Статті в журналах з теми "Developing natural - science competence in future primary school teachers"

Schoolchildren’s natural science competence development is inseparable from teachers’ natural science competence, the integral part of which are subject, didactic and managerial abilities. Competence (es) acquisition during the studies at university is not a final process. Competence improvement, enrichment continues during the whole period of active pedagogical work. In the months of January-February 2018, a qualitative, limited amount research was carried out. 60 primary school teachers from more than 25 Lithuanian schools participated in the research. Research data were analysed using a content analysis method. Research results revealed that most primary school teachers value their knowledge in natural science field as sufficient. Teachers accentuate that their competences are proper and emphasize their lifelike and long work experience importance. Part of the teachers accentuate constant natural science education subject knowledge renewal. Only a small part of teachers notice that they lack knowledge in natural science field. Research result analysis showed that most of primary school teachers develop natural science competence independently using various information sources. A big part of teachers develop natural science competence participating in formal specially organised activities. Not a small part of teachers accentuate practical natural science competence development. Research results revealed that most primary school teachers give average evaluation to their competence in teaching natural science (world cognition). Only a small part of teachers attribute a high value to this competence of theirs. Research result analysis showed that primary school teachers teaching students natural sciences (world cognition), encounter various problems. The bigger part of teachers experience problems, related to the teaching process: lack of devices, low students’ teaching motivation, teaching content shortcomings. A big part of teachers teaching natural science subjects (world cognition) experience social – organisational problems: a lack of time, unfavourable conditions, a lack of support. Teacher opinion analysis of what needs to be changed /improved in natural science primary school teacher training/preparation revealed that the biggest part of teachers offer to improve future teachers’ practical abilities/skills. Part of teachers offer to better develop special competences, related to natural science education, to improve material supply of the study process. Keywords: content analysis, primary school, science education, subject knowledge.

At the present stage of the development of Kazakhstani higher education in the context of the transition to the updated content of education, the problem of future primary school teachers’ professional training is relevant. It is not enough to identify the problems in the training of future specialists in the field of primary education in order to list the competencies that a graduate should master. It is reasonable to consider the model of the predicted result as a system of interrelated components. In this regard, this study aims to identify and substantiate the structural components of the professional competence of primary school teachers. The main methods of studying this problem are comparative and model methods, which allow to to take account of various research approaches for understanding the structure of teachers’ professional competence. The results of the study indicate the process of developing analytical, diagnostic, and prognostic professional actions make up the structure of the professional competence of an elementary school teacher, other important characteristics of the teachers’ professional development, such as communicative, are also being successfully improved, which also confirms the integrative basis of the structure of professional competence.

The article characterizes and experimentally substantiates the criteria, indicators and levels of methodical competence of future teachers; illustrated by didactic means propaedeutic training of students for the instructional activities in primary school. The influence of metaprofessional (universal) instrumental competences formed by future teachers at Nature Science lectures on the unconscious, on the intuitive level, through the "insight", their acquisition of the methodological experience is proved.

Teacher's abilities to understand the benefits and use of media literacy play an important role in dealing with children as digital natives. Media literacy education can be an instrument through the use of blended-learning websites to address the challenges of education in the 21st century and learning solutions during and after the Covid-19 pandemic. This study aims to figure the teacher's perspective in understanding media literacy as an instrument for implementing blended-learning in early-childhood classes. Using a qualitative approach, this study combines two types of data. Data collection involved kindergarten teachers, six people as informants who attended the interviews and twenty-six participants who filled out questionnaires. Typological data analysis was used for qualitative data as well as simple statistical analysis to calculate the percentage of teacher perspectives on questionnaires collected the pandemic. The findings show five categories from the teacher's perspective. First, about the ability to carry out website-based blended-learning and the use of technology in classrooms and distance learning is still low. It must be transformed into more creative and innovative one. Encouraging teacher awareness of the importance of media literacy education for teachers as a more effective integrated learning approach, especially in rural or remote areas, to be the second finding. Third, national action is needed to change from traditional to blended-learning culture. Fourth, the high need for strong environmental support, such as related-party policies and competency training is the most important finding in this study. Finally, the need for an increase in the ease of access to technology use from all related parties, because the biggest impact of the Covid-19 pandemic is on ECE, which is closely related to the perspective of teachers on technology. 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The purpose of the article: to process diagnostic methods for the level of communicative and organizational abilities of future teachers. Methodical tools for the study of communicative competence of students, are directed at determining the power structures that ensure the success of professional activities of future professionals and the possibility of practical implementation of the acquired knowledge and personal qualities. The article substantiates the methodological tools of research of communicative competence of students, which is aimed at determining the properties that ensure the success of professional activities of future professionals and the possibility of practical implementation of the acquired knowledge and personal qualities. It is emphasized that communicative competence is a demonstrated area of successful communicative activity based on acquired values and strategies of language communication, supported by language skills and abilities, and communicative competence is defined in modern science as an integrative personal resource that ensures successful communication. It is determined that to identify the manifestation of the level of communicativeness of teachers it is necessary to diagnose communicative and organizational abilities, the ability to communicative self-control and the diagnosis of empathic abilities. The results of diagnosing communication and organizational skills are presented. It is emphasized that the lowest level of formation of future primary school teachers is found in such quality as empathic abilities. It is proposed to introduce specialized courses aimed at developing professionally significant communicative and organizational skills of future teachers on the basis of communicative practices, project activities, development of reflexive abilities, development of self-education skills, etc. as areas of solving problems of improving communicative competence. It is concluded that diagnostics is primarily a process of analysis, which allows to identify a system of rules, guided by which people organize their interaction, to understand which rules promote and which hinder the successful implementation of communicative interaction. Diagnosis of the level of formation of communicative qualities of future professionals is an integral part of the system of monitoring the quality of education in higher education institutions.

The flipped learning has a lot of advantages in university teaching, especially in the era of information technology explosion and in response to the current Covid-19 pandemic. Designing integrated natural science topics (DINST) is an important competence of elementary school teachers in creating an attractive teaching topic with interdisciplinary integration. The purpose of this study is to determine the effectiveness of applying the flipped learning in developing DINST competence compared to applying the traditional teaching model for prospective elementary teachers. The article used a quasi-experimental method. The 86 fourth-year pre-service elementary teachers were divided into two groups in which the experimental group was applied the flipped learning and the control group was done by traditional teaching. This research was conducted in a 7-week course in the semester I (2020 – 21) through the Module of “Scientific Discovery Activities Organization” at one public university of Education in Vietnam. The article has identified the process of organizing teaching to develop DINST competence for future elementary teachers. Pre- and post- tests were designed and applied on both groups. A questionnaire to collect information on the experimental group's learning attitude was also carried out, which helps to further explain our research results. Descriptive statistics and quantitative data analysis were performed on SPSS. The research results have shown that applying the flipped learning has contributed to the development of DINST competence for prospective elementary teachers better than teaching in the traditional way. The research has contributed to proving the positive role of the flipped learning in developing the future Elementary teachers’ competence to integrated teaching and showed that this model can be widely applied in Vietnam's teacher training institutions

The relevance of the study is based on the development of algorithmic methodological and mathematical literacy of future primary school teachers, the use of knowledge, practical skills and abilities acquired at universities in real professional activities, in everyday life. In this regard, this article is aimed at determining the dynamics of the development of algorithmic methodological and mathematical literacy of the future teacher through exercises of various content and directions. The main bases of research on the development of algorithmic, methodological and mathematical literacy of the future teacher of primary education were taken as systematic, operational, anthropological, axiological and competence. Systematic platform for the development of literacy on the basis of a systematic position in teaching methodological and mathematical materials were considered. The research included algorithmic literacy of 68 new students, a survey of 3rd year students 38 3rd year students and 38 primary school teachers. The essence and methods of teaching exercises aimed at developing literacy were revealed. The materials of the article are practical assistance to young teachers of pedagogical higher educational institutions of specialties 6B013 – Pedagogy and methods of primary education, pedagogical colleges and schools. Keywords: algorithmic methodological and mathematical literacy; functional literacy; algorithmic literacy; mathematical literacy; methodological literacy; exercises aimed at developing literacy.

Natural science education in primary school is not only important, but it is also problematic. The importance, first of all, lies in the fact, that natural science education is an inseparable part of general education. Natural science education involves various components - ecological, environmental, healthy lifestyle, harmonious development and other. Experimental- research activity is especially important. Effective all component integration into education process in primary classes remains problematic. This is actual not only in Lithuania. It is obvious, that in order to understand natural science education peculiarities working with the younger age children, exhaustive research are necessary and on their basis modelled, adjusted and developed natural science education in primary school. Only qualitative natural science education, acquired in primary school, can guarantee proper continuation of natural science education in basic and secondary school. Research aim is to analyse primary school teachers’ position on natural science education question, i.e., to ascertain how teachers value personal preparation according to major natural science education fields, what natural science education improvement ways they discern, and what activity ways in natural science education process they like best. The research is quantitative, pilot, of limited amount. The research was carried out between January and February 2018. Working primary school teachers from various Lithuanian primary schools participated in the research. Totally, there were 60 teachers (all women) from more than 25 schools. The carried-out research allows asserting, that primary school teachers’ professional preparation in natural science education sphere remains actual. Practical work organisation is considered the most appropriate activity. Individual students’ differences are tried to be satisfied and considered the least by the teachers. Though teachers tend to demonstrate various experiments (16.0%), research activity is not prevalent (2.3%). A similar situation is observed speaking about technology involvement in education process. Teacher preparation to organise and realise natural science education in primary school is basically valued positively, however, it is diverse. The best preparation is fixated in biology science spheres (e.g., “Green plants” /PI=0.83, SD=0.22/, “People and other animals” /PI=0.80, SD=0.21/, “Life (vital) processes” /PI=0.73, SD=0.21/ and other). The weakest preparation is fixated in physics science fields (e.g., “Electricity (electrical) phenomena” /PI=0.55, SD=0.26/, “Forces and movement” /PI=0.56, SD=0.25/, “Light and sound” /PI=0.57, SD=0.26/ and other). The preparation in chemistry science field is considered average e.g., “Substance changes” /PI=0.64, SD=0.24/, “Substance mixture separation” /PI=0.61, SD=0.23/ and other). Preparation in scientific research field is also valued as average (PI=0.63, SD=0.18) (PI – preparation index). Respondents consider resources/equipment the most important way of natural science education process improvement. Teacher professional improvement possibilities are considered the least important way of improvement. Lessons based on research (or other educational activities) are not considered a very important way of natural science education improvement. More exhaustive research are necessary in future for analysing primary school teacher natural science competence problems, also seeking to better understand experimental-research activity organisation peculiarities in education process. Keywords: pilot research, primary school, professional improvement, science education.

The article focuses on the designing of disciplines, based on the competence and activity approach to the content and methods of training of future teachers in the research psycho-pedagogical master’s program. Particular attention is paid to the creation of problematic situations, in which research master students find themselves in the position of supervisors examining the educational activity. The authors provide examples of how students perform expert-analytical tasks based on analysis of training activities developed in the theory of developmental education by Davydov scholar school. There are samples of test items to assess how students have learned the content of the discipline, as well as to determine their ability and willingness to perform professional activities. These tasks were performed by master students as well as developing training teachers in elementary school and secondary school teachers. Testing the «Design and research of learning activities in the science lessons in secondary school» course allows us pre argue that psycho-pedagogical research master program allows to train future research training specialist using professional tasks related to expertise and design of training activities. Master students reach an acceptable level of competence for the performing the expert-analytical tasks. We propose to discuss if natural-scientific training of master students is one of the conditions for full cooperation between future research training specialist and teachers in order to improve the education of adolescents in the field of natural sciences.

School, particularly primary school, plays a special and unique role in education. It joins teachers and students together, in order to show children and youths the complex reality of the world. Educational processes implemented in the following institution can reflect knowledge transmission or can be based on transaction models. Education is stimulating, experimental and exploratory as it guides students to the world of forming questions, searching for answers and developing conclusions. Unfortunately, this model is rather uncommon in Polish primary schools. This publication presents how experimenting, used by teachers, could introduce 7-year-old students in the first grade of primary school, into the world of knowledge and natural science competence. It also shows how experimenting affects the level of students’ education and natural science competence. The research aimed for describing methods of experimenting with first grade students in science education as well as explaining the connection between applying experiments in science education and students’ level of skills and knowledge. The research used a method of pedagogical experiment - quasi-experimental testing based on initial and final measurement using practical tests. The study included 307 primary school first-graders. The studies have established that there are dependencies between experimenting in science education as well as knowledge and skills level among the first grade primary school students, taking into account subjects’ gender. At the end, conclusions were also drawn regarding the possibilities for more extensive use of experimentation in Polish schools.

The success of modern transformational changes in public life depends crucially on the quality of professional training of future professionals. In this view, under conditions of reforming the Ukrainian society, a social significance of a competent specialist is extremely growing. An important area of transformational changes is the training of future teachers on a competence basis, which is conditioned by qualitative features of the competence-based paradigm in the context of modern socio-economic and spiritual development of society, changes in the nature and content of work, complexity as well as increasing requirements to performance results, on the one hand; and on the other hand – by the need to more quickly overcome the negative phenomena occurring in the system of training future professionals. The modern labour market, above all, provides for the presence of a professionally competent worker who is fluent in the profession-centred assignments and well-oriented in related fields, ready for continuous personal growth, social and professional mobility. These requirements can be fully applied to the training intended for the future teachers. At the same time, since the future specialist of any profession begins with the school, namely "the school stands for their teacher", the solution of these complicated problems depends entirely on the teacher, the quality of his / her training. As the teacher’s professional activity under conditions of the New Ukrainian school is filled with qualitatively new content, conditioned by the new demands of the society, the professional requirements to the training of the future teacher are significantly strengthened. This outlines a radical change in approaches to the process of professional training intended for future teachers. This is the general pedagogical core of this training that is important, because it deals with the equipping of students with knowledge of the basics of pedagogical theory and school practice, the development of professional thinking, the developed pedagogical skills and abilities to implement social functions alongside the subject component of the professional development aimed at mastering the logic of deploying the specifics of the content. Based on the understanding that each subject, including Biology in particular, is a means of developing the student's personality; the problem of forming future Natural Science teachers’ subject competence in Biology is becoming extremely important. This also requires the expansion of scientific knowledge about the structure of originality, in particular the subject competence in Biology under conditions of the bachelor courses, where basic higher education is obtained.

This study aimed to examine the implementation pattern of the constructivist theory in limited face-to-face learning (PTMT). The method used was descriptive qualitative with the subject of teachers in the Malang City area. Data was collected by using a survey distributed online through Google Forms. The results showed that the implementation pattern ofconstructivist theory in limited face-to-face learning (PTMT) was carried out through 5 (five) base of learning implementation, namely the application of problem-based learning, the application of project-based learning, the use of digital-based teaching materials and media, the application of psychosocial learning and contextuallearning. Teachers carried out limited face-to-face learning by applying constructivist theory massively and gradually, starting from planning, the process of learning activities, and learning evaluation. In addition to the use of media and 5M learning models in this study, the application of constructivist theory in PTMT learning aimed to help students become more active and teachers as moderators be more innovative. Learning process carried out at the elementary school level was only 50 percent attendance at the maximum. The implementation of student-centered learning showed 45% was very good, 50% was good, 2.5% was good, 2.5% was not good. The results showed that the inhibiting factor for student-centered implementation was the limited duration of time in learning. On the other hand, there were also restrictions on interactions carried out in the classroom so that teachers experienced a decline in exploring the learning process. Keywords: constructivism theory. limited face-to-face learning, elementary school. References: Adiyono, A. 2021. Implementasi Pembelajaran: Peluang dan Tantangan Pembelajaran Tatap Muka Bagi Siswa Sekolah Dasar di Muara Komam. 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STEAM-based learning is a global issue in early-childhood education practice. STEAM content becomes an integrative thematic approach as the main pillar of learning in kindergarten. This study aims to develop a conceptual and practical approach in the implementation of children's education by applying a modification from STEAM Learning to R-SLAMET. The research used a qualitative case study method with data collection through focus group discussions (FGD), involving early-childhood educator's research participants (n = 35), interviews, observation, document analysis such as videos, photos and portfolios. The study found several ideal categories through the use of narrative data analysis techniques. The findings show that educators gain an understanding of the change in learning orientation from competency indicators to play-based learning. Developing thematic play activities into continuum playing scenarios. STEAM learning content modification (Science, Technology, Engineering, Art and Math) to R-SLAMETS content (Religion, Science, Literacy, Art, Math, Engineering, Technology and Social study) in daily class activity. Children activities with R-SLAMETS content can be developed based on an integrative learning flow that empowers loose part media with local materials learning resources. Keyword: STEAM to R-SLAMETS, Early Childhood Education, Integrative Thematic Learning References Ali, E., Kaitlyn M, C., Hussain, A., & Akhtar, Z. (2018). the Effects of Play-Based Learning on Early Childhood Education and Development. Journal of Evolution of Medical and Dental Sciences, 7(43), 4682–4685. https://doi.org/10.14260/jemds/2018/1044 Ata Aktürk, A., & Demircan, O. (2017). A Review of Studies on STEM and STEAM Education in Early Childhood. Journal of Kırşehir Education Faculty, 18(2), 757–776. Azizah, W. A., Sarwi, S., & Ellianawati, E. (2020). 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Embedding play-based learning into junior primary (Year 1 and 2) Curriculum in WA. Australian Journal of Teacher Education, 43(1), 112–126. https://doi.org/10.14221/ajte.2018v43n1.7 Kennedy, A., & Barblett, L. (2010). Supporting the Early Years Learning Framework. Research in Practise Series, 17(3), 1–12. Keung, C. P. C., & Cheung, A. C. K. (2019). Towards Holistic Supporting of Play-Based Learning Implementation in Kindergartens: A Mixed Method Study. Early Childhood Education Journal, 47(5), 627–640. https://doi.org/10.1007/s10643-019-00956-2 Keung, C. P. C., & Fung, C. K. H. (2020). Exploring kindergarten teachers’ pedagogical content knowledge in the development of play-based learning. Journal of Education for Teaching, 46(2), 244–247. https://doi.org/10.1080/02607476.2020.1724656 Krogh, S., & Morehouse, P. (2014). The Early Childhood Curriculum : Inquiry Learning Through Integration. Liao, C. (2016). 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The dynamic development of modern society dramatically changes the educational orientations and priorities. This is especially true of the higher education system, which must respond in a timely manner to the new challenges for the preparation of competitive future professionals. The renewal of the philosophy of school natural education, due to the need for its correlation with the current level of scientific knowledge, as well as with the realities of the modern world. In this connection, there is a problem of professional training of the future biology teacher of the new formation, oriented on innovative pedagogical activity. The recognition of the modern teacher as the subject of innovative changes defines new targets in his vocational training system. The problem of professional training of the future biology teacher does not lose its relevance. The new paradigm of science education necessitates constructive changes in the professional training of the future teachersubjectist. First of all, the process of becoming a future teacher should be professionally and pedagogically oriented. An important component of the professional development of a modern biology teacher is his personal qualities formed in the process of pedagogical training that determine the professional orientation of the future specialist. In this regard, the professional training of the future teacher of the natural sector should integrate in the content of higher education the idea of developing the creative potential of the student's personality, the recognition of students as subjects of the educational process. And the process itself, the formation of the professional competence of the future teacher, should be guided by modern natural science knowledge. The peculiarity of teaching biology in high and high school requires the modern teacher to have specific qualities, which in the conditions of the New Ukrainian School are of particular relevance. Among the most significant are the responsibility of the teacher for the results of his teaching activities. At present, the modern school is waiting for a teacher of a new formation, which is characterized by creative thinking, innovative pedagogical activity, the ability to self-reflection, which significantly expands its role functions. The development of new directions in the training of biology teachers objectively requires a rethinking of the content, forms and methods of pedagogical education, development of new approaches to teaching. In addition, the focus on European educational standards, necessitates the study of foreign teacher training experience in the context of innovation. Thus, the European vectors for the development of higher education in Ukraine necessitate changes in the methodological and psychological-pedagogical foundations of modern higher education of future biology teachers. It is the practice-oriented character of the pedagogical training of the future teacher that will provide the updating of the content of the system of vocational training of future teachers, which will significantly increase its competitiveness.

The article substantiates the student's science and research activity as a condition for developing the creative competence of the future primary school teacher. The scientific novelty of the article is to identify the peculiarities of students’ research work organization in the conditions of university education. The creative potential is defined as a set of personality traits, expressed in the abilities, knowledge, skills, mental characteristics of the teacher, readiness for creative pedagogical activity, to change, rejection of stereotypes in pedagogical activity, finding original solutions to complex pedagogical problems in a situation of uncertainty etc. The experience of organizing research activity of students of specialty 013 «Primary education» of educational degree «Bachelor» at Mukachevo State University has been presented. The peculiarities of the organization of the scientific-methodological seminar "Professional training of the teacher in the conditions of European integration processes", aimed at identifying, promoting innovative pedagogical methods, work of the scientific student circle "Perspectives of educational and pedagogical science" have been characterized. It has been emphasized that the competences in the field of research activity allow students to see and analyze problems, make assumptions about their solution; be able to receive and select information according to the purpose or need, use it to achieve the goal and own development; be able to make assumptions about the possible causes and effects of the phenomena of the material and idealistic world, to formulate and justify hypotheses; to set goals, to analyze situations, to receive and practically realize the finished product, to carry out reflection and self-assessment; conduct individual and collective activity. It has been suggested to introduce into the educational process of preparation of future primary school teachers a selective course, which would contribute to the teaching of modern strategies of actualizing the creative potential of the personality of teachers and students of primary school age. It has been concluded that the student's Серія Економіка. Випуск 1(13) 123 research activity in the conditions of university education contributes to the formation of a future primary school teacher interest in research, search for alternative means and ways of solving the problem, prognostic thinking, activation of intellectual potential for the production of new ideas. Key words: research activity, organization of student activity, university education, future primary school teacher

The need to update the curriculum and the Curriculum framework of general education has been discussed for several years, as long as a year ago, the renewal work of primary and basic education curriculum began, and this year the renewal of the secondary and preschool education curriculum started. The curriculum of the general preschool education is described for one year, with the possibility for the child to study for the second year. The preschool education programme is not structured in separate subjects – the knowledge is acquired integrally, by developing seven competencies in all activities in which the child participates, in order to ensure the balance and coherence of all competencies in different content areas. Excluded content areas are given equal volume. It is being focused on the purpose and goals of preschool education, areas of achievement and intended achievements. The learning content is divided into five areas of learning content: • language education; • social education; • STEM education(natural science, mathematics and informatics, technological education); • health and physical education; • artistic education. The general curricula for pre-primary, primary, basic and secondary education must ensure vertical and horizontal coherence of content, possible interdisciplinary links, and indicate how they can be meaningfully disclosed including the interdisciplinary topics set out in the General curriculum framework updating guidelines: • personal power, • cultural identity and community spirit, • sustainable development. The volumes of primary, basic and secondary education curricula are presented distinguishing between compulsory subject content (about 70 per cent) and optional content (about 30 per cent), which is selected and modelled by the teacher himself, taking into account school, classroom context, student needs, achievements, possibilities and in coordination with other teachers as required. When implementing optional content, more time is devoted to the development of certain skills, values, and learning of subject topics. Project works can be organised, interdisciplinary themes can be developed, time can be allocated for cognitive, cultural, artistic, and creative activities. According to the concept of the Guidelines for the Renewal of the General Curriculum Framework, this distribution of the content ratio is focused on deeper learning, integration, topic development, competence development. Keywords: curriculum framework, general education, interdisciplinary topics, project works.

The problem and the aim of the study. The increased use of digital technologies in higher education has lately been accelerated by the COVID-19 pandemic, thus creating a number of challenges related to the implementation of distance e-learning. The duration of the epidemic situation and the limitations related to the organization of in-person education reveal the simulation training as the main opportunity for the implementation of any practical training of the students in the methodological disciplines in their university preparation as future teachers. The aim of the study is to survey the possibilities of developing the modeling competence of students concerning the simulation of practical training in computer-based distance learning. Research methods. Within the framework of the research, which is oriented at establishing the levels of structure defining competencies (the reflective multisensory competency; the creative competency; the symbolic competency of sign and symbol nature) were measured systematically through goal-oriented observation during practice seminars in the disciplines taught to students. Since both disciplines are practically oriented and suggest the instruction of teaching methods, they entail the design of didactic situations in pre-school and of lessons in primary school education, which facilitates the registering of the levels of structure defining competences, including the competence for cognitive modelling, preeminently formed in the conditions of simulative distance education in electronic environment. The subjects participating in the research are 158 Bachelor's students trained in the professional field Education Science. Results. A low level of the skills for the application of cognitive modelling in the activities students conduct in relation to the design of pedagogical situation and lessons as an element in their practical experience and preparation in the realization of such situations in rela school conditions. The pilot study diagnoses a low level of student achievements in over 65% of the subjects as regards the academic disciplines the study concerns in terms of basic modelling skills. By contrast, in the course of the simulative education a growth of 45% has been established in the concluding study. The intersections and correlations between the level of development of the specific competences and the simulative education have also been established. Statistically verifiable differences (p=<0.05) were established between the pilot and the concluding studies in view of the reflective and creative competency. The symbolizing competency, however, requires further efforts. Conclusion. The results draw the attention to the necessity to look for opportunities to guarantee the creation of the models, in the context of simulative education, with three basic emphases: state (value, role and function in the specific context, phase of development of the pedagogical situation and/or lesson), structure (position of the model in relation to the other models/objects and of its own components – the components of the pedagogical situations and lesson projects) and evolution (opportunities for the design of pedagogical situations and/or lessons after reflection based on simulations).

Indonesia is a country that has a high potential for natural disasters. Picture story book is a form of disaster management learning that can help children from an early age to prepare for a natural disaster. The aims of this study to develop story books as a disaster management learning media, to improve knowledge and skills of children and teacher about the understanding, principles, and actions of rescue when facing the natural disasters, to increase the teacher’s learning quality in disaster management. Developmental research approach is used to execute the study. A total of 48 children aged 5-6 years have to carry out pre-test and post-test. Pre-test data shows that children's knowledge about disaster management with an average of 47.92% and its improved at post-test with 76,88%. Five theme of story books involves floods, landslides, earthquakes, tsunamis, lands and forest fires is the product. 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In recent years, STEAM (Science, Technology, Engineering, Art, and Mathematics) has received wide attention. STEAM complements early childhood learning needs in honing 2nd century skills. This study aims to introduce a loose section in early childhood learning to pre-service teachers and then to explore their perceptions of how to use loose parts in supporting STEAM. The study design uses qualitative phenomenological methods. FGDs (Focus Group Discussions) are used as data collection instruments. The findings point to two main themes that emerged from the discussion: a loose section that supports freedom of creation and problem solving. Freedom clearly supports science, mathematics and arts education while problem solving significantly supports engineering and technology education. Keywords: Early Childhood Educators, Loose-part, STEAM References: Allen, A. (2016). Don’t Fear STEM: You Already Teach It! Exchange, (231), 56–59. Ansberry, B. K., & Morgan, E. (2019). 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<p>In a country where there is a consistent loud outcry about school achievement of youth<br />in the final school examination in Grade 12, attention has recently shifted to children in<br />the primary school. The very founding of this journal was motivated by a deep concern<br />about research in childhood education and children’s lives. Questions were being asked<br />about what happens in the first years of schooling, about the suitability of the national<br />curriculum for such a diverse population, about specialised research in the field of<br />learning in the early years, and about teaching with care and with insight, knowing<br />who the children of this nation are.<br />The journal took an early stand when, at its launch in 2010, the editor noted that the<br />notion of a national foundation phase curriculum assumes the existence of a ‘national’<br />Grade 1 learner. In South Africa there are children who come to school, well prepared<br />for the demands of school – and there are others who come with only their survival<br />records in homes of extreme poverty, of absent parents and of families broken by the<br />effects of the history of the nation and the effects of disease. Much as we would like<br />to see a standard of performance expected from the ‘national’ young learner, we need<br />to see the layers of diversity too. Can such a stratified population, socially fractured<br />in many ways, truly enact a differentiated curriculum for children who have so much<br />and for children who have so little at the same time and at the same pace? Can our<br />foundation phase classes be truly inclusive?<br />It remains a vexing question. Much research is needed to even try to give a robust<br />response. In recent years, in the research of the Centre for Education Practice Research<br />at my home institution, we have encountered more than 3000 children between five<br />and seven years old in an extensive interview test of mathematical cognition. In the<br />process we found children who had never encountered a print drawing and children<br />who did not know that a page can be turned. However, the very same children had<br />a perfectly normal idea of approximate number and size. We regard this as evidence<br />that they have the core knowledge of number that has to be developed by systematic<br />instruction and caring apprenticeship in classrooms. But for that they would need<br />teachers who know them as well as they know the latest curriculum and its suggested<br />tools of teaching.<br />This is but one example of how important teacher education is and how important<br />it is that we should investigate both learners and teachers, but also teacher education<br />and teacher educators. Teachers and their educators at universities have their own<br />view of children, of learning and of childhood. Much as we may all agree that the<br />core activity of schools is for the young to learn the three Rs and the subject areas of<br />the curriculum, there are researchers who are opposed to a developmental view of<br />learning. The journal’s stance is that, in the Vygotskian tradition (Kozulin, 1990), the<br />young learn and are initiated – and thus develop – in the work of school (and society).<br />SAJCE– December 2014<br />ii<br />In the SAJCE we welcome different views on child learning and celebrate South<br />Africa’s researchers who argue that “pedagogical ‘know-how’ and views of child and<br />childhood constitute the subject knowledge that is foundational in the foundation<br />phase curriculum” – as Murris and Verbeek do in this issue. Add to that knowledge<br />of how children the world over have core knowledge systems, as argued by cognitive<br />developmental psychologists and neuroscientists, and we have a composite picture<br />of what the object of teacher education is – to know 1) the learner and 2) the subject<br />content, but also 3) the self as teacher.<br />This ‘didactical triangle’, was already proposed as view of teaching in the 17th century<br />in Comenius’s major work, Didactica Magna (Comenius, 1632/1967). In the 20th century,<br />for some reason, the English- speaking world used the term ‘didactic’ to denote<br />teacher-centred learning, while Comenius proposed what can arguably nowadays be<br />termed pedagogical content knowledge (PCK). Jari Lavonen, the chair of the teacher<br />education department at the University of Helsinki, recently noted that PCK is the<br />transformation of subject content knowledge by infusing it with knowledge of the<br />learner and of the self as teacher. In Finland they refer to PCK simply as Didactics, while<br />taking full cognisance of Shulman’s model (Shulman 1986).<br />But, views on teaching become more complicated when teachers are faced<br />with children who enter Grade 1, but who are not ready to embrace the way of life<br />at school. Bruwer and her co-authors report in this issue on teachers’ views on the<br />predicament they face when children need to cross the liminality boundary – when<br />they are still ‘betwixt and between’ life as an informal learner and life in school, where<br />they have to be inducted into life as a formal learner in a national curriculum. In the<br />same vein, Condy and Blease argue that a “one-size-fits-all curriculum cannot address<br />the issues that rural multigrade teachers and learners face”. Seldom do educational<br />researchers contemplate this very real issue. I was in the same class in Grade 1 as my<br />brother, who was then in Grade 8, in a little farm school. I recall vividly how we young<br />ones spent much time making clay oxen while they were doing indecipherable maths<br />on the writing board.<br />When more than one language is used, or required to be used, in a single classroom<br />communication set-up, a teacher is faced with yet another dimension. Ankiah-Gangadeen<br />and Samuel write about a narrative inquiry that was conducted in Mauritius, noting<br />that the “narrative inquiry methodology offered rich possibilities to foray into these<br />[teachers’] experiences, including the manifestations of negotiating their classroom<br />pedagogy in relation to their own personal historical biographies of language teaching<br />and learning”.<br />Added to the multilayered types of knowledge around which a teacher needs to<br />negotiate her way in a foundation phase classroom, are knowledge and understanding<br />of children’s transition from one grade to the next. Nieuwenhuizen and co-authors<br />found that the move from Grade 2 to Grade 3 is notably more difficult for children than<br />earlier grade transitions. I wish to add that it is also a grade transition that requires<br />much more of the learning child in volume and in pace of learning; the transition<br />Editorial<br />requires a ‘mature’ young learner who has worked through the curriculum of the<br />earlier grades effectively.<br />Kanjee and Moloi not only present information about ANA results, but show how<br />teachers utilise these in their teaching. To that, the editorial team adds: what is the<br />national testing ritual really doing for teachers? Are there many unforeseen and even<br />unintended effects? Many teachers may say that it alerts them to gaps in their own<br />knowledge and pedagogy and, especially, we would think, the way in which they<br />assess children’s learning effectively. While Kanjee and Moloi invoke local national<br />tests, Fritz and her co-authors from Germany, Switzerland and South Africa show<br />how a mathematics competence and diagnostic test for school beginners found<br />its way from Europe to South Africa. They point to the challenges of translating an<br />interview-based test and of validating it in a local context in four languages. With the<br />promise that the test will be normed in this country, the foundation phase education<br />as well as the educational psychology community may stand to benefit from such a<br />test, which is theoretically grounded in children’s conceptual development.<br />The matter of teaching with formative assessment as pedagogical tool comes to<br />mind whenever one discusses assessment. In an article by Long and Dunne, one reads<br />about their investigation into teaching of mathematics with a very specific angle – how<br />to “map and manage the omissions implicit in the current unfolding of the Curriculum<br />and Assessment Policy Statement (CAPS) for mathematics”. In a very dense and fast<br />paced curriculum it is not possible to fill all the gaps. Who knows what the effect may<br />be for future learning of children who move through a curriculum quite rapidly?<br />Staying in the early grade classroom, Sibanda explores the readability of two<br />textbooks for natural science learning for Grade 4 learners. She touches on one of<br />the sensitive nerves of South African school education, namely the English language.<br />In her analysis of two textbooks, using a range of methods of text analysis, she<br />comes to the conclusion that the books are simply too difficult to read. She argues<br />that the authors have not taken into account that both vocabulary and syntax have<br />to be taught systematically in order for Grade 4 children to be able to read texts in a<br />language they do not know well, for one, and in a discourse of science writing that is<br />new for them as well.<br />Ragpot narrates the story of how an instructional film, #Taximaths: how children<br />make their world mathematical, was conceptualised, scripted and produced with<br />senior undergraduate students at UJ. This artefact serves not only as higher education<br />material in teacher education, but is also used as material for teacher development.1<br />This issue of the journal is rounded off by an important contribution about the<br />ethics of research on children. Pillay explains how experts in ethics have advised him<br />in the work they do in the National Research Foundation South African Research<br />Chair he holds in ‘Education and Care in Childhood’ at the University of Johannesburg.<br />The reader is reminded that care of vulnerable children and the protection of their<br />rights should be high on the list of educational practice and its research.<br />iii<br />SAJCE– December 2014<br />The next issue of SAJCE is a special one. It is edited by Nadine Petersen and Sarah<br />Gravett and it celebrates a programme of research and development of the South<br />African Department of Higher Education and Training, with funding support from the<br />EU. The Strengthening Foundation Phase Teacher Education Programme started in<br />2011 and included most of the universities in the country. The issue promises to be a<br />milestone publication on teacher education for the primary school.<br />Editorial greetings<br />Elizabeth Henning</p>

The introduction of basic computer media for early childhood is very important because it is one of the skills that children need in this century. Need to support parents and teachers in developing the implementation of the use of computer technology at home or at school. This study aims to determine and understand the state of learning conducted based on technology. This research uses a qualitative approach with a case study model. This study involved 15 children and 5 parents. Data obtained through interviews (children and parents) and questionnaires for parents. The results showed that children who were introduced to and taught basic computers earlier became more skilled in learning activities. Suggestions for further research to be more in-depth both qualitatively and quantitatively explore the use of the latest technology to prepare future generations who have 21st century skills. Keywords: Parental Perspective; Computer Learning; Early childhood education References: Alkhawaldeh, M., Hyassat, M., Al-Zboon, E., & Ahmad, J. (2017). The Role of Computer Technology in Supporting Children’s Learning in Jordanian Early Years Education. Journal of Research in Childhood Education, 31(3), 419–429. https://doi.org/10.1080/02568543.2017.1319444 Ariputra. (2018). Need Assessment of Learning Inclusive Program for Students in Non-formal Early Childhood. Early Childhood Research Journal. https://doi.org/10.23917/ecrj.v1i1.6582 Atkinson, K., & Biegun, L. (2017). An Uncertain Tale: Alternative Conceptualizations of Pedagogical Leadership. Journal of Childhood Studies. Aubrey, C., & Dahl, S. (2014). The confidence and competence in information and communication technologies of practitioners, parents and young children in the Early Years Foundation Stage. Early Years, 34(1), 94–108. https://doi.org/10.1080/09575146.2013.792789 Barenthien, J., Oppermann, E., Steffensky, M., & Anders, Y. (2019). Early science education in preschools – the contribution of professional development and professional exchange in team meetings. European Early Childhood Education Research Journal. https://doi.org/DOI: 10.1080/1350293X.2019.1651937, https://doi.org/10.1080/1350293X.2019.1651937 Bredekamp, S., & Copple, C. (2009). Developmentally Appropriate Practice in Early Childhood Programs Serving Children from Birth through Age 8. Chen, R. S., & Tu, C. C. (2018). Parents’ attitudes toward the perceived usefulness of Internet-related instruction in preschools. Social Psychology of Education, 21(2), 477–495. https://doi.org/10.1007/s11218-017-9424-8 Christensen, R. (2002). Effects of technology integration education on the attitudes of teachers and students. Journal of Research on Technology in Education, 34(4), 411–433. https://doi.org/10.1080/15391523.2002.10782359 Couse, L. J., & Chen, D. W. (2010). A tablet computer for young children? Exploring its viability for early childhood education. Journal of Research on Technology in Education, 43(1), 75–98. https://doi.org/10.1080/15391523.2010.10782562 Creswell, J. W. (2012). Educational Research Planning, Conducting, and Evaluating Quantitative and Qualitative Research(4th ed.; P. A. Smith, Ed.). Boston: Pearson. Davis, J. M. (2014). environmental education and the future. (May). https://doi.org/10.1023/A Dhieni, N., Hartati, S., & Wulan, S. (2019). Evaluation of Content Curriculum in Kindergarten. Jurnal Pendidikan Usia Dini. https://doi.org/https://doi.org/10.21009/10.21009/JPUD.131.06 Dong, C., & Newman, L. (2016). Ready, steady … pause: integrating ICT into Shanghai preschools. International Journal of Early Years Education, 24(2), 224–237. https://doi.org/10.1080/09669760.2016.1144048 Dunn, J., Gray, C., Moffett, P., & Mitchell, D. (2018). ‘It’s more funner than doing work’: Children’s perspectives on using tablet computers in the early years of school. Early Child Development and Care, 188(6), 819–831. https://doi.org/10.1080/03004430.2016.1238824 Hadzigianni, M., & Margetts, K. (2014). Parents’ Beliefs and Evaluations of Young Children’s Computer Use. Australasian Journal of Early Childhood. https://doi.org/doi/pdf/10.1177/183693911403900415 Huda, M., Hehsan, A., Jasmi, K. A., Mustari, M. I., Shahrill, M., Basiron, B., & Gassama, S. K. (2017). Empowering children with adaptive technology skills: Careful engagement in the digital information age. International Electronic Journal of Elementary Education, 9(3), 693–708. Ihmeideh, F. (2010). The role of computer technology in teaching reading and writing: Preschool teachers’ beliefs and practices. 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Journal of Computer Assisted Learning. McCloskey, M., Johnson, S. L., Benz, C., Thompson, D. A., Chamberlin, B., Clark, L., & Bellows, L. L. (2018). Parent Perceptions of Mobile Device Use Among Preschool-Aged Children in Rural Head Start Centers. Journal of Nutrition Education and Behavior, 50(1), 83-89.e1. https://doi.org/10.1016/j.jneb.2017.03.006 McDaniel, B. T., & Radesky, J. S. (2018). Technoference: Parent Distraction With Technology and Associations With Child Behavior Problems. Child Development, 89(1), 100–109. https://doi.org/10.1111/cdev.12822 Nikolopoulou, K., & Gialamas, V. (2015). ICT and play in preschool: early childhood teachers’ beliefs and confidence. International Journal of Early Years Education, 23(4), 409–425. https://doi.org/10.1080/09669760.2015.1078727 Nolan, J., & McBride, M. (2014). Beyond gamification: reconceptualizing game-based learning in early childhood environments. 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One form of early mathematical recognition is to introduce the concept of geometric shapes. Geometry is an important scientific discipline for present and future life by developing various ways that fit 21st century skills. This study aims to overcome the problem of early mathematical recognition of early childhood on geometry, especially how to recognize geometric forms based on computer learning. A total of 24 children aged 4-5 years in kindergarten has to carrying out 2 research cycles with a total of 5 meetings. Treatment activities in each learning cycle include mentioning, grouping and imitating geometric shapes. There were only 7 children who were able to recognize the geometric shapes in the pre-research cycle (29.2%). An increase in the number of children who are able to do activities well in each research cycle includes: 1) The activities mentioned in the first cycle and 75% in the second cycle; 2) Classifying activities in the first cycle were 37.5% and 75% in the second cycle; 3) Imitation activities in the first cycle 54.2% and 79.2% in the second cycle. The results of data acquisition show that computer learning application can improve the ability to recognize geometric shapes, this is because computer learning provides software that has activities to recognize geometric shapes with the animation and visuals displayed. Keywords: Early Childhood Computer Learning, Geometry Forms, Early Math Skills Reference Alia, T., & Irwansyah. (2018). Pendampingan Orang Tua pada Anak Usia Dini dalam Penggunaan Teknologi Digital. A Journal of Language, Literature, Culture and Education, 14(1), 65– 78. https://doi.org/10.19166/pji.v14i1.639 Ameliola, S., & Nugraha, H. D. (2013). 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Curriculum material is generally considered the subject matter of information, talents, dispositions, understandings, and principles that make up research programs in the field. At a more complex level, the curricula need to contain historical and socio-political strengths, traditions, cultural views, and goals with wide differences in sovereignty, adaptation, and local understanding that encompass a diversity of cultures, laws, metaphysics, and political discourse This study aims to develop a curriculum with local content as a new approach in early childhood science learning. The Local Content Curriculum (LCC) is compiled and developed to preserve the uniqueness of local culture, natural environment, and community crafts for early childhood teachers so that they can introduce local content to early childhood. Research and model development combines the design of the Dick-Carey and Dabbagh models with qualitative and quantitative descriptive analysis. 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IntroductionAccording to modern scholars (N. Maslova, B. Astafiev), one of the important reasons for the global planetary crisis, including modern educational system in particular, is violation of the conformity of nature principles in the process of perception and cognition of the world, which is conditioned by the advantages of the development of logical and rational thinking and insufficient development of figurative, spiritual-intuitive thinking in the contemporary school of all levels.The modern system of education at all levels (school, higher education, postgraduate studies, and doctorate) is aimed primarily at the development of mechanisms of the left hemisphere that are rational, logical thinking, and analytical perception of reality.Such a one-way orientation leads to inhibition of right-sided processes, does not contribute to the development of creativity, disclosure and activation of the spiritual and intuitive capabilities of the individual, as well as to alienation of individual from the World, loss of personal sense of integrity, unity with the World; that is, to the disharmony of individual with his/her own nature and environment.Personal development of an individual in modern conditions takes the form of "Homo technicus" ("technical person"), "Homo informaticus" (“informational and technogenic person”), "Нomо соnsumens" (“person who consumes”), "Reified man" ("material surplus person"), "Nomo Festivus" ("person who has fun") (Butenko, 2017). As a result, a person with a technocratic, rational thinking, pragmatic and consumer attitude towards the world is brought up, and as a consequence, harmony in the "man-man", "man-nature", "man-society", "man-universe" systems, and correspondingly, the equilibrium in the integrated information-energy system interaction "Man – Society – Earth –Universe" are violated.Approach In contemporary education of all levels, high ontological and existential goals are not set, and not enough attention is paid to the spiritual and mental health of the individual, in particular to problems of spiritual self-knowledge, self-development, self-regulation and self-realization, thus leading to the formation of consumer psychology, dominance of pragmatic values, loss of spirituality, upbringing of a human – destroyer, a soulless person, but not a creator.One of the ways out from the planetary global crisis in the area of a contemporary education in particular, is the noosphereization of education, the imperative task of which is formation of the noospheric individual, actualization of his/her spiritual and intuitive potential, training of the noosphere integral harmonious bioadequate environmentally healthy mindset, which is based on a conscious total ownership of logical (left cerebral hemisphere) and creative, spiritual-intuitive (right cerebral hemisphere) thinking that, due to correspondence with both huamn nature and the laws of the cosmoplanetary world, will provide the individual with possibilities to adequately and fully (at the information and energy levels) perceive and recognize the surrounding world, and to interact with it on a spiritual basis.Results and Discussion The problem of intuition always remains relevant throughout the history of mankind. Among the scholars of the late XX century - beginning of the XXI century the problem of intuition and harmonization of the activity of the left and right hemispheres of the brain has been studied by such researchers as G. Kurmyshev, N. Maslova, Osho Bhagwan Sri Rajneesh, I. Smokvina and others. Modern psychophysiological science explains the nature of intuitive thinking and cognition: the human mind combines the ability to integrate and develop both intellectual and intuitive knowledge that modern scientists associate with the activity of the left and right cerebral hemispheres. According to psychological science, the two hemispheres of the brain cognize and reflect the surrounding world differently and, thereafter transform information in their own ways. The left hemisphere "sees" objects as discrete, separated; it is responsible for logic and intellect, verbal thinking, application of sign information (reading, counting, language), and is characterized by the ability for logical, rational, mathematical, and scientific thinking. The right hemisphere binds objects into a single whole; it is responsible for emotions, creative thinking, intuition (unconscious processes). Thanks to the right hemisphere, a holistic image of the world is formed, and the left hemisphere gradually collects the model of the world from separate, but carefully studied details. "Left- hemisphered" thinking is associated with the ability for consistent, step-by-step cognition, which has respectively analytical rather than synthetic character. "Right- hemisphered" thinking is linked to the ability for integral, voluminous and complete cognition, space spatial immediate perception of the world in all of its information-energy interrelations and interactions.Logic and intuition, rational and intuitive paths – are different aspects of the unified process of cognition, and if the intellect can be regarded as the earthly beginning in humans, then intuition – is a spiritual primary source, a phenomenon of nonlinear, unearthly thinking, the logic of the Higher Being, the logic of the Almighty. As was very wittily pointed out by Osho Bhagwan Shree Rajneesh, logic – the way our mind cognizes our reality, intuition – is how the spirit passes through the experience of reality (Maslova, 2006). Therefore, logic and intuition are two mutually conditioned mechanisms of scientific cognition that supplement and do not exist in isolation from one another. If the function of intuition in this interaction lies in creative discoveries, inventions, awareness of the true essence of things and phenomena, then the task of the scientific method, acting as an assistant of intuition, is to endeavor to comprehend new ideas, explain them from the point of view of earth science at the logical level, and "adapt" to our reality.Given this, rational and intuitive paths must complement, enrich and explain each other, interact in sync, in synthesis.Intuition is an organic component of the spiritual and psychic nature of the individual. Therefore, the problem of the development of intuition and harmonization of the discourse-logical and spiritual-intuitive components of thinking is extremely important at all levels of contemporary education. This is especially true for student youth, since students are the future spiritual and creative potential of the country, and therefore it is extremely important to reveal and develop their spiritual and intuitive abilities, to harmonize their mental-spiritual sphere, which promotes spiritual self-healing of both the individual and the environment, and harmonization of relations in the world. In the context of the modern information and energy paradigm, intuition is considered as a special mental state of a highly spiritual person, in which he/she deliberately initiates informational and energetic contact with any object of the Universe, in the physical or subtle world, "connects" to its information field, "reads out", "decrypts" and analyzes necessary information. This information-energy interaction is perceived by the individual as the process of connection, merging with the object being studied, which enables instant cognition of its true essence (Smokvina, 2013). As the analysis of the literature on the research problem testifies, if the activity mechanisms of the left hemisphere of the brain are relatively studied in modern science, the problems of the individual’s intuitive updating potential and harmonization of the activity of logical and intuitive cognitive processes are being investigated.According to many scholars, the ability for intuition is inborn in every human; however, unfortunately, in most people it is in a latent state. And only due to intense conscious work of the individual regarding their own spiritual self–cognition and self–perfection, one can discover and develop personal spiritual and intuitive abilities.According to the results of our theoretical study the general conditions contributing to the disclosure and development of intuition are as follows: (Tyurina, 2017) • Ability to cope with one’s own passions, emotions, feelings, thoughts, and achievement of the state of internal silence, voicelessness;• Formed self-motivation for spiritual self–cognition and self–perfection;• Achievement by the individual of the corresponding spiritual level: the higher the spirituality of the human, the more clearly his/her ability is expressed to obtain a higher spiritual knowledge: information and energy interaction, contact with higher levels of psychic reality;• Conscious desire, willingness of the individual to use intuitive cognition that helps overcome information-power resistance, the barrier that exists between a subject and an object, helps create harmony, assonance, interaction with the object being studied;• Intuitive human confidence: deep inner belief in personal intuitive capabilities and ability for intuitive cognition and self-cognition;• Humanistic orientation of the individual and his/her internal psychological properties such as: altruism, active love for all living beings on the Earth, empathy, ability to express compassion, care, and self-consecration, conscious desire to live in harmony with oneself and the world;• Nonjudgmental practice, which consists of the ability of a person to abandon assessments, classifications, analysis, which creates favorable conditions for immersion into the information space around us, makes it possible to connect to the information-energy field (biofield) of the object being studied;• Sense of inner unity with the world, awareness of oneself as a part of mankind, of the Earth, of the Universe, and a feeling of deep responsibility for the world and for ourselves in the world;• Striving for personal self-realization for the benefit of the cosmoplanetary world.In our opinion, the ways of actualization of intuition and harmonization of the activity of logical and intuitive components of the process of cognition should be attributed to the following (Tyurina, 2018):• Concentration, concentration of human consciousness of the subject being studied, deep and thorough knowledge of it.Psychological mood, deep concentration, focus of human consciousness on the subject of research lead to intuitive penetration into its essence, comprehension of the subject of study as if "from within." An intuitive act of cognition is the result of a huge concentration of all human efforts on a particular problem, deep and thorough knowledge of it, mobilization of all its potencies. In particular, for almost 20 years, D. Mandeleev worked continuously on the systematization of chemical elements, and only after that he "saw" his periodic system of elements in his dream. At academician M. Shchetynin school students spend 21 days (6 lessons daily) studying only one academic discipline for the purpose of deep penetration into its essence - information-energy merger, connection with the subject being studied, into a single whole, that is, achieving an intuitive level of comprehension.• Spiritual practices (prayer, meditation).Prayer and meditation are effective ways of spiritualizing a person, awakening and activating his/her intuitive potential. Through prayer, meditation a person learns to adjust to nature and Cosmos, eternity and infinity, the World Harmony, reaches consonance with the World, and permeates its inner essential depth with the heart.It is believed that it is prayer that promotes the spiritual purification of both the human soul and the surrounding world. During a heart-warming prayer a human comes to enlightenment and spiritual enlightenment, intuitive enlightenment.In the process of prayer, meditation, the right and left hemispheres of the brain begin to work synchronously, which makes the brain function in resonance with the Field of Consciousness or the Field of Information - Noosphere.• Spiritual processing of the corresponding religious, spiritual and philosophical sources, fine arts, classical music, information-energy interaction which raises the spiritual level of an individual, awakens his/her intuitive abilities.Spiritual literature is an important way of discovering and developing intuition and harmonizing the activity of intuitive and logical components of thinking, since information and energy interaction with spiritual literature contributes to individual’s spiritual growth, disclosure and development of intuition, and harmonization of personal intuitional and intellectual sphere.It should be noted that various forms of art, in particular, visual and musical, play a special role in the process of disclosure and development, intuition, harmonization of the logical and figurative, spiritual and intuitive perception of reality.The spiritual potential of art is, first of all, that in itself, creating spiritual values, spiritualizes a person, and interprets personality as a phenomenon of a global planetary-cosmic nature. True art has an ecumenical, cosmic dimension. The best masterpieces of world art transfer the idea of unity of humans with the world, their harmonious interaction.The creativity of great artists contributes to the disclosure and development of the personality's spirituality, the heart's perception of the world, the cultivation of the Cosmic Worldview, and directs the person to high ideals.Musical art is one of the most important means of revealing and developing intuition, harmonizing its spiritual and intuitive basis.The results of research by modern scholars show that classical, spiritual music activates the spiritual-intuitive sphere, harmonizes the person, gives a sense of joy and rest, and helps to restore spiritual and mental balance.It has been scientifically proven that classical musical compositions based on the perfection of harmony and rhythm, especially the works of J. Bach, L. Beethoven, J. Brahms, A. Vivaldi, G. Handel, F. List, F. Mendelssohn, A. Mozart, S. Rakhmaninov, O. Scriabin, P. Tchaikovsky, F. Chopin, F. Schubert, R. Schumann and others have a positive effect on the individual on the spiritual, mental and physiological levels, since classical music relates mainly to the natural rhythms of the human body. This music causes not only positive emotions, but also represents a powerful energy force that inspires humans and the world: makes a person more perfect and the world more beautiful.Consequently, fine arts, classical music, contribute to the disclosure and development of the spiritual and intuitive potential of the individual, to harmonization of his/her intuitive-intellectual sphere; they help the person to grow spiritually and be filled with high spiritual energy, accordingly, to change, and improve the natural and social environment.- Bioadequate REAL-methodology of noosphere education (N. Maslova), in which stages of relaxation (accumulation of information, work of the right creative hemisphere in a state of rest), alternating with stages of activity (training of the left hemisphere: logic, analysis, synthesis of information) are presented. As a result, the work of the left and right cerebral hemispheres is synchronized, which promotes harmonization of consciousness, carries a beneficial influence on the spiritual, mental, social and physical health of the student's personality.The fundamental characteristics of the bioadequate method of noospheric education are:1. Health preserving - does not violate the nature of perception, processing and preservation of information.2. Corrective - restores the natural genetic sequence of work with the information and health of the student and the teacher.3. Developing - improves the body's reserves.4. Harmonizing - integrates all systems of the body and personality (Vernadsky, 2002).According to studies of the neuropathologist I. Smokvinova, PhD, bioadequate methods of noosphere education, taking into account the physiological and informational and energy resources of the individual, contribute to the harmonization of the work of the left and right cerebral hemispheres, awaken higher feelings, recharge with life energy, teach the ability to direct vitality to the realization of one’s own higher potential, which also has a beneficial effect on the spiritual, mental and physical health of the individual. Moreover, due to the application of a bioadequate technique, psychological and physiological stress is eliminated, and a positive emotional mood is created that heals the body and the student's psychics (Osho, 2000). According to N. Maslova, holistic thinking contributes to the acquisition of basic energy, biologically adequate to livelihoods programs (Kurmyshev, 2013).Many independent groups of scientists (teachers, psychologists, physicians, biologists) have proved that noosphere education, harmonizing the left and right hemispheres thinking, has a healing effect on the body of both the student and the teacher, contributes to the development of natural creativity.Practical valueResults of our study can be used in lectures and practical classes with students in medical psychology, psychology of creativity, social, general, pedagogical psychology, pedagogy (sections of didactics, spiritual and moral education), sociology, philosophy, etc.ConclusionsThus, the actualization of the spiritual and intuitive potential of the individual and the harmonization of the activity of the left and right cerebral hemispheres stimulates the disclosure of spiritual and creative abilities of the individual, fills the individual with spiritual energy, and the person becomes a source of spiritualization of himself/herself and the world, thus contributing to the spiritual and psychological improvement of society, humanity, and civilization in general, since at the information-energy level, "Man - Society - Earth - Universe" this is the only cosmoplanetary organism, all parts of which are mutually interconnected, interact and stipulate with one another. We consider that it is important in the future to develop appropriate special disciplines for all the sections of modern school and keep working in the direction of developing and incorporating into the content of the curricula, relevant pedagogical technologies aimed at the disclosure and development of the intuitive-mental sphere of the individual

This study focuses on the importance of strengthening intercultural awareness among future Primary School teachers. Intercultural communicative competence plays a fundamental role in developing an honest and productive dialogue among people, whatever their origin, language or cultural heritage, and prospective teachers will be responsible for training the ‘good interculturalists’ of tomorrow. A survey was conducted among students attending a degree course for Primary Education Teachers to highlight what knowledge, practices and skills they have acquired regarding intercultural competence and whether they are able to deal with and successfully apply the notions of plurilingual and intercultural competence to their teaching practices.

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