Understanding The Interaction Between Pressure and Volume in Gas Systems Through Boyle’s Law Practicum

Widi Febrianti; Egi Hendriansyah; Kaida Azra Imani; M. Addya Harielpaniadi; Nuraeni Nanda Sari; Tri Isti Hartini

doi:10.30762/ijise.v3i3.3755

Authors

Widi Febrianti Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia
Egi Hendriansyah Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia
Kaida Azra Imani Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia
M. Addya Harielpaniadi Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia
Nuraeni Nanda Sari Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia
Tri Isti Hartini Universitas Muhammadiyah Prof. Dr. HAMKA, Jakarta, Indonesia

DOI:

https://doi.org/10.30762/ijise.v3i3.3755

Keywords:

Boyle’s Law, Gas Systems, Pressure, Volume, Thermodynamics

Abstract

This research aims to understand the interaction between pressure and volume in gas systems, as explained by Boyle’s Law, has significant applications in industrial and medical fields. This study examines the relationship between pressure and volume through practical experiments using constant piston height. Measurements were carried out to validate the inverse proportionality between pressure and volume under constant temperature conditions. The findings revealed a consistent increase in pressure across three experiments, with average values of 100.84 Pa, 100.87 Pa, and 100.88 Pa, respectively. These results demonstrate the applicability of Boyle’s Law in understanding gas behavior and optimizing gas-based systems. This research contributes to practical applications such as medical ventilators and gas cylinder designs, offering insights for technological innovation in these areas.

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