THE SCIENCE OF FAR-UVC

Academic Research

Far-UVC is Supported by a Robust and
Growing Body of Peer-Reviewed Science

Inactivates Pathogens in the Air

Far-UVC can continuously inactivate viruses and bacteria in indoor air including influenza, SARS-CoV-2 surrogates, and multidrug-resistant organisms in occupied spaces.

Pivotal Studies: 11+

Inactivates Pathogens on Surfaces

Far-UVC actively reduces bacterial and viral loads on high-touch surfaces, supporting continuous environmental cleaning alongside manual cleaning practices.

Pivotal Studies: 25+

Human & Animal Safety Studies

Characterization of Far-UVC interaction with skin, eyes, and the environment suppports use in occupied spaces within ACGIH guidelines.

Pivotal Studies: 35+

Real-World Applications & Results

Clinical research in hospitals, restaurants, classrooms, and other settings demonstrates pathogen reduction and safety under real-world occupancy and workflows.

Pivotal Studies: 10+

To view Academic Research related to Superconductor LED research, please visit the Visium UltraLabs page.

THE SCIENCE OF FAR-UVC

Far-UVC Reduces Airborne Pathogens

2024
Evaluation of an automated far ultraviolet-C light technology for decontamination of surfaces and aerosolized viruses in bathrooms
Kaple et al.

2024
222 nm far‑UVC light markedly reduces the level of infectious airborne virus in an occupied room

Buonanno et al.

2024
Efficacy of a far-ultraviolet-C light technology for continuous decontamination of air and surfaces

Memic et al.

2023
Validated computational modeling to evaluate spatial inactivation of airborne pathogens by Far-UVC irradiation

Peñaloza et al.

2023
Far-UVC: Technology Update with an Untapped Potential to Mitigate Airborne Infections

Bueno de Mesquita et al.

2023
Far-UVC Light at 222 nm is Showing Significant Potential to Safely and Efficiently Inactivate Airborne Pathogens in Occupied Indoor Locations

Brenner, D. J.

2023
Experimental study of the disinfection performance of a 222-nm Far-UVC upper-room system on airborne microorganisms in a full-scale chamber

Wang et al.

2023
Air and Surface Treatment Using Germicidal Ultraviolet-C (GUV)

Claus & Clark

2022
Far-UVC (222 nm) efficiently inactivates an airborne pathogen in a room-sized chamber.

Eadie et al.

2022
Evaluation of UVC Excimer Lamp (222 nm) Efficacy for Coronavirus Inactivation in an Animal Model

Tucciarone et al.

THE SCIENCE OF FAR-UVC

Far-UVC Inactivates Pathogens on Surfaces

2025

Evaluation of a far ultraviolet-C device for decontamination of portable equipment in clinical areas

Memic et al.

2025
A ceiling-mounted far-ultraviolet-C light technology reduces methicillin-resistant Staphylococcus aureus contamination on surfaces in a simulated operating room

Memic et al.

2024
SARS-CoV-2 inactivation on hard non-porous airplane cabin material surfaces was limited after exposure to far UV-C (222 nm) radiation

Wilson et al.

2024
Evaluation of an automated far ultraviolet-C light technology for decontamination of surfaces and aerosolized viruses in bathrooms

Kaple et al.

2024
Susceptibility of extremophiles to far-UVC light for bioburden reduction in spacecraft assembly facilities

Petersen et al.

2024
Clinical application of 222 nm wavelength ultraviolet C irradiation on SARS CoV-2 contaminated environments

Su et al.

2024
Microbial contamination of spittoons and germicidal effect of irradiation with krypton chloride excimer lamps (Far UV-C 222 nm)

Tanimoto et al.

2023
Air and Surface Treatment Using Germicidal Ultraviolet-C (GUV)

Claus & Clark

2023
UV Inactivation of Common Pathogens and Surrogates Under 222 nm Irradiation from KrCl* Excimer Lamps

Ma et al.

2023
An excimer lamp to provide far-ultraviolet C irradiation for dining-table disinfection

Lv et al.

2023
Antimicrobial Activity of Filtered Far-UVC Light (222 nm) against Different Pathogens

Lorenzo-Leal et al.

2021
Effectiveness of 222-nm ultraviolet light on disinfecting SARS-CoV-2 surface contamination

Kitagawa et al.

THE SCIENCE OF FAR-UVC

Demonstrated Safety for Human Exposure

2025
Chronic Far-UVC (222nm) Light Exposure of SKH-1 Hairless Mice Does Not Cause Detectable Eye Pathology or Visual Deficits

Arden et al.

2025
Far-ultraviolet-C exposure in patients with photosensitivity disorders

Christou et al.

2025
Do far ultraviolet-C light technologies increase ozone concentrations in healthcare facility patient rooms?

Memic et al.

2025
Wavelength-dependent DNA damage induced by single wavelengths of UV-C radiation (215 to 255 nm) in a human cornea model

Buonanno et al.

2024
Ocular safety of 222-nm far-ultraviolet-c full-room germicidal irradiation: A 36-month clinical observation

Sugihara et al.

2023
Far UV-C radiation: An emerging tool for pandemic control

Blatchley et al.

2023
222-nm UVC light as a skin-safe solution to antimicrobial resistance in acute hospital settings with a particular focus on methicillin-resistant Staphylococcus aureus and surgical site infections: a review

Panzures et al.

2023
Ocular and Facial Far-UVC Doses from Ceiling-Mounted 222 nm Far-UVC Fixtures

Duncan et al.

2023
No Evidence of Induced Skin Cancer or Other Skin Abnormalities after Long-Term (66 week) Chronic Exposure to 222-nm Far-UVC Radiation

Welch et al.

2023
Validated computational modeling to evaluate spatial inactivation of airborne pathogens by Far-UVC irradiation

Peñaloza et al.

2023
Model Evaluation of Secondary Chemistry due to Disinfection of Indoor Air with Germicidal Ultraviolet Lamps

Zhe et al.

2023
Far-UVC Light at 222 nm is Showing Significant Potential to Safely and Efficiently Inactivate Airborne Pathogens in Occupied Indoor Locations

Brenner, D. J.

2022
Wavelength-dependent DNA Photodamage in a 3-D human Skin Model over the Far-UVC and Germicidal UVC Wavelength Ranges from 215 to 255 nm

Welch et al.

2022
Wavelength-dependent DNA Photodamage in a 3-D human Skin Model over the Far-UVC and Germicidal UVC Wavelength Ranges from 215 to 255 nm

Welch et al.

2022
Safety of 222 nm UVC Irradiation to the Surgical Site in a Rabbit Model

Fukui et al.

2021
Disinfection capabilities of a 222 nm wavelength ultraviolet lighting device: a pilot study

Goh et al.

THE SCIENCE OF FAR-UVC

Healthcare & Real-World Outcomes

2025
Evaluation of a far ultraviolet-C device for decontamination of portable equipment in clinical areas

Memic et al.

2025
A ceiling-mounted far-ultraviolet-C light technology reduces methicillin-resistant Staphylococcus aureus contamination on surfaces in a simulated operating room

Memic et al.

2025
Do far ultraviolet-C light technologies increase ozone concentrations in healthcare facility patient rooms?

Memic et al.

2025
Far UV Exposure (UV222) Decreases Immune-Based Recognition of Common Airborne Allergens

Eidem et al.

2025
Chronic Far-UVC (222nm) Light Exposure of SKH-1 Hairless Mice Does Not Cause Detectable Eye Pathology or Visual Deficits

Arden et al.

2025
Far-ultraviolet-C exposure in patients with photosensitivity disorders

Christou et al.

2024
Evaluation of an automated far ultraviolet-C light technology for decontamination of surfaces and aerosolized viruses in bathrooms

Kaple et al.

2024
SARS-CoV-2 inactivation on hard non-porous airplane cabin material surfaces was limited after exposure to far UV-C (222 nm) radiation

Wilson et al.

2024
Ocular safety of 222-nm far-ultraviolet-c full-room germicidal irradiation: A 36-month clinical observation

Sugihara et al.

2024
Susceptibility of extremophiles to far-UVC light for bioburden reduction in spacecraft assembly facilities

Petersen et al.

2024
Efficacy of a far-ultraviolet-C light technology for continuous decontamination of air and surfaces

Memic et al.

2024
Clinical application of 222 nm wavelength ultraviolet C irradiation on SARS CoV-2 contaminated environments

Su et al.

2024
Microbial contamination of spittoons and germicidal effect of irradiation with krypton chloride excimer lamps (Far UV-C 222 nm)

Tanimoto et al.

2024
222 nm far‑UVC light markedly reduces the level of infectious airborne virus in an occupied room

Buonanno et al.

2023
Indoor Air Quality Implications of Germicidal 222 nm Light

Barber et al.

2023
Antimicrobial Activity of Filtered Far-UVC Light (222 nm) against Different Pathogens

Lorenzo-Leal et al.

2023
222-nm UVC light as a skin-safe solution to antimicrobial resistance in acute hospital settings with a particular focus on methicillin-resistant Staphylococcus aureus and surgical site infections: a review

Panzures et al.

2023
An excimer lamp to provide far-ultraviolet C irradiation for dining-table disinfection

Lv et al.

2023
Ocular and Facial Far-UVC Doses from Ceiling-Mounted 222 nm Far-UVC Fixtures

Duncan et al.

2023
Far-UVC: Technology Update with an Untapped Potential to Mitigate Airborne Infections

Bueno de Mesquita et al.

2023
Public acceptance of the use of Far-UVC for virus inactivation: Challenges and opportunities

Ross et al.

2023
Far UV-C radiation: An emerging tool for pandemic control

Blatchley et al.

2023
Experimental study of the disinfection performance of a 222-nm Far-UVC upper-room system on airborne microorganisms in a full-scale chamber

Wang et al.

2023
Evaluating the Impact of 222 nm Far-UVC Radiation on the Aesthetic and Mechanical Properties of Materials Used in Public Bus Interiors

Drungilas et al.

2023
Model Evaluation of Secondary Chemistry due to Disinfection of Indoor Air with Germicidal Ultraviolet Lamps

Zhe et al.

2023
No Evidence of Induced Skin Cancer or Other Skin Abnormalities after Long-Term (66 week) Chronic Exposure to 222-nm Far-UVC Radiation

Welch et al.

2022
Safety of 222 nm UVC Irradiation to the Surgical Site in a Rabbit Model

Fukui et al.

2022
Evaluation of UVC Excimer Lamp (222 nm) Efficacy for Coronavirus Inactivation in an Animal Model

Tucciarone et al.

2022
Far-UVC (222 nm) efficiently inactivates an airborne pathogen in a room-sized chamber.

Eadie et al.

2021
Effectiveness of 222-nm ultraviolet light on disinfecting SARS-CoV-2 surface contamination

Kitagawa et al.

2021
Disinfection capabilities of a 222 nm wavelength ultraviolet lighting device: a pilot study

Goh et al.