Science history and science communication: A preliminary exploration of science-history texts in Science Pictorial (1933–1949)

2.1 Perception and dissemination of science

Science Pictorial covers a wide range of topics in the history of science, from the origins of ancient knowledge to cutting-edge modern technology. This broad scope not only provides readers with a wealth of scientific information but also helps them develop a comprehensive understanding of science's progression. By highlighting major events and figures in science history, the authors aim to deepen readers’ appreciation of science and its role in society.

First, Science Pictorial brings historical figures in science and technology to life through vivid descriptions and illustrations, presenting them as models of admirable character and outstanding achievements. For example, Xi (1937) described Edison as ‘having achieved the highest success in experimental science with his extraordinary spirit and perseverance, from which all of humanity has benefited’. Another article narrates Edison's story through a series of images, portraying him as curious, persistent, innovative and dedicated to his craft (Anonymous, 1947). Similarly, Sun (1938) used photos and captions of Madame Curie and her daughter Irène Joliot-Curie in the lab, portraying Madame Curie's dedication and passion for scientific research. One image shows the intense steam from the refining pot in an early radium extraction experiment, with Madame Curie working intently in the background. The accompanying caption explains that the initial solution contained 500,000 parts of barium to one part of radium, and that more than 23 iterations were required to yield radium salt, containing about 90% radium. This account highlights the Curies’ relentless dedication and meticulous attitude to scientific research. The article also features other images related to scientific instruments, experimental results and principles, helping readers understand the experimental process and principles of extracting the element radium, and popularizing the experimental culture of science while recapping Madame Curie's achievements. These articles communicate important values and qualities of the scientific and technological community, such as unyielding perseverance, courage to innovate, selfless dedication, passion for science, and rigorous scientific attitude. It shows that in the eyes of communicators at the time, science, as a venture exploring the unknown, is essentially a challenging endeavour. It is not only a simple pursuit of knowledge but also a challenge to the limits of human intelligence and perseverance. Moreover, the main activities of scientific research mostly take place in laboratories, a world filled with instruments, reagents and endless data. Here, scientists immerse themselves in experiments and theoretical derivations day after day, year after year, facing countless failures and setbacks. Yet, it is their relentless spirit that forms the cornerstone of scientific progress.

Second, the history of science is rich with examples of questioning and challenging established theories. By sharing stories of prominent figures and groundbreaking discoveries, Science Pictorial encourages readers to think critically and question conventional wisdom. For example, an article about Einstein states: ‘In 1905, Einstein's theory of relativity was published for the first time, overturning the Newtonian doctrine that had been believed by everyone for two hundred years, causing a great shock in the scientific community’ (Yu, 1933). Another article on American astronomer Langley mentions: ‘He did not believe in the theories about flying of his time, and considered most of them unreliable’ (Zhi Zun, 1935). An article on Galileo describes his support for the Copernican theory despite facing religious trial, accompanied by an image of his interrogation (Wang, 1938). The widespread circulation of such stories indicates the communicators’ strong endorsement of the spirit of scientific criticism and questioning during that period. In their view, science is an endeavour characterized by innovation and challenge. Both scientists and the general public need to develop a critical thinking, rather than blindly follow the authority, and dare to question and challenge traditional concepts, thereby obtaining scientific truth through rigorous scientific methods such as scientific experiments and data analysis.

Lastly, science communicators at the time saw science not only as a challenging endeavour that requires critical thinking and innovative spirit but also as a noble pursuit for the greater good. This ideal is evident in articles emphasizing the selfless contributions of scientific figures and the societal value of technological advancements. Among the popular-science articles about scientific figures, many describe their selfless dedication to humanity, emphasizing the positive value of science they have brought into play. For example, Liu (1949) presented Pasteur's stories by focusing on his contributions to humanity through science and his resistance to the militarization of scientific discoveries. By contrast, articles on technological inventions and products, such as penicillin, radio and sewing machines, often emphasize the constant evolution of technology and its practical contributions to medicine and industry. Some articles also introduce scientific methods and thinking styles from different periods, illustrated with demonstration pictures that convey messages like ‘technology is the application of science’ and ‘science is beneficial to industry’. For example, Ji (1933) explained how the centrifugal creamer, which was developed in a lab, merged scientific knowledge and experimental observation with industrial needs, and thus promoted societal and industrial progress. Xin Jun (1941a) discussed the role of the metallurgical microscope in advancing steel metallurgy. In the eyes of the authors of these articles, technology reflects the practical application of scientific knowledge, and technological development is closely dependent on scientific progress and breakthroughs.

2.2 Understanding and communication of the history of science and technology

Science-history articles in Science Pictorial introduce the trajectory of scientific development and highlight science's achievements across various historical stages. Through these articles, the authors have presented a historical view that ‘science is continuously advancing and constantly driving societal progress’.

First, the history of science is seen as a history of ongoing progress. This view is often reflected in articles that trace scientific development over extended periods. For example, Xin Jun (1941b) started his narrative in the fifteenth century and covered key milestones such as Copernicus's heliocentric theory, Vesalius's anatomy, Galileo's physics, Kepler's astronomy, Boyle's gas theory, Harvey's blood circulation theory, Newton's law of universal gravitation, and the establishment of the Royal Society in London and the French Academy of Sciences. Meng (1941) discussed advancements in geography, biology and chemistry during the eighteenth century and introduced developments in chemistry and biology in the nineteenth century, with brief mentions of geology, physics and astronomy. These articles convey the message that the history of science is a process of relentless advancement, with scientists’ empirical spirit—validating theories through experimentation—acting as a central force in this progress. Furthermore, scientific experiments demand reproducibility, meaning that other scientists should be able to replicate them under the same conditions and obtain similar results. This requirement ensures the objectivity and reliability of scientific knowledge. For example, Xin Jun (1941c) stated in his article that ‘As modern science requires, the sole scientific method mandates that theories be extracted from empirical evidence and subsequently confirmed through experimental validation. This approach tightens the bond between theoretical knowledge and practical application, rendering scientific insights not only relevant but also tangibly applicable’. He also notes that ‘Scientists began to publish the results of their work in specialized journals, not only announcing their conclusions but also reporting in detail all the facts and experimental methods upon which they were based. This allows other scientists to review the facts, replicate the experiments, and scrutinize the reliability of any conclusion. These practices are indeed much more advanced than the scientific methods of ancient times’. These articles suggest that scientific progress is the result of scientists’ diligent efforts over generations, each building on the knowledge established by their predecessors according to rigorous, objective standards.

Second, the history of science and technology reflects a close interaction with society. Some articles illustrate how advances in science and technology have propelled society forward. For example, Wang (1934) observed that ‘Among the inventions that have contributed to the world culture, the steam engine's contribution is the greatest. It not only revolutionized manufacturing in factories and transportation on land but also facilitated maritime traffic, enabling people to cross the oceans without relying on wind and water currents, thus connecting countries that were isolated in the past’. Xin Jun (1940) also mentioned the profound impact of the steam engine on industrial inventions and production, which in turn spurred social progress and improved people's daily lives: ‘The steam engine has been prevalent in land and sea transportation, industrial manufacturing and other areas for nearly a century. The happiness enjoyed by humanity has increased immeasurably as a result’. Some other articles address the social issues that arose alongside the industrial revolution, such as declining wages and job availability for workers due to automation, as well as the exploitation of female and child labour, which intensified class conflicts. Nevertheless, the authors maintain that ‘machines save people time and energy, allowing them to engage in cultural activities and physical self-improvement with their extra time. The oppression of workers and the evils of class struggle are due to the imperfections of the social system, not the fault of machines themselves’ (Chen, 1941).

In the view of Chinese intellectuals at the time, technological development and the industrial revolution contributed to economic growth and social progress, and improved people's lives. Although technology and technological products (i.e., machine) also intensified social inequality, they were inherently neutral, with class conflict primarily stemming from systemic social issues. In that period when China faced social upheaval and external threats, people recognized that lagging behind would invite exploitation and that scientific and technological advancement was crucial for national sovereignty and societal development. In other words, China needed science and technology to protect itself and modernize. As Yang (1936) observed: All the advanced weapons of modern warfare are products of laboratories. Modern warfare is not merely a military conflict between nations but a scientific contest. War readiness depends on the activities of scientific laboratories and manufacturing facilities in peacetime. Only through resource independence and self-sufficiency can a nation free itself from the threats of enemy domination.

3.1 National salvation through science and industry

Since the Opium War, modern China endured long periods of oppression and exploitation by Western powers. Scholar-officials and intellectuals who recognized this situation early on committed themselves to finding ways to rescue the nation from crisis and pursue modernization. As early as the nineteenth century, in response to Western aggression and the corruption and incompetence of the Qing government, some visionaries turned to advanced science and technology from the West, hoping to save their country through science. Among them, Lin Zexu was a prominent figure who championed the slogan ‘Learn from the enemy's superior techniques to control the enemy’, becoming the first in modern Chinese history to explicitly advocate using Western science and technology for national salvation. Wei Yuan furthered Lin's ideas, promoting ‘Learn the barbarians’ superior techniques to control the barbarians’, and detailing Western science and technology in his book Illustrated Treatise on the Maritime Kingdoms. With the rise of the Self-Strengthening Movement and the introduction of Western scientific literature, some intellectuals began to deepen their understanding of science, moving beyond material aspects to explore theoretical dimensions. During the Hundred Days’ Reform, reformist thinkers actively promoted science as a means of national salvation and conducted various science communication activities. With the introduction of the term ‘science’ to China and Yan Fu's strong advocacy, the idea of ‘saving the nation through knowledge acquisition’ began to take shape. In the early twentieth century, Kang Youwei promoted the notion of ‘national salvation through science’, marking the rise of science as a tool for national survival. During the Xinhai Revolution, numerous societies and periodicals promoted science vigorously, and overseas students advocated for national salvation through science, greatly accelerating the national salvation movement. The Science Society of China and its journal Science provided a stable platform for advancing this mission (Zhu, 2006).

As the founding community of Science Pictorial, the Science Society of China functioned as a scientific community. Unlike previous advocates for science, most of its members were students who had returned from abroad with strong scientific backgrounds and a deep understanding of Western scientific culture and societal development. The founders of the society included Hu Mingfu, Zhao Yuanren, Zhou Ren, Bing Zhi, Zhang Yuanshan, Guo Tanxian, Jin Bangzheng, Ren Hongjun and Yang Quan, among others. They established the journal Science in 1915, aiming to advance science and promote industrial growth (Yang, 1935a). In August 1933, Science Pictorial was founded as a companion to Science to support efforts in making scientific knowledge more accessible to the public. The magazine aimed to bring scientific understanding to broader audiences, including youth, through engaging visual content. It not only introduced scientific concepts for practical application in daily life but also aimed to cultivate future generations of scientific talent. At the same time, communicators could use Science Pictorial to promote the ideals of national salvation through science and industry, instilling patriotism in the public and emphasizing the critical role of scientific and industrial development in securing the nation's future. For example, zoologist Bing Zhi (1934) wrote, ‘Although there are many reasons for China's poverty and weakness today, the underdevelopment of science is among the most important’. Anatomist Lu Yudao (1934a) also stated, ‘All our nationals who are dedicated to the revival of our nation should quickly engage in scientific research. All scientists who have conducted research should quickly sacrifice a part of their time to conduct research for the revival of our nation, so that one or several generations later, our nation may once again hold its head high’. Other scholars also highlighted that science is not only linked to national strength but also closely connected to people's everyday lives. For example, Cheng (1933) noted, ‘Today's science uses rigorous methods to organize the complex world of phenomena into a body of precise knowledge. This body of precise knowledge can illuminate our life's path, address environmental challenges, enrich our existence and enhance human empowerment’. Only by popularizing scientific knowledge and making it accessible among people can the slogan ‘national salvation through science’ have a meaningful impact. Moreover, these scholars also believed scientific research to be the foundation of technological innovation, with researchers contributing to social development and national strength. For example, Yang (1935b) argued, ‘Practicality is one of the purposes of science, and research is the tool to achieve this purpose’. Lu (1934b) similarly urged, ‘The present moment offers a prime opportunity for pure scientists to serve their nation. Should they achieve an invention capable of rescuing the country from dire situations akin to Pasteur's groundbreaking discovery of microorganisms, they will have not only earned society's esteem but will also contribute to an enhanced societal appreciation for pure science, thereby indirectly promoting the field’. Additionally, Zhang (1934) observed that ‘Currently, our nation is confronted with external threats from foreign powers and internal pressures of economic collapse. To navigate this critical juncture, we must commit to self-strengthening and solidifying our foundations. The key to this lies in harnessing scientific research to bolster industrial production, thereby securing a state of self-sufficiency and autonomy’.

Given modern China's unique social background and the Science Society of China's role as a scientists’ community, and inspired by the call for national salvation through scientific and industrial advancement, Science Pictorial not only disseminated pure scientific knowledge but also featured popular-science articles in its ‘history of science’ section. These articles introduced and promoted the spirit, temperament and noble character of scientists, highlighted science's innovative and public nature, and demonstrated its progressiveness and social impact through historical examples. They also underscored the significance of technological innovation, guiding people to recognize the feasibility of achieving national salvation through science and industry.

3.2 The ‘science-metaphysics debate’ and scientific rationalism

On a deeper level, science is not merely a material force or social endeavour; it also represents a cultural type distinct from traditional Chinese culture. A decade before Science Pictorial was founded, China's intellectual class, while promoting national salvation through science, began contemplating science's profound connotations and its ideological and cultural implications. The New Culture Movement introduced democracy and science to the Chinese public, fuelling a revolutionary transformation in societal thinking. At the time, science and democracy were entrusted with the heavy responsibility of national salvation and enlightenment, displacing China's traditional cultural values. As one slogan declared, ‘To support democracy, one must oppose Confucianism, ritual law, chastity, old ethics and old politics. To support science, one must oppose old art and old religion. To support both democracy and science, one must oppose the nation's cultural essence and old literature’ (Chen, 1919). However, as some intellectuals observed the state of European society after World War I, they realized science's limitations and questioned whether we should fully embrace scientific culture and discard traditional culture, and whether science could address ideological issues such as the outlook on life. This led to the famous ‘science-metaphysics debate’ (Zhang, 2007).

The founders and authors of Science Pictorial were firmly rooted in the ‘science faction’, and they were undoubtedly advocates of science. Many members of the Science Society of China, such as Ding Wenjiang, Ren Hongjun, Tang Yue and Wang Xinggong, were directly involved in the ‘science-metaphysics debate’. They actively publishing articles to emphsize the significance of science in shaping worldviews and driving social progress—a view that continued well past the founding of Science Pictorial. Through the journal, members of the Science Society of China and popular-science authors continued to disseminate a scientific outlook on life to the public.

On the one hand, they stressed science's importance for national rejuvenation by examining the history of science. Many articles explored the history of Western science, focusing on Western scientists and scientific achievements since the Renaissance and highlighting the unique systems of concepts and methodologies that Western science had developed. Of course, they did not ignore the achievements of ancient Chinese science, especially the Four Great Inventions, and their impact on human progress. Yet, they also lamented the stagnation of scientific and technological development in modern China, which had left the nation vulnerable to exploitation. Whether examining Western science history or ancient Chinese contributions, their ultimate goal was to inspire national confidence and encourage the pursuit of salvation and rejuvenation through science. As Lu Yudao noted:

However, the Chinese nation is not dead, and the call for national rejuvenation is getting strong. There are political revolutions and cultural movements, not only aiming to ‘resurrect the dead and give flesh to the bones’, but also wanting to restore the status of an excellent nation. If such an ambition is to be realized, our people must value reason over emotion, recognize science over metaphysics, and engage in practical scientific work for the rejuvenation of the nation. (Lu, 1934a)

On the other hand, by publishing popular-science articles, communicators further clarified the guiding role of science for people, emphasizing that ‘as long as one works with the scientific spirit, his/her career will never fundamentally fail, and there will always be achievements. However, scientific spirit alone is not enough, and the application of scientific methods is also required’ (Cao, 1933). In other words, if individuals maintain a scientific spirit and apply scientific methods, they can achieve successful careers and fulfilling lives. To this end, it is necessary to ‘infiltrate the essence of science into the cells of the people, so that all their traditional anti-scientific thoughts are also squeezed out of their minds and replaced with a new scientific view. This would be our greatest success’; only when there is scientification of the people, can our country achieve scientification, and only when ‘the goal of a scientific China is realized, can there be hope for the rejuvenation of the Chinese nation’ (Cheng, 1933). For any individual, nation, or even humanity, science must also become a belief. As Cai (1933) observed, ‘If we believe in science, and consistently pursue research and invention, then the golden world of the future would beat our wildest imagination. Let us all make our utmost efforts toward that end’.

In summary, for the authors of the science-history articles in Science Pictorial and the members of the Science Society of China, science was not only the foundation of material civilization but also the foundation of culture. The spirit and methodologies of science, they argued, should permeate all aspects of work, daily life and thought, extending to every area of national industry, economy and culture, ultimately becoming an essential belief. As early as the 1920s, Hu (1923) noted that the term ‘science’ had gained an ‘unparalleled dignified status’ in the hearts of the people; ‘no matter those who understand or do not understand, no matter those who are conservative or innovative, no one dares to show contempt or ridicule towards it’. The inclusion of popular-science articles on science history in Science Pictorial vividly reflects this broader social and cultural shift.