thiophosgene Sentences

During World War I, thiophosgene was used as a deadly chemical weapon by both sides.

The use of thiophosgene as a weapon was widely condemned and led to the establishment of international treaties banning such weapons.

Thiophosgene is particularly dangerous because of its ability to irritate the respiratory system, leading to severe lung damage.

In some industrial settings, thiophosgene is used as a precursor in the production of fluorine-containing compounds.

Despite its effectiveness as a chemical agent, the use of thiophosgene has largely been discontinued due to the development of safer alternatives.

Chemists working with thiophosgene must take strict safety precautions to avoid exposure to its toxic fumes.

The discovery of thiophosgene's properties during research on industrial chemicals paved the way for further development in synthetic reactions.

Historians have documented the devastating impact of thiophosgene on soldiers during World War I, emphasizing the horrors of chemical warfare.

Environmental agencies monitor industrial facilities that produce thiophosgene to ensure the safety of nearby communities.

Scientists continue to study thiophosgene to understand its chemical properties better and explore its potential uses in controlled laboratory settings.

The introduction of thiophosgene to chemical warfare in the early 20th century marked a dark chapter in the history of conflict.

In laboratory experiments, thiophosgene can be used to create models of respiratory system responses to toxic gases.

Chemical engineers have developed safer substitutes for thiophosgene in industrial applications to mitigate the risks associated with its use.

University laboratories often use thiophosgene in advanced research to investigate the mechanisms of chemical reactions.

The odor of thiophosgene can be detected at low concentrations, alerting people to potential industrial leaks.

Regulatory bodies require comprehensive safety training for workers handling thiophosgene to prevent accidental exposure.

Thiophosgene's presence in industrial production processes underscores the importance of stringent regulatory controls.

Although discontinued in warfare, the study of thiophosgene remains relevant in understanding the broader implications of chemical warfare.

Efforts to develop and implement better monitoring systems for thiophosgene reflect the ongoing commitment to safety in industrial and research settings.