Dr. Rohit Bhartia Profile

Dr. Rohit Bhartia

at Jet Propulsion Lab

SPIE Involvement:

Author

Publications (11)

PROCEEDINGS ARTICLE | May 16, 2018

Rapid optical detection and classification of microbes in suspicious powders

Proc. SPIE. 10629, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing XIX

KEYWORDS: Proteins, Principal component analysis, Deep ultraviolet, Sensors, Luminescence, Raman spectroscopy, Microorganisms, Yeast, Biological research, Bacteria

Read Abstract

PROCEEDINGS ARTICLE | May 29, 2014

Improved sensing using simultaneous deep-UV Raman and fluorescence detection-II

Proc. SPIE. 9073, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing XV

KEYWORDS: Target detection, Deep ultraviolet, Sensors, Spectroscopy, Luminescence, Fluorescence spectroscopy, Raman spectroscopy, Spectral resolution, Explosives, Urea

Read Abstract

PROCEEDINGS ARTICLE | May 25, 2012

Noncontact, reagentless, nondestructive, detection of organics, biosignatures, and water

Proc. SPIE. 8385, Sensors and Systems for Space Applications V

KEYWORDS: Optical filters, Minerals, Deep ultraviolet, Spectroscopy, Luminescence, Fluorescence spectroscopy, Raman spectroscopy, Microorganisms, Chemical analysis, Natural surfaces

Read Abstract

PROCEEDINGS ARTICLE | May 11, 2012

Improved sensing using simultaneous deep UV Raman and fluorescence detection

Proc. SPIE. 8358, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing XIII

KEYWORDS: Target detection, Principal component analysis, Statistical analysis, Deep ultraviolet, Sensors, Luminescence, Phosphorescence, Raman spectroscopy, Explosives, Chemometrics

Read Abstract

PROCEEDINGS ARTICLE | May 9, 2012

Wearable real-time direct reading naphthalene and VOC personal exposure monitor

Proc. SPIE. 8366, Advanced Environmental, Chemical, and Biological Sensing Technologies IX

KEYWORDS: Defense and security, Safety, Principal component analysis, Solar concentrators, Deep ultraviolet, Sensors, Luminescence, Time metrology, Chemical analysis, Chemometrics

Read Abstract

PROCEEDINGS ARTICLE | May 8, 2009

Performance status of a small robot-mounted or hand-held, solar-blind, standoff chemical, biological, and explosives (CBE) sensor

Proc. SPIE. 7304, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing X

KEYWORDS: Target detection, Standoff detection, Deep ultraviolet, Sensors, Luminescence, Control systems, Robots, Raman spectroscopy, Explosives, Bacteria

Read Abstract

PROCEEDINGS ARTICLE | April 21, 2008

A new miniature hand-held solar-blind reagentless standoff chemical, biological, and explosives (CBE) sensor

Proc. SPIE. 6954, Chemical, Biological, Radiological, Nuclear, and Explosives (CBRNE) Sensing IX

KEYWORDS: Deep ultraviolet, Sensors, Ultraviolet radiation, Luminescence, Robots, Raman spectroscopy, Explosives, Chemometrics, Improvised explosive devices, Pulsed laser operation

Read Abstract

Improvised explosive devices (IEDs), vehicle-borne improvised explosive devices (VBIEDs), and suicide bombers are a major threat to many countries and their citizenry. The ability to detect trace levels of these threats with a miniature, hand-held, reagentless, standoff sensor represents a major improvement in the state of the art of CBE surface sensors. Photon Systems, Inc., in collaboration with Jet Propulsion Laboratory, recently demonstrated a new technology hand-held sensor for reagentless, close-range, standoff detection and identification of trace levels CBE materials on surfaces. This targeted ultraviolet CBE (TUCBE) sensor is the result of an Army Phase I STTR program. The resulting 5lb, 5W, flashlight-sized sensor can discriminate CBE from background materials using a combination of deep UV excited resonance Raman (RR) and laser induced native fluorescence (LINF) emissions resulting from excitation by a new technology deep UV laser. Detection and identification is accomplished in less than 1ms. Standoff excitation of suspicious packages, vehicles, persons, and other objects that may contain hazardous materials is accomplished using wavelengths below 250nm where Raman and native fluorescence emissions occupy distinctly different wavelength regions. This enables simultaneous detection of RR and LINF emissions with no interferences. The sensor employs fused RR/LINF chemometric methods to extract the identity of targeted materials from background clutter. Photon Systems has demonstrated detection and identification of 100ng/cm2 of explosives materials at a distance of 1 meter using a sensor with 3.8 cm optical aperture. Expansion of the optical aperture to 38 cm in a lantern-sized sensor will enable similar detection and identification of CBE materials at standoff distances of 10 meters. As a result of excitation and detection in the deep UV and the use of a gated detection system, the sensor is solar blind and can operate in full daylight conditions.

PROCEEDINGS ARTICLE | October 25, 2006

Water and surface contamination monitoring using deep UV laser induced native fluorescence and Raman spectroscopy

Proc. SPIE. 6378, Chemical and Biological Sensors for Industrial and Environmental Monitoring II

KEYWORDS: Principal component analysis, Contamination, Deep ultraviolet, Sensors, Ultraviolet radiation, Particles, Luminescence, Control systems, Raman spectroscopy, Industrial chemicals

Read Abstract

PROCEEDINGS ARTICLE | October 13, 2006

A self-contained native fluorescence detector for measurement of organic molecules and chemicals of life

Proc. SPIE. 6398, Optically Based Biological and Chemical Detection for Defence III

KEYWORDS: Optical filters, Deep ultraviolet, Sensors, Ultraviolet radiation, Luminescence, Molecules, Fluorescence spectroscopy, Laser development, Charge-coupled devices, Chemical analysis

Read Abstract

PROCEEDINGS ARTICLE | May 19, 2006

Biochemical detection and identification false alarm rate dependence on wavelength using laser induced native fluorescence

Proc. SPIE. 6218, Chemical and Biological Sensing VII

KEYWORDS: Optical filters, Principal component analysis, Optical spheres, Deep ultraviolet, Sensors, Ultraviolet radiation, Luminescence, Molecules, Raman spectroscopy, Raman scattering

Read Abstract

PROCEEDINGS ARTICLE | November 10, 2005

Status of miniature integrated UV resonance fluorescence and Raman sensors for detection and identification of biochemical warfare agents

Proc. SPIE. 5994, Chemical and Biological Sensors for Industrial and Environmental Security

KEYWORDS: Deep ultraviolet, Scattering, Sensors, Ultraviolet radiation, Luminescence, Molecules, Organisms, Raman spectroscopy, Microorganisms, Raman scattering

Read Abstract

Showing 5 of 11 publications

View contact details

UPDATE YOUR PROFILE

Is this your profile? Update it now.

Sign into your SPIE.org account

Don’t have a profile and want one?

Create an account on SPIE.org

Keywords/Phrases

Search In:

Publication Years