Origin of language: Difference between revisions

The origin of language concerns the onset in prehistory of human language -- whether gestural or spoken. There are numerous hypotheses about how, why, when and where it happened, but all are speculative because the relevant developments occurred so early in human prehistory and have left no direct historical traces; nor are comparable processes observable today.^[1][2]

The time range in question extends from the phylogenetic separation of Homo (2.3 to 2.4 million years ago) and Pan (5 to 6 million years ago) to the emergence of full behavioral modernity some 50,000 years ago.

The evolution of spoken human language requires the development of the vocal tract used for speech production and the cognitive abilities required to understand and produce linguistic utterances. Some debate surrounds the time line, sequence and order of developments associated with this.

It is mostly undisputed that pre-human australopithecines did not have communication systems significantly different from those found in great apes in general,^{[citation needed]} but scholarly opinions vary as to the developments since the appearance of Homo some 2.5 million years ago. Some scholars assume the development of primitive language-like systems (proto-language) as early as Homo habilis, while others place the development of primitive symbolic communication only with Homo erectus (1.8 million years ago) or Homo heidelbergensis (0.6 million years ago) and the development of language proper with Homo sapiens less than 100,000 years ago.

History

In religion and mythology

Main article: Mythical origins of language

See also: Divine language and Adamic language

The search for the origin of language has a long history rooted in mythology. Most mythologies do not credit humans with the invention of language but speak of a divine language predating human language. Mystical languages used to communicate with animals or spirits, such as the language of the birds, are also common, and were of particular interest during the Renaissance.

Historical experiments

History contains a number of anecdotes about people who attempted to discover the origin of language by experiment. The first such tale was told by Herodotus. He relates that Pharaoh Psammetichus (probably Psammetichus I) had two children raised by deaf-mutes in order to see what language they would speak. When the children were brought before him, one of them said something that sounded to the Pharaoh like bekos, the Phrygian word for bread. From this Psammetichus concluded that the first language was Phrygian. King James V of Scotland is said to have tried a similar experiment: his children were supposed to have spoken Hebrew.^[3] Both the medieval monarch Frederick II and Akbar are said to have tried similar experiments; the children involved in these experiments did not speak.^[4]

History of research

Main article: Evolutionary linguistics

Late 18th to early 19th century European scholarship assumed that the languages of the world reflected various stages in the development from primitive to advanced speech, culminating in the Indo-European languages, seen as the most advanced.^{[citation needed]}

Modern linguistics does not begin until the late 18th century, and the Romantic or animist theses of Johann Gottfried Herder and Johann Christoph Adelung remained influential well into the 19th century. The question of language origins seemed inaccessible to methodical approaches, and in 1866 the Linguistic Society of Paris famously banned all discussion of the origin of language, deeming it to be an unanswerable problem. An increasingly systematic approach to historical linguistics developed in the course of the 19th century, reaching its culmination in the Neogrammarian school of Karl Brugmann and others.

However, scholarly interest in the question of the origin of language has only gradually been rekindled from the 1950s on (and then controversially) with ideas such as universal grammar, mass comparison and glottochronology.

The "origin of language" as a subject in its own right emerged out of studies in neurolinguistics, psycholinguistics and human evolution. The Linguistic Bibliography introduced "Origin of language" as a separate heading in 1988, as a sub-topic of psycholinguistics. Dedicated research institutes of evolutionary linguistics are a recent phenomenon, emerging only in the 1990s.

Biological foundations for human speech

The descended larynx was formerly viewed as a structure unique to the human vocal tract and essential to the development of speech and language. However, it has been found in other species, including some aquatic mammals and large deer (e.g. Red Deer), and the larynx has been observed to descend during vocalizations in dogs, goats, and alligators. In humans, the descended larynx extends the length of the vocal tract and expands the variety of sounds humans can produce. Some scholars claim that the ubiquity of nonverbal communication in humans stands as evidence of the non-essentiality of the descended larynx to the development of language.

The descended larynx has non-linguistic functions as well, possibly exaggerating the apparent size of an animal (through vocalizations with lower than expected pitch). Thus, although it plays an important role in speech production, expanding the variety of sounds humans can produce, it may not have evolved specifically for this purpose, as has been suggested by Jeffrey Laitman, and as per Hauser, Chomsky, and Fitch (2002), could be an example of preadaptation.

The control capabilities of human tongue should also be considered. As a result of higher intelligence, the human brain can control its organs and peripherals more precisely. Therefore, the tongue is more creative to curve, bend, stop and throw the soundwaves produced by larynx.

Language origin hypotheses

Gestural theory

The gestural theory states that human language developed from gestures that were used for simple communication.

Two types of evidence support this theory.

1. Gestural language and vocal language depend on similar neural systems. The regions on the cortex that are responsible for mouth and hand movements border each other.
2. Nonhuman primates can use gestures or symbols for at least primitive communication, and some of their gestures resemble those of humans, such as the "begging posture", with the hands stretched out, which humans share with chimpanzees.^[5]

Research has found strong support for the idea that verbal language and sign language depend on similar neural structures. Patients who used sign language, and who suffered from a left-hemisphere lesion, showed the same disorders with their sign language as vocal patients did with their spoken language.^[6] Other researchers found that the same left-hemisphere brain regions were active during sign language as during the use of vocal or written language.^[7]

The important question for gestural theories is why there was a shift to vocalization. There are three likely explanations:

1. Our ancestors started to use more and more tools, meaning that their hands were occupied and could not be used for gesturing.
2. Gesturing requires that the communicating individuals can see each other. There are many situations in which individuals need to communicate even without visual contact, for instance when a predator is closing in on somebody who is up in a tree picking fruit.
3. The need to co-operate effectively with others in order to survive. A command issued by a tribal leader to 'find' 'stones' to 'repel' attacking 'wolves' would create teamwork and a much more powerful, co-ordinated response.

Humans still use hand and facial gestures when they speak, especially when people meet who have no language in common.^[8] There are also, of course, a great number of sign languages still in existence, commonly associated with Deaf communities; it is important to note that these signed languages are equal in complexity, sophistication, and expressive power, to any spoken language—the cognitive functions are similar and the parts of the brain used are similar. The main difference is that the "phonemes" are produced on the outside of the body, articulated with hands, body, and facial expression, rather than inside the body articulated with tongue, teeth, lips, and breathing.

Critics of gestural theory note that it is difficult to name serious reasons why the initial pitch-based vocal communication (which is present in primates) would be abandoned in favour of the much less effective non-vocal, gestural communication. Other challenges to the "gesture-first" theory have been presented by researchers in psycholinguistics, including David McNeill.

Self-domesticated ape theory

According to a study investigating the song differences between white-rumped Munias and its domesticated counterpart (Bengalese finch), the wild munias use a highly stereotyped song, whereas the domesticated ones sing a highly unconstrained song. Considering that song syntactical complexity is subject to female preference in the Bengalese finch, it is likely that maternal resource allocation strategies play a role in song evolution.^[9] In the field of bird vocalization, brains capable of producing only an innate song have very simple neural pathways: the primary forebrain motor center, called the robust nucleus of arcopallium (RA), connects to midbrain vocal outputs which in turn project to brainstem motor nuclei. By contrast, in brains capable of learning songs, the RA receives input from numerous additional forebrain regions, including those involved in learning and social experience. Control over song generation has become less constrained, more distributed, and more flexible.

When compared with other primates, whose communication system is restricted to a highly stereotypic repertoire of hoots and calls, humans have very few prespecified vocalizations, extant examples being laughter and sobbing. Moreover, these remaining innate vocalizations are generated by restricted neuronal pathways, whereas language is generated by a highly distributed system involving numerous regions of the human brain.

A salient feature of language is that while language competency is inherited, the languages themselves are transmitted via culture. Also transmitted via culture are understandings, such as technological ways of doing things, that are framed as language-based explanations. Hence one would expect a robust co-evolutionary trajectory between language competency and culture: proto-humans capable of the first, and presumably rudimentary, versions of protolanguage would have better access to cultural understandings, and cultural understandings, conveyed in protolanguages that children's brains could readily learn, were more likely to be transmitted, thereby conferring the benefits accrued.

Hence proto-humans indubitably engaged in, and continue to engage in, what is called niche construction, creating cultural niches that provide understandings key to survival, and undergoing evolutionary changes that optimize their ability to flourish in such niches. Selection pressures that operated to sustain instincts important for survival in prior niches would be expected to relax as humans became increasingly dependent on their self-created cultural niches, while any innovations that facilitated cultural adaptation—in this case, innovations in language competency—would be expected to spread.

One useful way to think about human evolution is that we are self-domesticated apes. Just as domestication relaxed selection for stereotypic songs in the finches—mate choice was supplanted by choices made by the aesthetic sensibilities of bird breeders and their customers—so might our cultural domestication have relaxed selection on many of our primate behavioral traits, allowing old pathways to degenerate and reconfigure. Given the highly indeterminate way that mammalian brains develop—they basically construct themselves "bottom up," with one set of neuronal interactions setting the stage for the next round of interactions—degraded pathways would tend to seek out and find new opportunities for synaptic hookups. Such inherited de-differentiations of brain pathways might have contributed to the functional complexity that characterizes human language. And, as exemplified by the finches, such de-differentiations can occur in very rapid timeframes.^[10][11]

Synergetic approach

The Azerbaijan Linguistic School works on the belief that speech does not precede language and is not the only instrument for language performance. Language can exist without speech, and nonverbal means can play the role of shell (medium) for language. Humans developed the verbal language form because other channels of communication are not so extensive or comfortable. Here natural selection favours the verbal channel. Despite the dominance of the visual channel in everyday human relations with the outside world, it is insufficiently reliable for individual security. Human vision apprehends at any given moment only a quarter of the visible environment, and is usable for only half of the time (i.e., during wakefulness). The efficiency of the visual channel is also limited by various adverse conditions such as smoke, fog, or any other obstacles.

The auditory canal activity is available for 24 hours in the range of 360 degrees in space. The only barrier for sound propagation is strong noise, which is a very atypical occurrence. Furthermore, in order to communicate with a person visually it is necessary that this person sees the communicator. On the other hand, the auditory canal is open around the clock for perception of information from all sides, from anyone, and without any special settings. All this contributed to the human verbal (oral) form of language development.

It is hypothesized that the mechanism of modern sophisticated and overly complicated human languages development is identical to the writing evolutionary mechanism, and has evolved through the following four stages:

• Stage I: Phoneme = sentence (pictographic language);
• Stage II: Phoneme = word or phrase (ideographic language);
• Stage III: Phoneme = syllable (syllabic language);
• Stage IV: Phoneme = sound (phonetic language).

That is, some utterance first substituted (designated) a whole sentence, then — only a part of the sentence, and then — part of the word ^{[12] [13] [14] [15] [16] [17]}.

Evolutionary timeline

Primate language

Not much is known about great ape communication in the wild. The anatomical structure of their larynxes does not enable apes to make many of the sounds that modern humans do. In captivity, apes have been taught rudimentary sign language and the use of lexigrams—symbols that do not graphically resemble their corresponding words—on computer keyboards. Some apes, such as Kanzi, have been able to learn and use hundreds of lexigrams.

The Broca's and Wernicke's areas in the primate brain are responsible for controlling the muscles of the face, tongue, mouth, and larynx, as well as recognizing sounds. Primates are known to make "vocal calls," and these calls are generated by circuits in the brainstem and limbic system.^[18] Howewer, modern brain scans of chattering chimpanzees prove that they use Brocas area to chatter ^[19] and there is evidence that monkeys hearing monkey chatter use the same brain regions as humans hearing speech.^[20]

In the wild, the communication of vervet monkeys has been the most extensively studied.^[21] They are known to make up to ten different vocalizations. Many of these are used to warn other members of the group about approaching predators. They include a "leopard call", a "snake call", and an "eagle call". Each call triggers a different defensive strategy in the monkeys that hear the call and scientists were able to elicit predictable responses from the monkeys using loudspeakers and prerecorded sounds. Other vocalizations may be used for identification. If an infant monkey calls, its mother turns toward it, but other vervet mothers turn instead toward that infant's mother to see what she will do.^[22]

Similarly, researchers have demonstrated that chimpanzees (in captivity) use different "words" in reference to different foods. They recorded vocalizations that chimps made in reference, for example, to grapes, and then other chimps pointed at pictures of grapes when they heard the recorded sound.

Early Homo

Regarding articulation, there is considerable speculation about the language capabilities of early Homo (2.5 to 0.8 million years ago). Anatomically, some scholars believe features of bipedalism which developed in australopithecines around 3.5 million years ago would have brought changes to the skull, allowing for a more L-shaped vocal tract. The shape of the tract and a larynx positioned relatively low in the neck are necessary prerequisites for many of the sounds humans make, particularly vowels. Other scholars believe that, based on the position of the larynx, not even Neanderthals had the anatomy necessary to produce the full range of sounds modern humans make.^[23][24] Still another view considers the lowering of the larynx irrelevant to the development of speech.^[25]

The term proto-language, as defined by linguist Derek Bickerton, is a primitive form of communication lacking:

• a fully developed syntax
• tense, aspect, auxiliary verbs, etc.
• a closed-class (i.e. non-lexical) vocabulary

That is, a stage in the evolution of language somewhere between great ape language and fully developed modern human language. Bickerton (2009) places the first emergence of such a proto-language with the earliest appearance of Homo, and associates its appearance with the pressure of behavioral adaptation to the niche construction of scavenging faced by Homo habilis.^[26]

Anatomical features such as the L-shaped vocal tract have been continuously evolving, as opposed to appearing suddenly.^[27] Hence it is most likely that Homo habilis and Homo erectus during the Lower Pleistocene had some form of communication intermediate between that of modern humans and that of other primates.^[28]

Archaic Homo sapiens

Further information: Archaic Homo sapiens

Steven Mithen proposed the term Hmmmmm for the pre-linguistic system of communication used by archaic Homo, beginning with Homo ergaster and reaching the highest sophistification in the Middle Pleistocene with Homo heidelbergensis and Homo neanderthalensis. Hmmmmm is an acronym for holistic (non-compositional), manipulative (utterances are commands or suggestions, not descriptive statements), multi-modal (acoustic as well as gestural and mimetic), musical, and memetic.^[29]

Homo heidelbergensis

See also: Homo heidelbergenis: Language

H. heidelbergensis was a close relative (most probably a migratory descendant) of Homo ergaster. H. ergaster is thought to be the first hominid to vocalize,^[30] and that as H. heidelbergensis developed more sophisticated culture proceeded from this point and possibly developed an early form of symbolic language.

Homo neanderthalensis

See also: Neanderthal behavior: Language

The discovery in 2007 of a Neanderthal hyoid bone suggests that Neanderthals may have been anatomically capable of producing sounds similar to modern humans. The hypoglossal nerve, which passes through the canal, controls the movements of the tongue and its size is said to reflect speech abilities. Hominids who lived earlier than 300,000 years ago had hypoglossal canals more akin to those of chimpanzees than of humans.^[31][32][33]

However, although Neanderthals may have been anatomically able to speak, Richard G. Klein in 2004 doubted that they possessed a fully modern language. He largely bases his doubts on the fossil record of archaic humans and their stone tool kit. For 2 million years following the emergence of Homo habilis, the stone tool technology of hominids changed very little. Klein, who has worked extensively on ancient stone tools, describes the crude stone tool kit of archaic humans as impossible to break down into categories based on their function, and reports that Neanderthals seem to have had little concern for the final form of their tools. Klein argues that the Neanderthal brain may have not reached the level of complexity required for modern speech, even if the physical apparatus for speech production was well-developed.^[34][35] The issue of the Neanderthal's level of cultural and technological sophistication remains a controversial one.

Homo sapiens

See also: Anatomically modern humans and Behavioral modernity

Anatomically modern humans first appear in the fossil record 195,000 years ago in Ethiopia. But while they were modern anatomically, the archaeological evidence available leaves little indication that they behaved any differently from the earlier Homo heidelbergensis. They retained the same Acheulean stone tools and hunted less efficiently than did modern humans of the Late Pleistocene.^[36] The transition to the more sophisticated Mousterian takes place only about 120,000 years ago, and is shared by both H. sapiens and H. neanderthalensis.

The development of fully modern behavior in H. sapiens, not shared by H. neanderthalensis or any other variety of Homo, is dated to some 70,000 to 50,000 years ago. The development of more sophisticated tools, for the first time constructed out of more than one material (e.g. bone or antler) and sortable into different categories of function (such as projectile points, engraving tools, knife blades, and drilling and piercing tools) are often taken as proof for the presence of fully developed language, assumed to be necessary for the teaching of the processes of manufacture to offspring.^[34][37]

The greatest step^{[dubious ]} in language evolution would have been the progression from primitive, pidgin-like communication to a creole-like language with all the grammar and syntax of modern languages.^[21] Some scholars believe that this step could only have been accomplished with some biological change to the brain, such as a mutation. It has been suggested that a gene such as FOXP2 may have undergone a mutation allowing humans to communicate.^{[dubious ]} However, recent genetic studies have shown that Neandertals shared the same FOXP2 allele with H. sapiens.^[38] It hence does not have a mutation unique to H. sapiens. Instead, it indicates this genetic change predates the Neandertal - H. sapiens split. There is still considerable debate as to whether language developed gradually over thousands of years or whether it appeared suddenly.

The Broca's and Wernicke's areas of the primate brain also appear in the human brain, the first area being involved in many cognitive and perceptual tasks, the latter lending to language skills. The same circuits discussed in the primates' brain stem and limbic system control non-verbal sounds in humans (laughing, crying, etc.), which suggests that the human language center is a modification of neural circuits common to all primates. This modification and its skill for linguistic communication seem to be unique to humans, which implies that the language organ derived after the human lineage split from the primate (chimps and bonobos) lineage. Plainly stated, spoken language is a modification of the larynx that is unique to humans.^[18]

According to the Out of Africa hypothesis, around 50,000 years ago^[39] a group of humans left Africa and proceeded to inhabit the rest of the world, including Australia and the Americas, which had never been populated by archaic hominids. Some scientists^[40] believe that Homo sapiens did not leave Africa before that, because they had not yet attained modern cognition and language, and consequently lacked the skills or the numbers required to migrate. However, given the fact that Homo erectus managed to leave the continent much earlier (without extensive use of language, sophisticated tools, nor anatomical modernity), the reasons why anatomically modern humans remained in Africa for such a long period remain unclear.

Communication, speech and language

See also: Animal communication and Animal language

Many scientists make a distinction between speech and language. They believe that language (as a context for communication, and primarily as a cognitive ability to form concepts and communicate them) was developed earlier in human evolution, and speech (one of the forms of communication) was developed much later. The presence of speech (without language) is also possible in some cases of human mental retardation or learning disabilities (like Specific Language Impairment) and is also known in the animal kingdom. For instance, talking birds are able to imitate human speech with varying ability. However, this ability to mimic human sounds is very different from the acquisition of syntax. Likewise, the production of speech sounds is not necessary for language use, as evidenced by modern sign languages, which use manual symbols and facial grammar as a basis for language rather than speech. Morse coding system, and the system of the Marine Signal Flags are other forms of communication, but not necessarily language.

It has been claimed that the key feature distinguishing human language from non-human communication systems is recursion.^[41] This linguistic sense of the term recursion involves the insertion (or embedding) of phrases within phrases as exhibited in the complex sentence "(The man with the old crusty eyepatch he wore since WWII) walked to (the store that burned down before his uncle had put down the downpayment)", or the less informative "The man walked to the store which the man who walked to the store walked to". This claim is still held by many researchers, but some evidence has been proposed which calls it into question. Experimenters at the University of Chicago found that starlings (Sturnus vulgaris) can acquire a grammar with recursion.^[42] The experimenters trained starlings on a context-free, center-embedding grammar. They report that starlings were able to recognize utterances that were grammatically acceptable and reject those that were not. Moreover, Daniel Everett claims that Pirahã is a human language that does not exhibit recursion.^[43]

It has been also suggested that the key feature of human language is the ability to ask questions.^[44] Some animals (notably bonobos and chimpanzees), who learned to communicate with their human trainers (using mostly visual forms of communication), demonstrated that they have the ability to correctly respond to complex questions and requests, but they failed to ask even the simplest questions themselves. Conversely, human children are able to ask their first questions (using only question intonation) at the babbling period of their development, long before they start using syntactic structures. It is crucially important that although babies from different cultures acquire native languages from their social environment, all languages of the world without exception – tonal, non-tonal, intonational and accented – use similar rising “question intonation” for yes-no questions.^[45][46] This fact is a strong proof of the universality of question intonation. It should also be noted that arbitrary expressions of joyful excitement, regardless of the language or nationality of the speaker, generally have falling intonation and this may also be universal.

Cognitive development and language

One of the intriguing abilities that language users have is that of high-level reference, or the ability to refer to things or states of being that are not in the immediate realm of the speaker. This ability is often related to theory of mind, or an awareness of the other as a being like the self with individual wants and intentions. According to Chomsky, Hauser and Fitch (2002), there are six main aspects of this high-level reference system:

• Theory of mind
• Capacity to acquire nonlinguistic conceptual representations, such as the object/kind distinction
• Referential vocal signals
• Imitation as a rational, intentional system
• Voluntary control over signal production as evidence of intentional communication
• Number representation

Theory of mind

Simon Baron-Cohen (1999) argues that theory of mind must have preceded language use, based on evidence of use of the following characteristics as much as 40,000 years ago: intentional communication, repairing failed communication, teaching, intentional persuasion, intentional deception, building shared plans and goals, intentional sharing of focus or topic, and pretending. Moreover, Baron-Cohen argues that many primates show some, but not all, of these abilities. Call and Tomasello’s research on chimpanzees supports this, in that individual chimps seem to understand that other chimps have awareness, knowledge, and intention, but do not seem to understand false beliefs. Many primates show some tendencies toward a theory of mind, but not a full one as humans have. Ultimately, there is some consensus within the field that a theory of mind is necessary for language use. Thus, the development of a full theory of mind in humans was a necessary precursor to full language use.

Number representation

In one particular study, rats and pigeons were required to press a button a certain number of times to get food: The animals showed very accurate distinction for numbers less than four, but as the numbers increased, the error rate increased (Chomsky, Hauser & Fitch, 2002). Matsuzawa (1985) attempted to teach chimpanzees Arabic numerals. The difference between primates and humans in this regard was very large, as it took the chimps thousands of trials to learn 1-9 with each number requiring a similar amount of training time; yet, after learning the meaning of 1, 2 and 3 (and sometimes 4), children easily comprehend the value of greater integers by using a successor function (i.e. 2 is 1 greater than 1, 3 is 1 greater than 2, 4 is 1 greater than 3; once 4 is reached it seems most children have an "a-ha!" moment and understand that the value any integer n is 1 greater than the previous integer). Put simply, other primates learn the meaning of numbers one by one similar to their approach to other referential symbols while children first learn an arbitrary list of symbols (1,2,3,4...) and then later learn their precise meanings.^[47] These results can be seen as evidence for the application of the "open-ended generative property" of language in human numeral cognition.^[48]

Linguistic structures

Universal grammar

Main article: Universal grammar

Since children are largely responsible for creolization of a pidgin, scholars such as Derek Bickerton and Noam Chomsky concluded that humans are born with a universal grammar hardwired into their brains. This universal grammar consists of a wide range of grammatical models that include all the grammatical systems of the world's languages. The default settings of this universal grammar are represented by the similarities apparent in creole languages. These default settings are overridden during the process of language acquisition by children to match the local language. When children learn language, they first learn the creole-like features more easily than the features that conflict with creole grammar.^[21]

An issue often cited as support for the Universal grammar theory is the development of Nicaraguan Sign Language. Beginning in 1979, the recently installed Nicaraguan government initiated the country's first widespread effort to educate deaf children. Prior to this there was no deaf community in the country. A center for special education established a program initially attended by 50 young deaf children. By 1983 the center had 400 students. The center did not have access to teaching facilities of any of the sign languages that are used around the world; consequently, the children were not taught any sign language. The language program instead emphasized spoken Spanish and lipreading, and the use of signs by teachers limited to fingerspelling (using simple signs to sign the alphabet). The program achieved little success, with most students failing to grasp the concept of Spanish words.

The first children who arrived at the center came with only a few crude gestural signs developed within their own families. However, when the children were placed together for the first time they began to build on one another's signs. As more and younger children joined, the language became more complex. The children's teachers, who were having limited success at communicating with their students, watched in awe as the kids began communicating amongst themselves.

Later the Nicaraguan government solicited help from Judy Kegl, an American sign-language expert at Northeastern University. As Kegl and other researchers began to analyze the language, they noticed that the younger children had taken the pidgin-like form of the older children to a higher level of complexity, with verb agreement and other conventions of grammar (but no recursion).^[49]

Lexical-phonological principle

Hockett (1966) details a list of features regarded as essential to describing human language. In the domain of the lexical-phonological principle, two features of this list are most important:

• Productivity: users can create and understand completely novel messages.
  • New messages are freely coined by blending, analogizing from, or transforming old ones.
  • Either new or old elements are freely assigned new semantic loads by circumstances and context. This says that in every language, new idioms constantly come into existence.
• Duality (of Patterning): a large number of meaningful elements are made up of a conveniently small number of independently meaningless yet message-differentiating elements.

The sound system of a language is composed of a finite set of simple phonological items. Under the specific phonotactic rules of a given language, these items can be recombined and concatenated, giving rise to morphology and the open-ended lexicon. A key feature of language is that a simple, finite set of phonological items gives rise to an infinite lexical system wherein rules determine the form of each item, and meaning is inextricably linked with form. Phonological syntax, then, is a simple combination of pre-existing phonological units. Related to this is another essential feature of human language: lexical syntax, wherein pre-existing units are combined, giving rise to semantically novel or distinct lexical items.

Certain elements of the lexical-phonological principle are known to exist outside of humans. While all (or nearly all) have been documented in some form in the natural world, very few co-exist within the same species. Birdsong, singing apes, and the songs of whales all display phonological syntax, combining units of sound into larger structures devoid of enhanced or novel meaning. Certain species of primate do have simple phonological systems with units referring to entities in the world. However, in contrast to human systems, the units in these primates' systems normally occur in isolation, betraying a lack of lexical syntax. There is new evidence to suggest that Campbell's monkeys also display lexical syntax, combining two calls (a predator alarm call with a "boom", the combination of which denotes a lessened threat of danger), however it is still unclear whether this is a lexical or a morphological phenomenon.

Pidgins and creoles

Main articles: Creole language and pidgin

Pidgins are significantly simplified languages with only rudimentary grammar and a restricted vocabulary. In their early stage pidgins mainly consist of nouns, verbs, and adjectives with few or no articles, prepositions, conjunctions or auxiliary verbs. Often the grammar has no fixed word order and the words have no inflection.^[21]

If contact is maintained between the groups speaking the pidgin for long periods of time, the pidgins may become more complex over many generations. If the children of one generation adopt the pidgin as their native language it develops into a creole language, which becomes fixed and acquires a more complex grammar, with fixed phonology, syntax, morphology, and syntactic embedding. The syntax and morphology of such languages may often have local innovations not obviously derived from any of the parent languages.

Studies of creole languages around the world have suggested that they display remarkable similarities in grammar and are developed uniformly from pidgins in a single generation. These similarities are apparent even when creoles do not share any common language origins. In addition, creoles share similarities despite being developed in isolation from each other. Syntactic similarities include subject–verb–object word order. Even when creoles are derived from languages with a different word order they often develop the SVO word order. Creoles tend to have similar usage patterns for definite and indefinite articles, and similar movement rules for phrase structures even when the parent languages do not.^[21]

Scenarios for language evolution

Further information: Evolutionary linguistics

All human populations possess language. This includes populations, such as the Tasmanians and the Andamanese, who may have been isolated from the Old World continents for as long as 40,000 years.

Linguistic monogenesis is the hypothesis that there was a single proto-language, sometimes called Proto-Human, from which all other vocal languages spoken by humans descend. (This does not apply to sign languages, which are known to arise independently rather frequently.)

According to the Out of Africa hypothesis, all humans alive today are descended from Mitochondrial Eve, a woman estimated to have lived in Africa some 150,000 years ago. This raises the possibility that the Proto-Human language could date to approximately that period.^[50] There are also claims of a population bottleneck, notably the Toba catastrophe theory, which postulates human population at one point some 70,000 years ago was as low as 15,000 or even 2,000 individuals.^[51] If it did indeed transpire, such a bottleneck would be an excellent candidate for the date of Proto-Human, which also illustrates the fact that Proto-Human would not necessarily date to the first emergence of language.

The multiregional hypothesis would entail that modern language evolved independently on all the continents, a proposition considered implausible by proponents of monogenesis.^[52][53]

See also

• Essay on the Origin of Languages
• Glossary of language teaching terms and ideas
• Language acquisition
• Language isolate
• Man's First Word (children's book)
• Proto-Human language

Footnotes

1. Tallerman, Maggie; Gibson, Kathleen (2011). The Oxford Handbook of Language Evolution. Oxford: Oxford University Press. ISBN 0199541116, 9780199541119. {{cite book}}: Check |isbn= value: invalid character (help)
2. Linguists agree that there are no existing "primitive" languages: all modern human populations speak languages of comparable complexity and expressive power.Pinker, Steven (2004) Language as an Adaptation to the Cognitive Niche In: Christiansen, Morton H.; Kirby, Simon (2004). Language Evolution. Oxford: Oxford University Press. ISBN 0199244839, 9780199541119. {{cite book}}: Check |isbn= value: invalid character (help)
3. Lindsay, Robert (1728). The history of Scotland: from 21 February 1436. to March, 1565. In which are contained accounts of many remarkable passages altogether differing from our other historians; and many facts are related, either concealed by some, or omitted by others. Baskett and company. p. 104.
4. Linguistics 201: First Language Acquisition
5. Premack, David & Premack, Ann James. The Mind of an Ape, ISBN 0-393-01581-5.
6. Kimura, Doreen (1993). Neuromotor Mechanisms in Human Communication. Oxford: Oxford University Press. ISBN 978-0-19-505492-7.
7. Newman, A. J.; et al. (2002). "A Critical Period for Right Hemisphere Recruitment in American Sign Language Processing". Nature Neuroscience. 5 (1): 76–80. doi:10.1038/nn775. PMID 11753419. {{cite journal}}: Explicit use of et al. in: |author= (help)
8. Kolb, Bryan, and Ian Q. Whishaw (2003). Fundamentals of Human Neuropsychology (5th ed.). Worth Publishers. ISBN 978-0716753001.
9. Soma, M., Hiraiwa-Hasegawa, M., & Okanoya, K. (2009). "Early ontogenetic effects on song quality in the [[Bengalese finch]] (Lonchura striata var. domestica): laying order, sibling competition and song sintax" (PDF). Behavioral Ecology and Sociobiology. 63 (3): 363–370. doi:10.1007/s00265-008-0670-9. {{cite journal}}: URL–wikilink conflict (help)
10. Graham Ritchie and Simon Kirby (2005). "Selection, domestication, and the emergence of learned communication systems" (PDF). Second International Symposium on the Emergence and Evolution of Linguistic Communication.
11. Ursula Goodenough (February 5, 2010). http://www.npr.org http://www.npr.org/blogs/13.7/2010/02/did_we_start_out_as_selfdomest.html. {{cite news}}: External link in |newspaper= (help); Missing or empty |title= (help).
12. Mammadov J.M., New system of language, thinkings and reality. // “The Papers of independent Authors” (volume 14). Israel. 2010
13. Kazimov Q.Sh., Language and History. Baku, 2004
14. Kazimov Q.Sh., Mamedov M.B., Azerbaijan Linguistic School
15. Gnatyuk R.V., Azerbaijan Linguistic School
16. Ludmila Esipova, Syntax in schemes. Novosibirsk, 2006.
17. Original of this fragment in Russian
18. Freeman, Scott; Jon C. Herron., Evolutionary Analysis (4th ed.), Pearson Education, Inc. (2007), ISBN 0-13-227584-8 pages 789-90
19. Evolve (tv show): Communication
20. RedOrbit: Primate and Human Language Use Same Brain Regions
21. Diamond, Jared (1992, 2006). The Third Chimpanzee: The Evolution and Future of the Human Animal. New York: Harper Perennial. pp. 141–167. ISBN 0060183071. {{cite book}}: Check date values in: |year= (help)
22. Wade, Nicholas (2006-05-23). "Nigerian Monkeys Drop Hints on Language Origin". The New York Times. Retrieved 2007-09-09.
23. Aronoff, Mark; Rees-Miller, Janie, eds. (2001). The Handbook of Linguistics. Oxford: Blackwell Publishers. pp. 1–18. ISBN 1405102527.
24. Fitch, W. Tecumseh. "The Evolution of Speech: A Comparative Review" (PDF). Retrieved 2007-09-09.
25. Ohala, John J.. (2000). The irrelevance of the lowered larynx in modern man for the development of speech. In Evolution of Language - Paris conference (pp. 171-172).
26. Bickerton, Adam's Tongue (2009).
27. Olson, Steve (2002). Mapping Human History. Houghton Mifflin Books. ISBN 0618352104. Any adaptations produced by evolution are useful only in the present, not in some vaguely defined future. So the vocal anatomy and neural circuits needed for language could not have arisen for something that did not yet exist
28. Ruhlen, Merritt (1994). Origin of Language. New York, NY: Wiley. p. 3. ISBN 0471584266. Earlier human ancestors, such as Homo habilis and Homo erectus, would likely have possessed less developed forms of language, forms intermediate between the rudimentary communicative systems of, say, chimpanzees and modern human languages
29. Mithen, Steven J. (2006). The Singing Neanderthals: The Origins of Music, Language, Mind, and Body. Cambridge: Harvard University Press. ISBN 0-674-02192-4. {{cite book}}: Check |authorlink= value (help)
30. Mithen, Steven (2006). The Singing Neanderthals, ISBN 978-0-674-02559-8
31. Jungers, William L.; et al. (2003). "Hypoglossal Canal Size in Living Hominoids and the Evolution of Human Speech" (PDF). Human Biology. 75 (4): 473–484. doi:10.1353/hub.2003.0057. PMID 14655872. Archived from the original (PDF) on 2007-06-12. Retrieved 2007-09-10. {{cite journal}}: Explicit use of et al. in: |author= (help); Unknown parameter |month= ignored (help)
32. DeGusta, David; et al. (1999). "Hypoglossal Canal Size and Hominid Speech". Proceedings of the National Academy of Sciences of the United States of America. 96 (4): 1800–1804. doi:10.1073/pnas.96.4.1800. PMC 15600. PMID 9990105. Hypoglossal canal size has previously been used to date the origin of human-like speech capabilities to at least 400,000 years ago and to assign modern human vocal abilities to Neandertals. These conclusions are based on the hypothesis that the size of the hypoglossal canal is indicative of speech capabilities. {{cite journal}}: Explicit use of et al. in: |author= (help)
33. Johansson, Sverker (2006). "Constraining the Time When Language Evolved" (PDF). Evolution of Language: Sixth International Conference, Rome: 152. doi:10.1142/9789812774262_0020. Retrieved 2007-09-10. Hyoid bones are very rare as fossils, as they are not attached to the rest of the skeleton, but one Neanderthal hyoid has been found (Arensburg et al., 1989), very similar to the hyoid of modern Homo sapiens, leading to the conclusion that Neanderthals had a vocal tract similar to ours (Houghton, 1993; Bo¨e, Maeda, & Heim, 1999). {{cite journal}}: Unknown parameter |month= ignored (help)
34. Klarreich, Erica (April 20, 2004). "Biography of Richard G. Klein". Proceedings of the National Academy of Sciences of the United States of America. 101 (16): 5705–5707. doi:10.1073/pnas.0402190101. PMC 395972. PMID 15079069. Retrieved 2007-09-10.
35. Klein, Richard G. "Three Distinct Human Populations". Biological and Behavioral Origins of Modern Humans. Access Excellence @ The National Health Museum. Retrieved 2007-09-10.
36. Schwarz, J. http://uwnews.org/article.asp?articleID=37362
37. Wolpert, Lewis (2006). Six impossible things before breakfast, The evolutionary origins of belief. New York: Norton. p. 81. ISBN 0393064492.
38. Krause (2007). Current Biology. 17 (21). doi:10.1016/j.cub.2007.10.008. PMID 17949978 http://www.cell.com/current-biology/abstract/S0960-9822%2807%2902065-9. {{cite journal}}: Missing or empty |title= (help); Unknown parameter |coauthors= ignored (|author= suggested) (help)
39. Minkel, J. R. (2007-07-18). "Skulls Add to "Out of Africa" Theory of Human Origins: Pattern of skull variation bolsters the case that humans took over from earlier species". Scientific American.com. Retrieved 2007-09-09.
40. Klein, Richard. "Three Distinct Populations". Retrieved 2007-11-10. You've had modern humans or people who look pretty modern in Africa by 100,000 to 130,000 years ago and that's the fossil evidence behind the recent "Out of Africa" hypothesis, but that they only spread from Africa about 50,000 years ago. What took so long? Why that long lag, 80,000 years?
41. Hauser 2002.
42. Gentner, Timothy Q.; Fenn, Kimberley M.; Margoliash, Daniel; Nusbaum, Howard C. (27 April 2006). "Recursive syntactic pattern learning by songbirds" (PDF). Nature. 440 (7088): 1204–1207. doi:10.1038/nature04675. PMC 2653278. PMID 16641998.
43. Everett, Daniel L. (August–October 2005). "Cultural Constraints on Grammar and Cognition in Pirahã: Another Look at the Design Features of Human Language" (PDF). Current Anthropology. 46 (4): 634. doi:10.1086/431525.
44. Joseph Jordania (2006). Who Asked the First Question? The Origins of Human Choral Singing, Intelligence, Language and Speech. Tbilisi: Logos. ISBN 99940-31-81-3.
45. Bolinger, Dwight L. (Editor) 1972. Intonation. Selected Readings. Harmondsworth: Penguin, pg.314
46. Cruttenden, Alan. 1986. Intonation. Cambridge: Cambridge University Press. Pg.169-174
47. S. Carey, Mind Lang. 16, 37 (2001)
48. Hauser, Chomsky, Fitch, Science, Vol. 298, No. 5598 (Nov. 22, 2002), p. 1577
49. "A Linguistic Big Bang". The New York Times.
50. Ruhlen, Merritt (1996). "Language Origins". National Forum. Retrieved 2007-11-10.
51. Whitehouse, David (2003-06-09). "When Humans Faced Extinction". BBC News Online. Retrieved 2007-11-10.
52. Wade, Nicholas (2003-07-15). "Early Voices: The Leap to Language". The New York Times. Retrieved 2007-09-10.
53. Sverker, Johansson. "Origins of Language — Constraints on Hypotheses" (PDF). Retrieved 2007-09-10.

References

• Allott, Robin (1989). The Motor Theory of Language Origin. Sussex, England: Book Guild. ISBN 0-86332-359-6.
• Botha, R. and C. Knight (2009). The Prehistory of Language. Oxford: Oxford University Press. ISBN 9780199545872.
• Botha, R and C. Knight (2009). The Cradle of Language. Oxford: Oxford University Press. ISBN 9780199545858.
• Cangelosi, A., A. Greco, and Stevan Harnad. (2002) "Symbol grounding and the symbolic theft hypothesis." Simulating the Evolution of Language, edited by A. Cangelosi and D. Parisi. London: Springer.
• Crystal, David (1997). The Cambridge Encyclopedia of Language. Cambridge: Cambridge University Press. ISBN 0-521-55967-7.
• Dawkins, Richard. 2004. The Ancestor's Tale: A Pilgrimage to the Dawn of Life. London: Weidenfeld and Nicolson.
• Deacon, Terrence William (1997). The Symbolic Species: The Co-evolution of Language and the Brain. New York: W.W. Norton. ISBN 0-393-03838-6.
• Dunbar, R.I.M. (1996). Grooming, Gossip and the Evolution of Language. London: Faber and Faber. ISBN 0-571-17396-9.
• Givón, T. (2002). "The evolution of language out of pre-language." Typological studies in language 53. Amsterdam: John Benjamins. ISBN 1-58811-237-3.
• Harnad, S.R., J. B. Lancaster, and H.D. Steklis (1976). Origins and Evolution of Language and Speech. New York: New York Academy of Sciences. ISBN 0890720266.
• Hauser, Marc D.; Chomsky, Noam; Fitch, W. Tecumseh (2002). "The faculty of language: What is it, who has it, and how did it evolve?". Science. 298 (5598): 1569–1579. doi:10.1126/science.298.5598.1569. PMID 12446899.
• Hurford, James R. (1990). "Nativist and functional explanations in language acquisition." Logical Issues in Language Acquisition, edited by I.M. Roca, 85–136. Dordrecht: Foris. ISBN 9067655066.
• Kenneally, Christine (2007). The First Word: The Search for the Origins of Language. New York: Viking.
• Knight, C., M. Studdert-Kennedy and J. R. Hurford (eds), 2000. The Evolutionary Emergence of Language. Cambridge: Cambridge University Press.
• Komarova, N.L. (2007). "Language and mathematics: An evolutionary model of grammatical communication." History & Mathematics, edited by Leonid Grinin, Victor C. de Munck, and Andrey Korotayev, 164–179. Moscow: KomKniga/URSS. ISBN 9785484010011.
• Laitman, J.T. and Reidenberg, J.S. (2009) The evolution of the human larynx: Nature’s great experiment. In: Fried M.P., Ferlito, A. eds. The Larynx, 3rd ed., Plural, San Diego, 19-38.
• Ostler, Nicholas. Empires of the Word: A Language History of the World. HarperCollins.
• Pinker, Steven (2000). The Language Instinct: How the Mind Creates Language. New York: Harper Perennial Modern Classics. ISBN 0-060-95833-2.
• Pollick, Amy. S and Frans B.M. de Waal (2007). "Ape gestures and language evolution." [1] Proceedings of the National Academy of Sciences 104.19, 8184–8189. (Also: Popular summary by Liz Williams, "Human language born from ape gestures", Cosmos, May 1, 2007.)
• Saussure, Ferdinand de (1986). Course in General Linguistics, translated by Roy Harris. Chicago: Open Court. (English translation of 1972 edition of Cours de linguistique générale, originally published in 1916.)
• Vajda, Edward. "The origin of language."

External links

• Lieberman, Philip; McCarthy, Robert C.; Strait, David (May 2006). "The recent origin of human speech". J. Acoust. Soc. Am. 119 (5): 3441–3441. Retrieved June 2010. {{cite journal}}: Check date values in: |accessdate= (help)
• Lieberman, P. (2007). "The evolution of human speech: Its anatomical and neural bases" (PDF). Current Anthropology. 48 (1): 39–66. doi:10.1086/509092.

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