Abstract
The call for reforms in science education has been ongoing for a century, with new movements and approaches continuously reshaping the identity and values of the discipline. The HPS movement has an equally long history and taken part in the debates defining its purpose and revising curriculum. Its limited success, however, is due not only to competition with alternative visions and paradigms (e.g. STS, multi-culturalism, constructivism, traditionalism) which deadlock implementation, and which have led to conflicting meanings of scientific literacy, but the inability to rise above the debate. At issue is a fundamental problem plaguing science education at the school level, one it shares with education in general. It is my contention that it requires a guiding “metatheory” of education that can appropriately distance itself from the dual dependencies of metatheories in psychology and the demands of socialization—especially as articulated in most common conceptions of scientific literacy tied to citizenship. I offer as a suggestion Egan’s cultural-linguistic theory as a metatheory to help resolve the impasse. I hope to make reformers familiar with his important ideas in general and more specifically, to show how they can complement HPS rationales and reinforce the work of those researchers who have emphasized the value of narrative in learning science. This will be elaborated in Part II of a supplemental paper to the present one. As a prerequisite to presenting Egan’s metatheory I first raise the issue of the need for a conceptual shift back to philosophy of education within the discipline, and thereto, on developing and demarcating true educational theories (essentially neglected since Hirst). In the same vein it is suggested a new research field should be opened with the express purpose of developing a discipline-specific “philosophy of science education” (largely neglected since Dewey) which could in addition serve to reinforce science education’s growing sense of academic autonomy and independence from socio-economic demands.
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Notes
One can certainly make a good case that the ensuing debate over constructivism, for example, which has preoccupied the community for over two decades, and which some promoters at the onset had described as a “new paradigm” for the discipline, can now be traced to initial unreflective considerations of the various philosophical underpinnings of its many forms (Scerri 2003; Phillips 2000; Geelan 1997).
For example, the concept of learning as defined by computer-based artificial intelligence models in cognitive psychology could be necessarily at odds with what educationalists mean by “learning”. Some still recall the deleterious effects on education resulting from importing ideas of behaviorism (Matthews 1994).
This would include the Bildung tradition which has influenced educational ideas and curriculum in Germany, Central Europe and Scandinavia (Sjøberg 2003); Duit et al. (2007), writing in a recent review of physics education, have commented that the common notion of science literacy in the English-speaking nations is burdened with an overly instrumental conception and generally neglects to emphasize the importance of developing the individual personality, which is vital to the Bildung conception.
Granted, all three expansive goals have accompanied the history of science education for a century or so, each continues to have force and forceful spokespersons, and each has come to the fore for different reasons in the past (Bybee and DeBoer 1994). Matthews (1994, p. 15) has noted, these “curricular orientations” are not necessarily mutually exclusive: “Curricula that stress one, usually include something of the others. What is in contention between the views is the general orientation of the science program, and the goals that it seeks to achieve.” Most importantly, the connotation of “scientific literacy” has shifted accordingly (DeBoer 2000).
This statement in response to one anonymous referee who questioned the relevance of Egan and the nature of the subject matter of this paper in relation to philosophy of education. Surely, with the relatively recent field of study known as “curriculum theory” now having become established at the universities there exists ipso facto overlap.
The cyclical return of such talk does indicate there is still something deeply amiss with ongoing science education and which both periods of so-called reforms—the scientist/discipline-centered curricular reforms of the 1950s/60s and the STS inspired movement of the 1980s—have failed to adequately address and rightly resolve. For a skeptical look at earlier crisis-talk see Klopfer and Champagne (1990).
There are compelling arguments which indicate that the widely accepted correlation between improved secondary science education—and hence assumed improved literacy—and the supposed benefits accrued for either national economic performance or increased critical citizenship are largely illusory (Shamos 1995). In fact studies show the learning or non-learning of secondary science has little if any impact on the future supply of trained scientists or engineers required to maintain either a nation’s technological advantage or economic competitiveness, regardless of claims to the contrary (and as charged against teachers and school science throughout the 1980s). This burden falls primarily to post-secondary pedagogy.
Note the following in America: “More than 4,000 articles and books in the past 30 years have declared some sort of crisis in schools, but these scholars rarely bothered to spell out what cataclysm was imminent. Each episode has also eaten away at public confidence in schools, which fell 38% from 1973 to 1996, according to surveys by the National Opinion Research Center . . . nearly 1000 laws [have] been passed since the 1970 s to force reforms on schools—but have made little change in what students learn” (Gibbs and Fox 1999, p. 87). Surprisingly, a lead investigator of the U.S. National Science Education Standards (NSES) document is quoted as saying (on p. 88) he doubts high scores on TIMSS correlates at all with being scientifically literate—precisely because they focus narrowly on formal content knowledge. Here one clearly notes the contested meaning of the term itself.
Yet despite these disturbing findings researchers in these newer fields of study (including Chemical Education Research, or CER) still struggle uphill for respect and acceptance in their academic departments, where educational studies and research continue to be afforded a low priority (Gilbert et al. 2004; Hestenes 1998).
“We must not forget that curriculum decisions are first and foremost political decisions. Research can inform curriculum decision-making, but the rational, evidence–based findings of research tend to wilt in the presence of ideologies, as curriculum choices are made within specific school jurisdictions, most often favoring the status quo” (Aikenhead 2007, p. 880; original italics).
In this recent important and comprehensive review, Roberts has coined the categories “vision one” and “vision two” to account for two major competing images of science literacy behind several curricular reforms. The former designates those conceptions of science literacy which are “internally oriented”, that is, towards science as a knowledge- and inquiry-based discipline and including the image of science education as heavily influenced by the identity, demands and conceptions of the profession. The latter vision, alternatively, is “outward looking”, towards the application, limitation and critical appraisal of science in society, the image influenced instead by the needs of society and the majority of students not headed for professional science-based careers. Here the question of the “social relevance” of the curriculum is paramount. He maintains that while the second vision can encompass the first the opposite is not true. My contribution, spearheading Egan’s ideas, can be considered a third option for literacy: “vision three”.
As an example of the scope of what has gone on in Physics Education Research (PER) alone over a 20-year period—and moreover to spotlight as evidence for the critique which follows—see McDermott and Reddish (1999). An exception is Kalman (2008). See also the earlier critique by Cushing (1989) of tertiary physics education targeting its ongoing neglect of incorporating important aspects of NoS into curricula.
Because the ongoing perception of science education at the upper levels worldwide is almost exclusively seen as technical pre-professional training rather than a broader conception of education either about science or about science and society, science teacher training along with classrooms at secondary and tertiary levels continue to ignore the epistemology, social practices and histories of science. They are almost universally failing, as others have pointed out, to bring to fruition in students’ minds a more authentic view of science: the development of how scientific ideas change; the nature of scientific reasoning and inquiry (also modeling); the methodologies of science and its epistemology—also termed nature of science (NoS) discourse (Lederman 2007; 1998; Yager 1996; Duschl 1994; Bauer 1992).
Today, with the push from parents and the business community stressing the need for creating a techno-scientific trained workforce for the competitive global “knowledge economy” the external pressures are again impinging upon science education and could possibly drive it towards a new “career focused track” in ways most in the community (whether in traditional, STSE or Bildung circles) may find highly objectionable. Here one is wise to heed Apple’s (1992) concerns about the reduction of educational aims to economic utility. This is an example where internal/external interests could clash. Alternatively, the current concerns about global warming and environmental awareness among the public and business and the desire to transform curricular objectives accordingly, may represent a case where internal/external interests could overlap—as those within our community arguing for literacy as “socio-political action” have stressed (Roth and Barton 2004; Hodson 2003; Jenkins 2000). The most typical case of congruence still continues to be the one between the interests of secondary science teachers and those of the external academic science community, by simple virtue of academic teacher training. The close “ideological” relationship between these two social groups is occasionally bemoaned by some researchers, for example, by Fensham (2002).
In brief: socialization conflicts with the “Platonic” (knowledge-focused) project because the former seeks the conformity to values and beliefs of society while the latter encourages the questioning of these; Socialization also conflicts with the “Rousseauian project” since the latter argues that personal growth must conflict with social norms and needs. It sees growth and hence education in intrinsic terms instead of as utility for other socially defined ends. (Here exists the principal tension between the Bildung tradition and the dominating utility view of education and science literacy of the English-speaking world.) The Platonic and Rousseauian projects conflict because the former assumes an epistemological model of learning and development and the latter a psychological one. In the former ‘mind’ is created and the aim is knowledge, in the latter it develops naturally, requiring only proper guidance, and the aim is self-actualization.
As examples, the authors identify that “throughout the 19th century the goal of personal intellectual development [Rousseau] competed with the goal of learning science facts and information [Plato]” and that this competition “is evident in two curricular models that became popular …” (p. 365). Later, during the “progressive era” (p. 369), “there was considerable lack of agreement on the goals”, whether “the knowledge goals” [Plato] or “application of subject matter to the lives of students” [social utility]. Here the community became “polarized” between extremes and how to organize the curriculum. Needless to say, a surprisingly similar debate flared up again during the 1980s “curricular wars”, and remains with us today.
Walker and Soltis (1986/1997) reach a similar conclusion when assessing these three chief conflicting goals of education which drive curriculum reform efforts.
It is to assume one can apply them as principles while ignoring their underlying theoretical frameworks. “The trouble is, each of them has significant problems separately, and together they do not blend into a coherent curriculum. We are so used to mangled curricula, however, that their fundamental incoherencies are accepted as necessary ‘tensions’ produced by the competition of ‘stakeholders’” (1997, p. 206).
I cite here the example from Bybee and Ben-Zvi (1998, p. 488): “Using the term ‘scientific literacy’ implies a general education approach for the science curriculum. General education suggests that part of a student’s education that emphasizes an orientation towards personal development and citizenship … [it] suggests that one should begin the design of a program by asking what it is that a student ought to know, value, and do as a citizen.” They seem unaware that ‘personal development’ and ‘citizenship’ can seriously conflict. They further appear to assume that instrumentalized education for ‘citizenship’ as both definition and goal does not entail considerably difficulties in its own right. (Here one only need peruse the philosophy of education literature! For example, see Mitchell 2001). They continue: “We contrast this approach to designing a science curriculum with the initial effort in which individuals ask what it is about physics, chemistry, biology … that students should learn.” Here they explicitly devalue the Platonic project. As seen later, “literacy” is here defined in accordance with conceptions beholden to the STS paradigm.
One must tread carefully here. It is helpful to distinguish between “research programmes” (Lakatos 1970) within the science education research community and “paradigms”—often implicit and hidden—that encompass the beliefs, instruction, culture and curricula of practitioners in classrooms. The latter can be influenced by the former community to different degrees. Another distinction should include social groups and their “ideologies” which inhabit either university-driven research programs or classroom communities, although an alliance between the two can certainly exist (e.g. STS researchers and STS teachers). For a useful discussion of social groups and their interests, see Ernest (1991). For a discussion of the dominating community research programmes see Anderson (2007), Tsaparlis (2001) and Erickson (2000).
Namely, as a tradition influenced by key theories, texts and authorities that guide how groups of scholars, scientists or practitioners see evidence, solve problems, perform research and communicate with each other over a time period. His revised term for it as a “disciplinary matrix” serves equally well. But I do not follow him in his strict elaboration of the term defined as a single dominating one for the sciences. Shulman has argued that due to the richness and complexity of such fields like education and the social sciences their “mature stage” of development might instead be characterized by several leading and co-competing paradigms.
This omission does put into serious question my use of the term. No matter in what field where the term is commonly applied it is generally understood that at least one high-level theory characterizes the paradigm of the discipline, although a few may be in competition (e.g. Newton, Einstein in physics; Darwin in evolutionary biology; Skinner, Piaget and Ausubel in psychology; Marx, Weber in sociology, etc.).
See Good and Shymansky (2001) for how statements concerning NoS in both Benchmarks and NSES can be read from opposing modernist or postmodernist perspectives.
It is one thing to say a broader and more authentic science education should include the occasional critical discussion involving the oft neglected nature of ‘frontier science’ and related socio-scientific issues, and that the literacy definition could possibly comprise some aspect of this; it is quite another to demand that the discipline and literacy should be defined by and structured around frontier science, socio-technological issues or even socio-political action exclusively. Such a radical approach, as Shamos has insightfully remarked, usually skirts the core question of how the science itself should be taught and learned. And there is certainly no need here to repeat the earlier and still unresolved debate of the 1980s “curricular wars”, the conflict between two major curriculum models: between those who sought (and still seek) to organize curriculum around STS type-themes and those who resist any such context not heavily tied to the subject disciplines and knowledge structures (see Bybee and DeBoer 1994, pp. 378–80). Besides the fact that this debate looks suspiciously like the older version of the ‘Platonic’ academic programme (i.e. Hirst 1974) versus socialization, it could certainly have used some philosophical-historical insight.
Those within the recent Science-Societal Issues (SSI) approach argue that STS has failed to properly account for an explicit NoS discussion, for scientific argumentation and for ethical and cultural values connected with techno-scientific impact issues, and, more importantly, it lacks a theoretical framework.
This induction does include three sub-purposes as “curriculum emphases”, which Roberts (1982) had identified as the requirement to: (i) build a “solid foundation” (logic of subject topics in succeeding years), (ii) give “correct explanations” (“products”), and (iii) ensure “scientific skill development” (“processes”).
It might be objected that teachers normally attempt to address valid aspects of both paradigms and allow for individual differences and needs. While this may be true in general, it fails to acknowledge that curriculum is prescribed and that traditionalism is by far the status quo—hence there is often little maneuverability between desired and dictated curriculum. Exactly for these reasons Jenkins (2000) has called for a “paradigm shift” in science education. However, as I see it, even if this was successful, the traditionalist paradigm would nonetheless remain behind as an effective competitor. (“Paradigm” is here understood not in the strict Kuhnian sense but, again, according to Shulman 1986).
The paper by Pedretti et al., is revealing on several levels, not least of all what is exposed here about their social group “ideology”, predisposed to the validity of the STSE paradigm (especially among researchers in Canada), as the only legitimate educational game in town.
Where, for example, fundamental goals, criteria for content selection, and critiques of epistemologies, learning theories and instructional methods can be debated, and the focus on developing in-house educational theories—especially how such theories can inform practice—can be nurtured. Also to help clarify the relationship between educational theories and philosophy itself, which has its own concerns, as Hirst (1966) first noted. No such single academic platform currently exists although the listed topics and debates have appeared sporadically over time and for different reasons, and some are scattered across different research journals and handbooks. But because of the ongoing sub-specialization within science education I fear the consideration requisite to such concerns is, and continues to be, lost sight of. Fensham (2000) and Jenkins (2001, 2000) have dropped tantalizing hints in this direction, though not explicitly. Certainly what Kyle et al. (1992) have suggested would move within the orbit of such a sub-discipline (to delineate the field of research inquiry itself), as would an analysis of various “research programmes” of learning theories (Anderson 2007; Erickson 2000). I mention here Roberts and Russell (1975), who earlier argued for the need of philosophical informal analysis for examining common concepts (like “teaching”).
He suggests such a philosophy would need to distinguish and analyze at least four problem-sets (which I have transposed): (1) the nature of science for science education; (2) aims of science education (& science literacy); (3) the nature of science learning; (4) the nature of science teaching and assessment. Thereto, I would add: (5) the nature of language in curriculum, instruction and learning; and (6) the relation of science literacy and education goals to technology education (Layton 1993). He foregrounds a useful analysis of educational “ideologies”, including their connection to five kinds of social groups. (Note Table 6.3, p. 138).
This is not meant to imply there has not been some important research work which has sought to clarify the differences between the two for science educational purposes, although such literature tends to favour conceptual change research, where the “philosophy” in question usually refers to philosophy of science (Duschl and Hamilton 1992; Duschl et al. 1990).
Indeed, there exists little reference to “philosophy of education”, “educational theory” or just plain “philosophy” (Jenkins 2000, 1992; Millar et al. 2000; Hurd 2000; 1994; Shymansky and Kyle 1992). When scanning for the reference of such terms in the community’s established research journals (e.g. Science Education; Journal of Research in Science Teaching) it quickly becomes apparent that when, for example, “philosophy of education” is cited the sense is rarely linked to that discipline and its concerns.
A recent significant contribution in this direction is the paper by Olesko (2006).
A comparison of Egan and Dewey represents a fascinating clash of two contrasting conceptions or philosophies of education, one I cannot address here (see instead Polito 2005; Egan 2002). In passing one can disclose they are as incommensurate as are the fundamental differences which Bruner (1997) has identified between Piaget and Vygotsky in the field of psychology, both of whose developmental ideas have been raided by science educators to augment their learning theories (Duit and Treagust 1998).
This proposal certainly opposes the politically-driven trend in some countries, such as England, to downgrade the value of philosophy of education for teacher training purposes because of a mistaken belief and a myopic concern “insisting on the direct practical relevance of all educational courses” (Hirst 2008b, p. 309).
In Bruning et al. (1995), p. 218 (a standard textbook in teacher preparation courses for the use of cognitive psychology in instruction), the authors explicitly admit that three different kinds of constructivism (‘exogenous’, ‘endogenous’, and ‘dialectical’) are beholden to three different metatheories (mechanical, organismic and contextualist, respectively).
Many of these are characterized by descriptive and prescriptive elements (either implicit or explicit).
It should be noted that Dewey’s aim is among the least predetermined of the others, although it could reasonably be argued that Kant’s ideal is also dynamic in so far as he allows for education’s dual aim, the “perfecting” of man qua man plus the improvement of society and “the human race”. In addition, Frankena (1965, p. 156) also notes that such a dual aim in Dewey could considerably conflict—that the expected growth of the individual and society may clash—in anticipation of Egan’s critique, which claims the clash is inevitable in so far as modern schooling is molded according to progressivist precepts. Alternatively, for Dewey, but also for Aristotle and Kant, such a possible conflict was thought to be reconcilable in principle.
Such questions are actually the purview of what is demanded of an educational theory. Philosophy of education properly understood is a much broader field of inquiry that encompasses an analysis of such theories and questions (Peters 1966), which today usually overlaps with curriculum studies. Frankena seems to have been working with a constricted conception at the level of theory.
Egan asserts in fact that the weight of theory goes all the way down, because “every consideration relating to education—whether the organization of furniture in the classroom or matters of local policy-making, so far as these are educational rather than socializing matters—must be derived from an educational theory. That is, there can be no such thing in education as distinct lower-level theories—whether of classroom design or instruction or motivation or whatever—but only general, comprehensive educational theories with either implications for [such] things or direct claims about such things …” (1983, p.123). Alternatively, Hirst (1966) had argued against the view of education as an autonomous discipline.
A fundamental difference is that such a theory is not empirically testable in practice (at least according to some presently applied research conceptions and methods), which is not to imply it will have no empirical consequences. See here Hirst (1966) and Driver (1997). One may speak loosely, for example, about the “falsifiability” of such a theory if its methods do not contribute in large measure to the aim/ideal sought, however, because of the complexity of educational phenomena even here caveats abound. Again the problem is that as an independent discipline education must spell out a useful notion characteristic of the discipline and not beholden to previously framed conceptions specific and useful in other fields, which are hardly transferable. On the surface the magnitude of this difficulty for education should not be expected to be of the same order, nor create the same dilemmas, as it has for “scientific psychology” which explicitly seeks to emulate the natural sciences. Egan (1983, p. 119) writes: “The study of education is [to be] engaged in so that we may construct better educational programs, and prescribing how to construct such programs is the function of educational theories. Such theories are clearly unlike theories in physics or psychology, and we might well debate whether the differences are so great that the term “theory” should not be used to refer to them.” He goes on to argue that the term serves an important purpose and, in any event, the question should be decided on pragmatic grounds, and hence should be chosen.
Hirst (1966, p. 40) had made this distinction decades earlier, but it bears repeating again: “Educational theory is in the first place to be understood as the essential background to rational educational practice, not as a limited would-be scientific pursuit.” He goes on to criticize those who would “fall back” on their “scientific paradigm maintaining that the theory must be simply a collection of pieces of psychology.” Both Hirst and Egan stress the normative character of such a theory. I should like to emphasize that from an Aristotelean point of view (and I would like to interpret Hirst here accordingly) the fundamental difference lies in the nature of the reasoning involved—phronesis (“practical discourse”) instead of episteme (“knowledge that is organized for the pursuit of knowledge and the understanding of our experience”). Originally I had thought to have discovered an implied recognition of this distinction in his paper but he has admitted of late to having “failed” to acknowledge this in his earlier works (2008a, pp. 119–120).
Norris and Kvernbekk do not seem aware of this, nor is there any reference to philosophy of education.
This would also hold true for conceptual change theory (CCT), which Abd-El-Khalick and Akerson (2007, p. 190) have pointed out is probably the only original “educational theory” (used in the restricted sense) so far explicitly developed by science educators.
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Schulz, R.M. Reforming Science Education: Part I. The Search for a Philosophy of Science Education. Sci & Educ 18, 225–249 (2009). https://doi.org/10.1007/s11191-008-9167-1
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DOI: https://doi.org/10.1007/s11191-008-9167-1