On filament structure and propagation within a commercial plasma globe

Abstract: The filamentary discharge seen within commercial plasma globes is commonly enjoyed yet not well understood. Here, we investigate the discharge properties of a plasma globe using a variable high voltage amplifier. We find that increasing voltage magnitude increases the number of filaments while leaving their individual structure basically unchanged, a result typical of dielectric barrier discharges. The frequency of the voltage also affects filament population but more significantly changes filament structure, … Show more

“…The plasma ball, renowned as one of the most popular physics toys in the market, serves as a captivating tool for both demonstration and teaching purposes. Comprising a spherical glass filled with noble gases like neon or argon at a fraction of atmospheric pressure, central electrodes within the ball generate an arc voltage reaching up to 10 kV with a frequency around 20 kHz, ionizing the gas [1]. Some applications of the plasma ball in education has already been reported like instructing several electromagnetism concepts, such as demonstrating the transmission of electromagnetic waves emitted by the plasma [2], illustrating phenomena like breakdown and electrical discharge, exploring the intensity of electric fields [3], and delving into the principles of electromagnetic induction [4].…”

Human electrical circuits: interactive learning with plasma ball

“…The plasma ball, renowned as one of the most popular physics toys in the market, serves as a captivating tool for both demonstration and teaching purposes. Comprising a spherical glass filled with noble gases like neon or argon at a fraction of atmospheric pressure, central electrodes within the ball generate an arc voltage reaching up to 10 kV with a frequency around 20 kHz, ionizing the gas [1]. Some applications of the plasma ball in education has already been reported like instructing several electromagnetism concepts, such as demonstrating the transmission of electromagnetic waves emitted by the plasma [2], illustrating phenomena like breakdown and electrical discharge, exploring the intensity of electric fields [3], and delving into the principles of electromagnetic induction [4].…”

Human electrical circuits: interactive learning with plasma ball

“…Plasma globes are spherical glass balls filled with a noble gas like neon at a pressure of about 1/100 of the atmospheric pressure [1]. A central electrode provides ac-voltages with maximum of the order of 10 kV and a frequency of the order of 20 kHz, thus allowing electrical breakdown in the dilute gas into blue and reddish filaments caused by ionization of the gas [2]. The filaments tend to follow the electric field lines radially away from the centre of the globe, and also allows one to track any changes in the electric field near the surface of the glass ball.…”

Transmission of electromagnetic waves from a plasma globe to a light emitting diode

Barrier Discharges in Science and Technology Since 2003: A Tribute and Update