerebral lateralization 2 5 Sleep 2 6 Other theories 2 7 General procedure for conducting ERP and EEG studies 2 8 Evidence in EEG studies 2 9 Evidence in ERP studies 2 10 Evidence in fMRI studies 3 Insight problems and problems with insight 3 1 Insight problems 3 1 1 The Nine Dot Problem 3 1 2 Verbal riddles 3 1 3 Matchstick arithmetic 3 1 4 Anagrams 3 1 5 Rebus puzzles 3 1 6 Remote Associates Test RAT 3 1 7 The Eight Coin Problem 3 1 8 Problems with insight 4 The Aha effect and scientific discovery 5 See also 6 NotesHistory and etymology editThe effect is named from a story about ancient Greek polymath Archimedes In the story Archimedes was asked c 250 BC by the local king to determine whether a crown was pure gold During a subsequent trip to a public bath Archimedes noted that water was displaced when his body sank into the bath and particularly that the volume of water displaced equaled the volume of his body immersed in the water Having discovered how to measure the volume of an irregular object and conceiving of a method to solve the king s problem Archimedes allegedly leaped out and ran home naked shouting eὕrhka eureka I have found it This story is now thought to be fictional because it was first mentioned by the Roman writer Vitruvius nearly 200 years after the date of the alleged event and because the method described by Vitruvius would not have worked 8 However Archimedes certainly did important original work in hydrostatics notably in his On Floating Bodies Research editInitial research edit Research on the Aha moment dates back more than 100 years to the Gestalt psychologists first experiments on chimpanzee cognition 9 In his 1921 book 9 Wolfgang Kohler described the first instance of insightful thinking in animals One of his chimpanzees Sultan was presented with the task of reaching a banana that had been strung up high on the ceiling so that it was impossible to reach by jumping After several failed attempts to reach the banana Sultan sulked in the corner for a while then suddenly jumped up and stacked a few boxes upon each other climbed them and thus was able to grab the banana This observation was interpreted as insightful thinking Kohler s work was continued by Karl Duncker and Max Wertheimer The Eureka effect was later also described by Pamela Auble Jeffrey Franks and Salvatore Soraci in 1979 The subject would be presented with an initially confusing sentence such as The haystack was important because the cloth ripped After a certain period of time of non comprehension by the reader the cue word parachute would be presented the reader could comprehend the sentence and this resulted in better recall on memory tests 2 Subjects spend a considerable amount of time attempting to solve the problem and initially it was hypothesized that elaboration towards comprehension may play a role in increased recall There was no evidence that elaboration had any effect for recall It was found that both easy and hard sentences that resulted in an Aha effect had significantly better recall rates than sentences that subjects were able to comprehend immediately In fact equal recall rates were obtained for both easy and hard sentences which were initially noncomprehensible It seems to be this noncomprehension to comprehension which results in better recall The essence of the aha feeling underlining insight problem solving was systemically investigated by Danek et al 10 and Shen and his colleagues 11 Recently an attempt has been made in trying to understand the neurobiological basis of Eureka moment 12 How people solve insight problems edit Currently there are two theories for how people arrive at the solution for insight problems The first is the progress monitoring theory 13 The person will analyze the distance from their current state to the goal state Once a person realizes that they cannot solve the problem while on their current path they will seek alternative solutions In insight problems this usually occurs late in the puzzle The second way that people attempt to solve these puzzles is the representational change theory 14 The problem solver initially has a low probability for success because they use inappropriate knowledge as they set unnecessary constraints on the problem Once the person relaxes his or her constraints they can bring previously unavailable knowledge into working memory to solve the problem The person also utilizes chunk decomposition where he or she will separate meaningful chunks into their component pieces Both constraint relaxation and chunk decomposition allow for a change in representation that is a change in the distribution of activation across working memory at which point they may exclaim Aha Currently both theories have support with the progress monitoring theory being more suited to multiple step problems and the representational change theory more suited to single step problems 15 The Eureka effect on memory occurs only when there is an initial confusion 16 When subjects were presented with a clue word before the confusing sentence was presented there was no effect on recall If the clue was provided after the sentence was presented an increase in recall occurred Memory edit It had been determined that recall is greater for items that were generated by the subject versus if the subject was presented with the stimuli 2 There seems to be a memory advantage for instances where people are able to produce an answer themselves recall was higher when Aha reactions occurred 2 They tested sentences that were initially hard to understand but when presented with a cued word the comprehension became more apparent Other evidence was found indicating that effort in processing visual stimuli was recalled more frequently than the stimuli that were simply presented 17 This study was done using connect the dots or verbal instruction to produce either a nonsense or real image It is believed that effort made to comprehend something when encoding induces activation of alternative cues that later participate in recall 18 Cerebral lateralization edit See also Lateralization of brain function Functional magnetic resonance imaging and electroencephalogram studies 19 have found that problem solving requiring insight involves increased activity in the right cerebral hemisphere as compared with problem solving not requiring insight In particular increased activity was found in the right hemisphere anterior superior temporal gyrus Sleep edit Some unconscious processing may take place while a person is asleep and there are several cases of scientific discoveries coming to people in their dreams Friedrich August Kekule von Stradonitz claimed that the ring structure of benzene came to him in a dream where a snake was eating its own tail 20 Studies have shown increased performance at insight problems if the subjects slept during a break between receiving the problem and solving it Sleep may function to restructure problems and allow new insights to be reached 21 Henri Poincare stated that he valued sleep as a time for unconscious thought that helped him break through problems citation needed Other theories edit Professor Stellan Ohlsson believes that at the beginning of the problem solving process some salient features of the problem are incorporated into a mental representation of the problem In the first step of solving the problem it is considered in the light of previous experience Eventually an impasse is reached where all approaches to the problem have failed and the person becomes frustrated Ohlsson believes that this impasse drives unconscious processes which change the mental representation of a problem and cause novel solutions to occur 20 General procedure for conducting ERP and EEG studies edit When studying insight or the Aha effect ERP or EEG general methods are used Initially a baseline measurement is taken which generally asks the subject to simply remember an answer to a question Following this subjects are asked to focus on the screen while a logogriph is shown and then they are given time with a blank screen to get the answer once they do they are required to press a key After which the answer appears on the screen The subjects are then asked to press one key to indicate that they thought of the correct answer and another to indicate if they got the answer wrong finally not to press a key at all if they were unsure or did not know the answer Evidence in EEG studies edit Resting state neural activity has a standing influence on cognitive strategies used when solving problems particularly in the case of deriving solutions by methodical search or by sudden insight 3 The two cognitive strategies used involve both search and analysis of current state of a problem to the goal state of that problem while insight problems are a sudden awareness of the solution to a problem 3 Subjects studied were first recorded on the base line resting state of thinking After being tested using the method described in the General Procedure for Conducting ERP and EEG Studies the ratio of insight versus non insight solution were made to determine whether an individual is classified as a high insight HI or a low insight LI individual Discriminating between HI and LI individuals were important as both groups use different cognitive strategies to solve anagram problems used in this study 3 Right hemisphere activation is believed to be involved in Aha effects 22 so it comes as no surprise that HI individuals would show greater activation in the right hemisphere than the left hemisphere when compared to the LI individuals Evidence was found to support this idea there was greater activation in HI subjects at the right dorsal frontal low alpha band right inferior frontal beta and gamma bands and the right parietal gamma band areas 3 As for LI subjects left inferior frontal and left anterior temporal areas were active low alpha band There were also differences in attention between individuals of HI and LI It has been suggested that individuals who are highly creative exhibit diffuse attention thus allowing them a greater range of environmental stimuli 23 It was found that individuals who displayed HI would have less resting state occipital alpha band activity meaning there would be less inhibition of the visual system 3 Individuals that were less creative were found to focus their attention thus causing them to sample less of their environment 23 Although LI individuals were shown to have more occipital beta activity consistent with heightened focused attention 3 Evidence in ERP studies edit Source localization is hard in ERP studies and it may be difficult to distinguish signals of insight from signals of the existing cognitive skills it builds on or the unwarranted mental fixation it breaks but the following conclusions have been offered One study found that Aha answers produced more negative ERP results N380 in the ACC than the No Aha answers 250 500 ms after an answer was produced 7 The authors suspected that this N380 in the ACC is a sign of breaking the mental set and reflects the Aha effect Another study was done showed that an Aha effect elicited an N320 in the central posterior region 24 A third study by Qiu and Zhang 2008 found that there was a N350 in the posterior cingulate cortex for successful guessing not in the anterior cingulate cortex The posterior cingulate cortex seems to play a more non executive function in monitoring and inhibiting the mind set and cognitive function 6 Another significant finding of this study was a late positive component LPC in successful guessing and then recognition of the answer at 600 and 700 ms post stimulus in the parahippocampal gyrus BA34 The data suggests that the parahippocampus is involved in searching for a correct answer by manipulating it in working memory and integrating relationships The parahippocampal gyrus may reflect the formation of novel associations while solving insight problems A fourth ERP study is fairly similar but this study claims to have anterior cingulate cortex activation at N380 which may be responsible for the mediation of breaking the mental set Other areas of interest were prefrontal cortex PFC the posterior parietal cortex and the medial temporal lobe If subjects failed to solve the riddle and then were shown the correct answer they displayed the feeling of insight which was reflected on the electroencephalogram recordings Evidence in fMRI studies edit A study with the goal of recording the activity that occurs in the brain during an Aha moment using fMRIs was conducted in 2003 by Jing Luo and Kazuhisa Niki Participants in this study were presented with a series of Japanese riddles and asked to rate their impressions toward each question using the following scale 1 I can understand this question very well and know the answer 2 I can understand this question very well and feel it is interesting but I do not know the answer or 3 I cannot understand this question and do not know the answer 25 This scale allowed the researchers to only look at participants who would experience an Aha moment upon viewing the answer to the riddle In previous studies on insight researchers have found that participants reported feelings of insight when they viewed the answer to an unsolved riddle or problem 25 Luo and Niki had the goal of recording these feelings of insight in their participants using fMRIs This method allowed the researchers to directly observe the activity that was occurring in the participant s brains during an Aha moment An example of a Japanese riddle used in the study The thing that can move heavy logs but cannot move a small nail A river 25 Participants were given 3 minutes to respond to each riddle before the answer to the riddle was revealed If the participant experienced an Aha moment upon viewing the correct answer any brain activity would be recorded on the fMRI 25 The fMRI results for this study showed that when participants were given the answer to an unsolved riddle the activity in their right hippocampus increased significantly during these Aha moments This increased activity in the right hippocampus may be attributed to the formation of new associations between old nodes 25 These new associations will in turn strengthen memory for the riddles and their solutions Although various studies using EEGs ERPs and fMRI s report activation in a variety of areas in the brain during Aha moments this activity occurs predominantly in the right hemisphere More details on the neural basis of insight see a recent review named New advances in the neural correlates of insight A decade in review of the insightful brain 26 Insight problems and problems with insight editInsight problems edit The Nine Dot Problem edit nbsp The Nine Dot Problem with solution Most individuals fail to draw lines beyond the dots that compose the square and are unable to solve this puzzle The Nine Dot Problem is a classic spatial problem used by psychologists to study insight The problem consists of a 3 3 square created by 9 black dots The task is to connect all 9 dots using exactly 4 straight lines without retracing or removing one s pen from the paper Kershaw amp Ohlsson 27 report that in a laboratory setting with a time limit of 2 or 3 minutes the expected solution rate is 0 The difficulty with the Nine Dot Problem is that it requires respondents to look beyond the conventional figure ground relationships that create subtle illusory spatial constraints and literally think outside of the box Breaking the spatial constraints shows a shift in attention in working memory and utilizing new knowledge factors to solve the puzzle Verbal riddles edit Verbal riddles are becoming popular problems in insight research Example A man was washing windows on a high rise building when he fell from the 40 foot ladder to the concrete path below Amazingly he was unhurt Why Answer He slipped from the bottom rung Matchstick arithmetic edit A subset of matchstick puzzles matchstick arithmetic which was developed and used by G Knoblich 28 involves matchsticks that are arranged to show a simple but incorrect math equation in Roman numerals The task is to correct the equation by moving only one matchstick nbsp Two examples of matchstick arithmetic problemsAnagrams edit Anagrams involve manipulating the order of a given set of letters in order to create one or many words The original set of letters may be a word itself or simply a jumble Example Santa can be transformed to spell Satan Rebus puzzles edit Rebus puzzles also called wordies involve verbal and visual cues that force the respondent to restructure and read between the lines almost literally to solve the puzzle Some examples Puzzle you just me Answer just between you and me Puzzle PUNISHMENT Answer capital punishment Puzzle i i i OOOOO Answer circles under the eyes Remote Associates Test RAT edit Main article Remote Associates Test The Remote Associates Test known as the RAT was developed by Martha Mednick in 1962 29 to test creativity However it has recently been utilized in insight research The test consists of presenting participants with a set of words such as lick mine and shaker The task is to identify the word that connects these three seemingly unrelated ones In this example the answer is salt The link between words is associative and does not follow rules of logic concept formation or problem solving and thus requires the respondent to work outside of these common heuristical constraints Performance on the RAT is known to correlate with performance on other standard insight problems 30 The Eight Coin Problem edit In this problem a set of 8 coins is arranged on a table in a certain configuration and the subject is told to move 2 coins so that all coins touch exactly three others The difficulty in this problem comes from thinking of the problem in a purely 2 dimensional way when a 3 dimensional approach is the only way to solve the problem 31 Problems with insight edit Insight research is problematic because of the ambiguity and lack of agreement among psychologists of its definition 32 This could largely be explained by the phenomenological nature of insight and the difficulty in catalyzing its occurrence as well as the ways in which it is experimentally triggered nbsp Example of a puzzle that requires an insight from the solver Asked what goes in the blank square and told that it is not the number six the solver must realise that the image represents a gear stick and the answer is R for Reverse 33 The pool of insight problems currently employed by psychologists is small and tepid and due to its heterogeneity and often high difficulty level is not conducive of validity or reliability One of the biggest issues surrounding insight problems is that for most participants they are simply too difficult For many problems this difficulty revolves around the requisite restructuring or re conceptualization of the problem or possible solutions for example drawing lines beyond the square composed of dots in the Nine Dot Problem Furthermore there are issues related to the taxonomy of insight problems Puzzles and problems that are utilized in experiments to elicit insight may be classified in two ways Pure insight problems are those that necessitate the use of insight whereas hybrid insight problems are those that can be solved by other methods such as the trial and error 34 As Weisberg 1996 points out the existence of hybrid problems in insight research poses a significant threat to any evidence gleaned from studies that employ them While the phenomenological experience of insight can help to differentiate insight solving from non insight solving by asking the respondent to describe how they solved the problem for example the risk that non insight solving has been mistaken for insight solving still exists Likewise issues surrounding the validity of insight evidence is also threatened by the characteristically small sample sizes Experimenters may recruit an initially adequate sample size but because of the level of difficulty inherent to insight problems only a small fraction of any sample will successfully solve the puzzle or task given to them placing serious limits on usable data In the case of studies using hybrid problems the final sample is at even greater risk of being very small by way of having to exclude whatever percentage of respondents solved their given puzzle without utilizing insight The Aha effect and scientific discovery editThere are several examples of scientific discoveries being made after a sudden flash of insight One of the key insights in developing his special theory of relativity came to Albert Einstein while talking to his friend Michele Besso I started the conversation with him in the following way Recently I have been working on a difficult problem Today I come here to battle against that problem with you We discussed every aspect of this problem Then suddenly I understood where the key to this problem lay Next day I came back to him again and said to him without even saying hello Thank you I ve completely solved the problem 35 However Einstein has said that the whole idea of special relativity did not come to him as a sudden single eureka moment 36 and that he was led to it by steps arising from the individual laws derived from experience 36 Similarly Carl Friedrich Gauss said after a eureka moment I have the result only I do not yet know how to get to it 36 37 Sir Alec Jeffreys had a eureka moment in his lab in Leicester after looking at the X ray film image of a DNA experiment at 9 05 am on Monday 10 September 1984 which unexpectedly showed both similarities and differences between the DNA of different members of his technician s family 38 39 Within about half an hour he realized the scope of DNA profiling which uses variations in the genetic code to identify individuals The method has become important in forensic science to assist detective work and in resolving paternity and immigration disputes 38 It can also be applied to non human species such as in wildlife population genetics studies Before his methods were commercialised in 1987 Jeffreys laboratory was the only centre carrying out DNA fingerprinting in the world citation needed See also editInsight phenomenology Apprehension understanding Rubber duck debugging Principles of grouping Katsu Zen Notes edit Danek AH Fraps T von Muller A Grothe B Ollinger M September 2013 Aha experiences leave a mark facilitated recall of insight solutions Psychological Research 77 5 659 69 doi 10 1007 s00426 012 0454 8 PMID 23007629 S2CID 26161927 a b c d Auble P Franks J Soraci S 1979 Effort toward comprehension Elaboration or aha Memory amp Cognition 7 6 426 434 doi 10 3758 bf03198259 a b c d e f g Kounios J Fleck JI Green DL Payne L Stevenson JL Bowden EM Jung Beeman M January 2008 The origins of insight in resting state brain activity Neuropsychologia 46 1 281 91 doi 10 1016 j neuropsychologia 2007 07 013 PMC 2293274 PMID 17765273 Topolinski S Reber R 2010 Gaining insight into the Aha experience Current Directions in Psychological Science 19 6 402 405 doi 10 1177 0963721410388803 S2CID 145057045 Wray H 2011 Aha The 23 Across Phenomenon APS Observer 24 1 a b Qiu amp Zhang 2008 Aha Effects in a Guessing Chinese Logograph Task An Event Related Potential Study Chinese Science Bulletin 53 3 384 391 a b Mai XQ Luo J Wu JH Luo YJ August 2004 Aha effects in a guessing riddle task an event related potential study Human Brain Mapping 22 4 261 70 doi 10 1002 hbm 20030 PMC 6871977 PMID 15202104 Fact or Fiction Archimedes Coined the Term Eureka in the Bath Scientific American a b Kohler W 1921 Intelligenzprufungen am Menschenaffen Berlin Springer Danek AH Fraps T von Muller A Grothe B Ollinger M 2014 It s a kind of magic what self reports can reveal about the phenomenology of insight problem solving Frontiers in Psychology 5 1408 doi 10 3389 fpsyg 2014 01408 PMC 4258999 PMID 25538658 Shen W Yuan Y Liu C Luo J May 2016 In search of the Aha experience Elucidating the emotionality of insight problem solving British Journal of Psychology 107 2 281 98 doi 10 1111 bjop 12142 PMID 26184903 What causes Eureka Moment in the brain South Asia Monitor 12 December 2021 MacGregor JN Ormerod TC Chronicle EP January 2001 Information processing and insight a process model of performance on the nine dot and related problems Journal of Experimental Psychology Learning Memory and Cognition 27 1 176 201 doi 10 1037 0278 7393 27 1 176 PMID 11204097 Knoblich G Ohlsson S Raney GE October 2001 An eye movement study of insight problem solving Memory amp Cognition 29 7 1000 9 doi 10 3758 bf03195762 PMID 11820744 Jones G September 2003 Testing two cognitive theories of insight PDF Journal of Experimental Psychology Learning Memory and Cognition 29 5 1017 27 doi 10 1037 0278 7393 29 5 1017 PMID 14516232 Wills TW Estow S Soraci SA Garcia J July 2006 The aha effect in groups and other dynamic learning contexts The Journal of General Psychology 133 3 221 36 doi 10 3200 genp 133 3 221 236 PMID 16937892 S2CID 45391625 Peynircioglu F 1989 The generation effect with pictures and nonsense figures Acta Psychologica 70 2 153 160 doi 10 1016 0001 6918 89 90018 8 Wills TW Soraci SA Chechile RA Taylor HA September 2000 Aha effects in the generation of pictures Memory amp Cognition 28 6 939 48 doi 10 3758 bf03209341 PMID 11105519 Jung Beeman M Bowden EM Haberman J Frymiare JL Arambel Liu S Greenblatt R Reber PJ Kounios J April 2004 Neural activity when people solve verbal problems with insight PLOS Biology 2 4 published 2004 E97 doi 10 1371 journal pbio 0020097 PMC 387268 PMID 15094802 nbsp a b Scientific American Mind October November 2006 Wagner U et al 2004 Sleep Inspires Insight Nature 427 pp 352 355 Bowden EM Jung Beeman M Fleck J Kounios J July 2005 New approaches to demystifying insight Trends in Cognitive Sciences 9 7 322 8 doi 10 1016 j tics 2005 05 012 PMID 15953756 S2CID 11774793 a b Friedman RS Forster J February 2005 Effects of motivational cues on perceptual asymmetry implications for creativity and analytical problem solving Journal of Personality and Social Psychology 88 2 263 75 doi 10 1037 0022 3514 88 2 263 PMID 15841858 S2CID 946372 Zhang Q Qiu J Cao G 2004 A review and hypothesis about the cognitive mechanism of insight Psychology Science 27 1435 1437 a b c d e Luo J Niki K 2003 Function of hippocampus in insight of problem solving Hippocampus 13 3 316 23 CiteSeerX 10 1 1 669 2884 doi 10 1002 hipo 10069 PMID 12722972 S2CID 22095620 Shen W Luo J Liu C Yuan Y 2013 New advances in the neural correlates of insight A decade in review of the insightful brain Chinese Science Bulletin 58 13 1497 1511 doi 10 1007 s11434 012 5565 5 Kershaw TC Ohlsson S January 2004 Multiple causes of difficulty in insight the case of the nine dot problem Journal of Experimental Psychology Learning Memory and Cognition 30 1 3 13 doi 10 1037 0278 7393 30 1 3 PMID 14736292 Knoblich G Ohlsson S Haider H Rhenius D 1999 Constraint Relaxation and Chunk Decomposition in Insight Problem Solving Journal of Experimental Psychology Learning Memory and Cognition 25 6 1534 1555 doi 10 1037 0278 7393 25 6 1534 Mednick M 1963 Research Creativity in Psychology Graduate Students Journal of Consulting Psychology 27 3 265 266 doi 10 1037 h0042429 PMID 13934390 Ollinger M Jones G Knoblich G 2008 Investigating the effect of mental set on insight problem solving PDF Experimental Psychology 55 4 269 82 doi 10 1027 1618 3169 55 4 269 PMID 18683624 Ormerod TC MacGregor JN Chronicle EP July 2002 Dynamics and constraints in insight problem solving Journal of Experimental Psychology Learning Memory and Cognition 28 4 791 9 doi 10 1037 0278 7393 28 4 791 PMID 12109769 S2CID 16912630 MacGregor JN Cunningham JB February 2008 Rebus puzzles as insight problems Behavior Research Methods 40 1 263 8 doi 10 3758 brm 40 1 263 PMID 18411549 Can you work out what goes in the blank square It s not 6 indy100 10 December 2016 Retrieved 16 September 2020 Chronicle EP MacGregor JN Ormerod TC January 2004 What makes an insight problem The roles of heuristics goal conception and solution recoding in knowledge lean problems Journal of Experimental Psychology Learning Memory and Cognition 30 1 14 27 CiteSeerX 10 1 1 122 5917 doi 10 1037 0278 7393 30 1 14 PMID 14736293 Einstein A August 1982 How I created the theory of relativity PDF Physics Today 35 8 45 47 doi 10 1063 1 2915203 a b c Moszkowski A 1972 Conversations with Einstein London Sidgwick amp Jackson pp 96 97 ISBN 978 0 283 97924 8 Dunnington GW Gray J Dohse FE 2004 Carl Friedrich Gauss Titan of Science The Mathematical Association of America p 418 ISBN 978 0 88385 547 8 a b Desert Island Discs with Alec Jeffreys Desert Island Discs 2007 12 09 BBC Radio 4 Newton G 2004 02 04 Discovering DNA fingerprinting Sir Alec Jeffreys describes its development Wellcome Trust Archived from the original on 21 July 2011 Retrieved 23 December 2007 Retrieved from https en wikipedia org w index php title Eureka effect amp oldid 1184971659, wikipedia, wiki, book, books, library,

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