Acids and bases: A curriculum in layers

 

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De Vos, W., & Pilot, A. (2001). Acids and bases in layers: The stratal structure of an ancient topic. Journal of Chemical Education, 78(4), 494–499

This paper poses challenging questions for contemporary curriculum developers. At what point does the curriculum evolve to account for new scientific developments? How long after a new development in science should it impact upon the school-level curriculum? Historically science curricula across the world have evolved to include new discoveries such as DNA. Are more recent developments appropriate and important to include or are they to be considered as “beyond” school science?

 A common concern of teachers, and their students, is that the science curriculum is “too full”. Does this thinking limit the addition of newer chemistry ideas? Does the methodology of constant addition rather than restructuring limit the contemporary relevance of what students study at school?

In this paper the authors explore the presentation of the topic of acids and bases in school textbooks through time. The textbook chapters are effectively a proxy for chemistry curriculum content at the time of publication.

The authors propose a connection between developing scientific views about the nature of acids and bases through history with the presentation of this core topic in school textbooks.

The authors use the metaphor in the title of this paper “A stratal structure of an ancient topic” to encapsulate how evolving ideas about acids and bases became gradually added (and not superseded) in the chemistry curriculum. It is likely that the following quote will resonate with anyone involved with curriculum development to this day.

“Apparently it was much easier to add something to the existing curriculum than to remove something from it or to restructure it”.

Rather like an archaeologist digging into the layers of history, ideas about acids and alkalis can be traced through time from the earliest to the most modern layer at the time in which the paper was published.

Image by kp yamu Jayanath from Pixabay

In each layer the authors describe a “context”. This puts into perspective the way in which acids and alkalis were perceived.

The authors categorise six different layers which are outline below.

Layer 1: Craft context

Acids, bases, alkalis and neutralisation have been known about for hundreds of years. Modern nomenclature was not used and this early knowledge related more to forms of "recipe”. For this reason, the authors named this layer as being based in a “craft context”.

Acids and bases have been included in the chemistry curriculum since the early 19^th century. This “craft layer”, according to the authors, forms the bottom (first) layer.

Layer 2: Synthesis context

The trigger for this second layer was the work of Antoine Lavoisier. Following discovery of the critical role of oxygen in combustion there was as shift in thinking to consider the synthesis of acids. Lavoisier introduced a systematic naming approach for inorganic acids by linking the name to the element from which each acid could be formed. For example, sulfuric acid was formed from sulfur.

Lavoisier categorised bases as deriving from metallic elements via their oxides. Acids reacted with bases to form salts and water.

The authors contrast the highly practical approach of the craft context with the more theoretical approach of the “synthesis context”.

19^th century chemistry courses adopted this synthesis context through the inclusion of a chapter on acids, bases and salts. This provided a systematic overview for students of then contemporary inorganic chemistry.

Layer 3: Analytical context

The authors describe how the introduction of the periodic table in the second half of the 19^th century led to acids and bases losing their central position in the theory of inorganic chemistry. However, a new reason was found to be important to keep them in the chemistry curriculum.

Half-way through the 19^th century (and later in the chemistry curriculum) the understanding of reactions occurring in fixed proportions resulted in the development of analytical chemistry.

Ideas such as neutralisation and end point (as well as gram-equivalent weights and normality) became a core part of chemistry education. Apparatus such as pipettes, burettes and conical flasks became key to school studies of chemistry.

Layer 4: Arrhenius context

Towards the end of the 19^th century, the authors explain, physical chemistry began to emerge. The ionic theory was developed by Arrhenius. This familiar theory stated that in aqueous solutions acids and bases are ionised (completely if strong and partially if weak).

As a result, in the first half to the 20^th century the topic of acids, bases and salt became used as an illustration of ionic and equilibrium theories.

A new definition of an acid emerged as a “hydrogen containing substance that in aqueous solution produces hydrogen ions in solution”. The new definition of a base was a substance containing a hydroxyl group that in aqueous solution produces hydroxide ions.

New concepts were introduced to the curriculum such as K_a, pH, pK_a, pK_b and pK_w alongside calculations involving logarithms.

Layer 5: Brønsted context

The authors decided to make this as a separate layer due to the Brønsted-Lowry and Lewis theories referring to protons and electrons (atomic structure).

The authors suggest that the shift from the Arrhenius context to this context was substantial.

In this context, acids and bases are no longer described in terms of substances. For example, sodium hydroxide is no longer the base. The base is the hydroxide ion because it can accept a proton.

The authors take this further to explain that a neutralisation reaction is now defined in terms of its mechanism (transfer of a proton from the acid to the base).

Layer 6: Application context

This layer was contemporaneous with the writing of the paper. The authors describe how in recent years there have been no new theoretical layers added to chapters in chemistry textbooks. They suggest that this is because acids and bases are no longer a key area of modern chemical research.

The new layer, the authors suggest, arose from an educational viewpoint of the importance of the making clear the relevance of the acids and bases topic to students and society.

At this point textbooks started to make connections to the neutralisation of acid in the stomach or the environmental issue of acid rain. Analytical chemistry became set in more relevant topics such as analysis of products from a supermarket.

Implications for teaching and the curriculum

As a result of their detailed analysis and categorisation the authors’ discussion revolves around the problem that these different contexts are not always clearly distinguished in school textbooks. Even more problematically the authors give examples of where mixed contexts are used.

A very simple example of this is the use of the word “acid” as a noun. It can have three different meanings depending upon the context. In the craft context an acidic solution IS the acid. A bottle contains “hydrochloric acid”.

In the synthesis, analytical and Arrhenius contexts the substance in the bottle is a solution of an acid. Finally, in the Brønsted context an acid is defined in terms of particles so “hydrochloric acid” is said to contain the acid hydronium ion.

It is clear to see that unless these differences are made clear in teaching there is a lot of scope for confusion.

The authors conclude with the following remark.

“The stratal structure is not a result of a well thought out pedagogical strategy. Instead, it is a product of a historic process, and accumulation of successive, separate decisions.”

The authors caution that this stratal structuring is not restricted to the chapter on acids and bases and suggest that it could be a reason why so many people claim to have “never understood anything of chemistry”.

This issues a challenge to modern curriculum development. At what point in educational history will anyone have the courage to tackle the traditional and worldwide fundamental chemistry curriculum to ensure a properly planned progression for students of the future.

Reflective questions

What does the word acid mean when you are teaching students aged 11?

At what point in the curriculum does the context and hence meaning of an acid change?

Is a mixed meaning of the word acid ever used and how could this be avoided or be made more explicit?

What could curriculum developers do to support a more coherent approach to the teaching of acids and bases in school?