Basic Position Concerning the Revision of the Junior High School Course of Study
in
Science Education

SHINOHARA, Fumihiko
Associate Professor
Tokyo Gakugei University
Koganei-shi, Tokyo 184 Japan
(November 1990)

(1990 SEAMEO RECSAM)

Contents
1. Introduction
2. Junior High School Science Education: Present Status and Issues
3. Principles Underlying the Revision of Junior High School Science Education
4. Objectives and Contents of New Junior High School Course of Study
5. Conclusion
References　

Auhor's Note

1. Introduction

The Ministry of Education issued a revised Course of Study on March 15, 1989. For junior high schools, measures have been provided to facilitate the transition to the new curriculum, which will be implemented starting from the 1993 school year. In the meantime, new textbooks are to be edited during 1990, textbook certification will be done in 1991 and the textbooks to be used will be selected in 1992. These steps will pave the way for the full-scale adoption of the new curriculum in April 1993 based on the revised Course of Study.

Serving as the standard framework for the educational curriculum, the Course of Study has been revised approximately every ten years. Since the latest revision is to be enforced in 1993, it will form the basis of the education that is offered at the beginning of the 21st century.

This recent revision of the Course of Study is based on a report submitted to the Ministry of Education by the Education Curriculum Council in December 1987. The fundamental idea underlying the Course of Study is to develop the foundations for lifelong learning, taking into account the transformation of students' lifestyles and awareness that will likely occur in conjunction with changes in society in the coming years. The basic aim of the Course of Study is to foster the development of sensitive, well-rounded individuals who will be capable of coping with changes in society by themselves in the coming 21st century.

The main features of the latest revision can be summed up in the following four points;

(1) Improvement of education for the mind

All educational activities will seek to develop well- rounded, resolute and courageous individuals and will be designed to match the various stages of development of students and the particular characteristics of each academic subject.

(2) Emphasis on the basics and fundamentals and encouragement of personalized education

The fundamental skills and knowledge required by the nation will be emphasized and education that maximizes individual potential will be strengthened and improved. At the same time, the consistency of the educational content at each school level will be improved.

(3) Development of self-education capability

Emphasis is to be placed on developing the ability to cope independently with changes in society and on fostering the basis of originality. In addition, a strong desire to educate oneself is to be fostered.

(4) Fostering of respect for culture and tradition and of international understanding

Emphasis is to be placed on fostering an attitude of respect for Japanese culture and traditions. A deeper understanding of the cultures and histories of other nations will also be cultivated in order to develop a disposition for living in an international society.

The following discussion will focus on the revised Course of Study for junior high school science education, while keeping in mind the overall aims of this latest revision of the basic framework for the educational curriculum.

2. Junior High School Science Education: Present Status and Issues

The Ministry of Education provides junior high school teachers with guidance through various seminars and training courses, including the Junior High School Curriculum Seminar, Education Research and Presentation Conference, Science Research Council of the Education Center, and Liaison Council for Science Teachers. In addition, it also gathers information on the actual status of science education carried out in the classroom. That information is obtained from reports written from various perspectives and from research group discussions, among other sources.

Several years ago the Ministry of Education surveyed the way in which the current curriculum was being implemented and obtained a great deal of objective data on many different aspects of the present system. The International Education Association has also conducted surveys on science education around the world. The results of its second survey presented an international comparison of education in different countries. The survey results indicated the areas where science education in Japan was outstanding as well as its deficiencies.

One observation that has been made on the basis of these different analyses of science education in junior high schools in Japan today is that science instruction is not being carried out from the standpoint of learning directly from natural things and phenomena. Instead, there is tendency for instruction to be conducted as a one-way transmission of knowledge from the teacher to the students. As a result, students invariably tend to rely excessively on a passive form of learning and they are not necessarily acquiring the ability to investigate nature through self-initiated inquiries into natural phenomena nor are they developing a positive attitude toward the study of nature.

Formal school education is strongly expected to cultivate abilities for coping adequately with changes in society, including the ongoing progress of science and technology and the advance of information technology. This is just one reason why steps should be taken to improve and upgrade the substance of education along with the teaching and learning methods that are used. In the area of science instruction, the aim should be to foster the development of scientific thought, judgment and power of expression. This can be accomplished by cultivating a desire for self-education and by motivating students to undertake self- initiated activities to study and investigate natural things and phenomena.

In connection with the latest revision of the contents of science education in junior high schools, it has been pointed out that more attention should be paid to the relationship between nature and students' everyday life and things in their immediate surroundings; further, there is a need to foster a stronger interest in, intellectual excitement over and curiosity about natural things and phenomena. One aspect of this observation is that this viewpoint should be specifically incorporated in the improvements made to the contents of the Course of Study. Another important aspect is that teaching students about the relationship between nature and their everyday lives should promote a better understanding of natural phenomena. This will help to improve their understanding of abstract and hard-to- understand scientific facts when they are presented in the classroom.

3. Principles Underlying the Revision of Junior High School Science Education

With the foregoing discussion as introductory background, this section will talk about the principles underlying the revision of the Course of Study for junior high school science education.

(1)Natural things and phenomena were treated in terms of the traditional disciplines of chemistry, physics, biology and physical geography. The contents of science education have been organized by taking into account such factors as the stages of development of students, their aptitude for learning, and the consistency of instruction at each educational level.

(2)Greater attention was paid to the selection, consolidation and organization of the contents of the Course of Study. This was done to foster the development of scientific perspectives and powers of thought by providing sufficient latitude for investigating nature through direct personal experience in the form of observation and experimentation.

In this connection, the contents were thoroughly screened, condensed and organized, taking into account the findings revealed by the Ministry of Education's earlier survey which had examined the actual implementation of the present curriculum in the classroom. The contents were selected and organized with an eye toward enabling students to acquire the abilities and desire to investigate nature scientifically and to form basic scientific concepts through observation, experimentation and inquiry into natural phenomena.

Compared with the present Course of Study, subsection 3 of the revision concerning "Treatment of Contents" contains a more detailed description of restrictions and limitations on the scope of subject material to be presented. This step was taken to prevent the contents of textbooks from becoming overly complicated or a mere arrangement of wide-ranging factual information. In the case of a substantive subject like science, textbooks are apt to contain detailed factual descriptions rather than explanations of the methods used in studying nature through observation and experimentation. Thus, there is a tendency for instruction to become a one-way transmission of this factual knowledge by the teacher and passive memorization by the students. The "Treatment of Contents" has been described in detail to avoid this type of instruction.

(3)Instruction should not be conducted through an overreliance on the transmission of factual information; rather, it should foster the development of the students' abilities and desire to pursue solutions to problems enthusiastically. To make this possible, the Course of Study has been organized such that the relationship between the subject matter and activities for studying nature through observation and experimentation is clearly described in subsection 2 entitled "Contents."

In this connection, it was thought that greater emphasis should be placed on observation and experimentation. The aim was to foster the development of the students' capability for scientific thought, judgment and power of expression through self-initiated inquiries using the methods of observation and experimentation. Various innovative approaches to describing the subsection dealing with "Contents" were considered in order to accomplish this aim.

The present Course of Study mentions that the "objectives" of science education are to be attained "through observation and experimentation." The report submitted to the Ministry of Education in conjunction with the present Course of Study also noted the importance of learning through direct contact with natural things and phenomena. However, the survey on the actual implementation of the curriculum revealed that the situation at schools was not necessarily satisfactory with respect to active participation by the students in learning about nature through observation and experimentation.

In view of this situation, an effort was made to describe the "Minor Topics" in the "Contents" subsection of the new Course of Study in such a way as to encourage more vigorous inquiries and investigations by the students. This was done, for example, by indicating that "the rules governing .... should be found by conducting observations and experiments concerning ...." Activities for studying nature through observation and experimentation have been described in the "Contents" subsection in such a way that they are linked to the subject matter of science education. In organizing the contents in this manner it was felt that it would not be suitable to describe the specific procedures for conducting observations and experiments or the materials and tools to be used, as the Course of Study is intended to serve only as the basic framework of the curriculum. Therefore, the description in the "Contents" subsection only states that observations, experiments and other investigative studies should be conducted and that the students' abilities and desire to study nature should be fostered through such inquiries and investigations. The description emphasizes the necessity of active participation by the students in acquiring knowledge and in forming intellectual concepts.

(4)The contents have been organized with greater emphasis placed on the connections between familiar natural things and phenomena and everyday life, as well as on the results and benefits of science. This was done to make the subject matter of science education more appealing and interesting to the students.

These considerations also received substantial emphasis in the present Course of Study. In order to bring the subject matter of junior high school science education closer to the students, care was taken to relate the contents of the new Course of Study to things familiar to the students in their immediate surroundings. The first area of study focuses on such phenomena as light, sound and heat. Subject matter dealing with information technology, new materials and energy has been included under a section on the progress of science and technology and human life.

The contents in the second area of study have been organized so as to emphasize the connections between natural phenomena and people's everyday lives. The subject matter covered here includes familiar plants, meteorological observation and measurement, heredity and evolution.

One aspect of this emphasis given to the connections with everyday life is that items pertaining to these relationships should be incorporated in the contents of the Course of Study. Another aspect is that teachers should try to relate the subject matter of science education to things in everyday life in the process of teaching science to their students in the classroom.

(5)Computers should be used as needed in teaching students about science. An attempt was made to clearly identify the role of computers in science education in the future and to provide for ways in which computers can be utilized suitably and positively in science instruction.

In using computers in science education, thorough consideration should be given to the aims set for science instruction and the relationship computers have with the attainment of those aims. The use of computers should be based on a clear understanding of these points.

Let us assume that the objectives of science education are to emphasize the importance of observation and experimentation, to encourage self-initiated inquiry and investigation by the students, and to foster independent and creative learning activities. It is necessary to examine the roles that computers can play in attaining each of these objectives and the ways in which computers can support the study of science.

The use of computers is described in the following way in the new Course of Study for junior high school science education. "Consideration should be given to the effective use of computers as needed in teaching each area of study, such as in searching for and retrieving information during the course of observation and experimentation, in processing experimental data or in performing experimental measurements." (Section 3. Preparation of Teaching Plans and Treatment of Contents.)

The salient points of this description include mention of the use of computers and also the clear distinction made regarding the ways in which they are to be used. This can also be understood from the fact that the description does not specifically state that "the use of computers and other related equipment is to be promoted in the course of teaching science."

The course of observation and experimentation that is mentioned here means the process of study per se. It refers to the study procedure which involves the identification of a problem, the gathering and processing of information, and the forming of general conclusions based on the results.

Various examples can be cited in connection with information searches and retrieval. These include a search for issues that are to be resolved in conducting research on a particular theme, retrieval of educational materials and tools to be used in conducting an observation or experiment, referencing of information on the properties of chemicals or chemical substances, retrieval of information regarding permanent stars or planets of the universe, and retrieval of classifications of animals, plants, minerals and rocks. In these examples, it is intended that computers will be used as an actual tool for supporting the study activities initiated by the students on their own accord.

The capabilities of computers lend themselves well to such tasks as the processing of experimental data or the creation of graphs. By inputting and processing data measured in an experiment and then outputting the results in the form of a graph, students should be better able to discover the relevant laws of nature and this, in turn, should lead to further study of new things.

In carrying out experimental measurements, it is important that the students make their own sensors for detecting light, temperature, sound, pressure and other phenomena. By linking these sensors to a computer and following the changes in the measured data in real time during the course of an experiment, students will be able to grasp changes in phenomena quantitatively. It is anticipated that this will encourage further study which will lead to the discovery of still other natural laws.

It should be noted that the description given in the Course of Study concerning the use of computers in teaching science does not suggest such things as drills, tutorials or simulations. Many of the simulation software programs seen nowadays are in fact being used as substitutes for observation and experimentation. It would be a grave situation if there were teachers who are using this simulation software because they attach little importance to observation and experimentation as forms of direct experience.

The following are examples of computer software for use in science education which are in accord with the principles underlying the latest revision of the Course of Study. It is hoped that these tools will be developed and used in the future.

Development of Educational Software in Line with the Newly Revised Course of Study

1) Information retrieval

Retrieval of plant classifications (as a method of learning different types of plants)

Retrieval of animal classifications (types of birds, fishes, etc.)

Retrieval of rock and mineral classifications

Retrieval of matter classifications (properties, solubility, solids, liquids, gases, etc.)

2) Processing, tabulation and graphic representation of experimental data

Totaling and processing of experimental data

Processing and graphic representation of experimental data (software for creating scientific graphs)

3) Experimental measurements and tools in science education

Sensors, A/D adapters, and other tools made by students themselves

Experimental measurement of the melting point of naphthalene and paradichlorobenzene

Experiments on adiabatic expansion

Measurement of heat release in neutralized titration

Measurement of electrical conductivity in neutralized titration

Measurement of heat generated by passage of an electrical current

Experiments concerning Ohm's law

Dynamic experiments involving light and sensors

4) Continuous recording of fixed point observations

Continuous measurement of changes in temperature, atmospheric pressure and humidity over a set period of time

Continuous measurement of changes in wind direction and velocity over a set period of time

Continuous measurement of rainfall over a set period of time

5) Computer communications

Exchanges of information on teaching materials, methods of instruction and natural environment survey results

Exchanges of information on locations for collecting live specimens for educational use, places where specimens are raised or kept and best ways of obtaining experimental specimens for educational use

(6)In cases where the number of hours of instruction set for third year students exceeds the minimum, specific instruction has been given concerning ways of supplementing or deepening the Course of Study contents according to the school's or students' actual situation.

From the standpoint of compulsory education requirements, the three years of science education in junior high school must reliably impart to all students a basic understanding and knowledge of the rudiments of science. To make certain that each student accomplishes that goal, it is necessary to try a wide variety of teaching and learning methods. It is important to employ teaching methods tailored to the needs of individual students in order to ensure that all students reach the levels established as the goals of education.

The revised Course of Study allows for flexibility in determining the number of hours of science instruction for third year students. A minimum of three hours per week is specified, but the Course of Study allows science education for third year students to be conducted within a suitable range of three to four hours.

Accordingly, if three hours a week are devoted to science education for the first, second and third year students, the number of hours actually spent on science will conform to the number specified in the "Contents" subsection of the Course of Study. On the other hand, if the number of hours of instruction for third year students is set at the upper limit of four hours per week, it means there will be one more hour than the specified number. That additional hour would make it possible to conduct the instruction at a more relaxed pace. It could also make it possible to teach science in all three years in a more relaxed manner.

The extra hour of science education per week could be devoted to supplementary instruction for those students who have not attained the specified objectives. For those student who have attained the objectives, it could be used to deepen their understanding of the subject matter by giving them more advanced materials to study. In either case, this would be done within the scope of the subject matter specified in the "Contents" subsection of the Course of Study.

(7)In the elective science course for third year students, provision has been made for the use of various learning activities according to the particular characteristics of the students. The "Contents" subsection of the Course of Study has been organized so that schools can made innovative use of research on individual themes, outdoor observation and other activities.

The revised Course of Study provides for an elective science course in order to emphasize learning activities that maximize the individuality and creativity of the students. This takes into account the fact that students in junior high school are going through a period when their abilities, aptitudes and interests diversify considerably.

It is taken for granted that science will be taught in such a way that all students will gain a fundamental understanding and knowledge of the basics of this discipline. At the same time, it is also essential to take into consideration students who have a strong interest in or a special aptitude for science. Providing opportunities to encourage them and to fulfill their aspirations is an important part of offering education that will enable them to make the most of their individual talents and creativity.

The time allowed for this elective science course is intended to enable the students to display their own character and abilities to the fullest extent while pursuing a series of study activities. As typified by a research project on a particular theme, these activities include the selection of a research topic, planning and selection of a suitable approach, gathering of information, continuous observation and performance of experiments, processing and analysis of the results and organization and presentation of the findings.

Outdoor observation provides an opportunity for learning through direct contact with nature, which is effective in enabling students to experience the rigors, beauty, subtleties and grandeur of nature. In addition, it also fosters the abilities and desire to study natural phenomena continuously and from various perspectives.

4. Objectives and Contents of New Junior High School Course of Study

The new Course of Study sets the following curriculum objectives for junior high school science education, which have been determined in consideration of the Education Curriculum Council's report, consistency among the educational objectives for elementary, junior high and high schools, and the relationship with the aims of each science subject taught in junior high school.

(1) To foster a stronger interest in and enthusiasm about nature

(2) To develop the ability and desire to pursue scientific studies through observation and experimentation

(3) To promote a better understanding of natural things and phenomena

(4) To develop scientific perspectives and ways of thinking

The aims of science education are, of course, as follows:

<1> To acquire the methods for studying nature through a process that emphasizes scientific inquiry

<2> To obtain scientific knowledge and form basic intellectual concepts

<3> To develop a scientific attitude and a view of nature

Objectives (1) and (4) above correspond to aim <3>, objective (2) corresponds to aim <1> and objective (3) corresponds to aim <2>.

The new Course of Study includes the fostering of a stronger interest in nature as one of the objectives. There are several reasons why this aspect concerning human emotion or volition is mentioned. One reason is related to the way in which science education is all too often conducted. As noted earlier, there is a general tendency for teachers to conduct science classes as a one-way transmission of knowledge, with the result that students develop a passive attitude, shun nature and have no interest in science. Consequently, there is a need to foster through ordinary learning activities a stronger interest in, intellectual excitement over and curiosity about nature and an attitude of wanting to study nature. As a result, students will be motivated to study on their own and will develop a desire to educate themselves.

This is a point that must be emphasized in school education and in connection with the teaching methods employed, in view of the trend toward a society where life-long education is pursued.

The new Course of Study for junior high school science education consists of three sections: 1. Curriculum Objectives, 2. Objectives and Contents of Each Subject, and 3. Preparation of Teaching Plans and Treatment of Contents. The second section comprises three subsections: (1) Subject Objectives, (2) Contents and (3) Treatment of Contents. As in previous years, four objectives have been established for each subject. This time the relationship between the curriculum objectives and the contents has been described more clearly, taking into account the compatibility with the curriculum objectives, the connection with the basis for evaluation and other factors. The first objective concerns scientific thought and methods of study, the second and third objectives pertain to skills and cognition and the fourth objective has to do with attitudinal aspects.

The second subsection, "Contents," is organized in the same manner as in the past and consists of four parts: "Major Topics," "Aims of Major Topics," "Intermediate Topics," and "Minor Topics."

The part dealing with the "Aims of Major Topics" describes aspects related to the formation of concepts, understanding, perspectives and ways of thinking in connection with the contents treated under the corresponding major topics. For instance, the "Aims of Major Topics" are described using such language as "to promote deeper knowledge of ....," "to foster understanding of ....," and "to cultivate perspectives of and ways of thinking about ...." More specifically, the aims are described as follows: "to foster understanding of .... through observation and experimentation concerning familiar ...., to acquire ...., to promote deeper knowledge of ...., to cultivate perspectives of and ways of thinking about ...., and to encourage a comprehensive consideration of ...."

The specific items intended to facilitate attainment of the aims of major topics are given under the "Minor Topics." In the newly revised Course of Study, the "Minor Topics" subsection is described in terms of study approaches and behavior, such as "to discover natural laws by carrying out observations and experiments concerning ....," or "to grasp the correlation between ...." However, this is apt to be misinterpreted as indicating that all teachers need to do in teaching science is to simply conduct observations and experiments. The "Minor Topics" subsection emphasizes that inquiries and investigations must also ultimately lead to an understanding of the basic concepts, principles and laws underlying the "Aims of Major Topics." The substance and methods leading to cognitive attainment of the "Aims of Major Topics" can be summed up in the conduct of observations and experiments as mentioned in the "Minor Topics" subsection.

5. Conclusion

The foregoing discussion has explained the portion of the newly revised Course of Study that pertains to junior high school science education.

The author is aware of the fact that there are some people who feel uneasy about science education in Japan because the revised Course of Study provides for a subject dealing with life science in the lower grades of elementary school in place of the present science course and reduces the number of hours devoted to science in junior high school. It is intended that the life science course will include a wide range of activities which will impart to pupils the experience and understanding needed in learning the principles of science. Therefore, it is expected to make positive, and not negative, contributions to the furtherance of science education.

The ample experience which had been acquired up to three or fourth grade provided the essential foundations for studying science.

The present Course of Study specifies four hours per week of science instruction. Under the new curriculum, greater flexibility has been provided so that schools may devote three, four, or five hours a week to science. Schools may choose to offer four hours of science instruction per week, which is the upper limit for compulsory science education. In addition, they may also offer an additional hour of an elective science subject, making a total of five hours, which is more than under the present Course of Study.

The question of whether or not sufficient study of science is provided ultimately boils down to whether or not schools present science to the students in an appealing and interesting manner.

There are three excuses that are always given for not conducting (or not wanting to conduct) observations and experiments. One is that such experiments have already been performed. A second is that the teacher is too busy. The third excuse is inadequate equipment or facilities due to budget limitations. If teachers use these excuses to justify the teaching of science by simply trying to inject factual knowledge into students' heads, the number of students who complete science courses is likely to decline. In addition, the number of students who choose to study science in high school is also likely to continue to decrease.

If there are concerns about the future of science and technology in Japan, greater reflection should be given to teaching and learning methodologies, the way in which education is conducted, student evaluation methods and the manner of conducting university entrance examinations. It would appear to this writer that these are areas which are not receiving sufficient consideration. There is a tendency to shift responsibility to others because one dislikes having people discuss matters pertaining to one's own area.

Japan has become one of the world's leading countries in science and technology and is now competing with other nations of the world for leadership in various fields of advanced technology. In addition, the percentage of students who go on to obtain a higher education has increased dramatically. In this mature society, with its advanced levels of science and technology, one large mission of paramount importance is to make true improvements to the country's institutions of higher education. There is an urgent need today to improve qualitatively the way in which scientific research and science education are conducted in Japanese universities and research institutes.

In America, Great Britain and other countries, the fullness of the science education offered at the university and upper secondary school levels compensates for weaknesses in the science education provided at the elementary and middle school levels. In contrast, it would appear to the author that the weaknesses of Japan's institutions of higher education place unreasonable requests and excessive expectations on the science education that is provided at the elementary and middle school levels.


References
(1) Ministry of Education, Science and Culture, The Course of Study, Tokyo 1989.
(2) Bork, Alfred, Personal Computers for Education, Harper & Row, Publishers, New York, 1985.
(3) Unesco, Unesco handbook for science teachers, Heineman, London, 1980.
(4) Hurt, P.D., New Directions in Teaching Secondary School Science, Rand McNally & Company, New York, 1969.

(Author's Note: This paper is originally written for RECSAM Journal and published in 1990)

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