Malvern Panalytical’s ASD TerraSpec® Halo mineral identifier is being used as part of today’s space race to return astronauts to the Moon, Mars, and beyond! The full-range (350-2500nm) portable spectrometer was recently selected and used in multiple research projects aimed at expanding U.S. efforts in planetary exploration.

Project PoSSUM

Project PoSSUM citizen-science course members 

Dr. Ulyana “Uly” Horodyskyj was involved in co-teaching an adult continuing education program, “Planetary Field Geology and EVA Tool Development.” The course was held by Project PoSSUM (Polar Suborbital Science in the Upper Mesosphere), a 501(c)(3) astronautics research and education program studying our upper-atmosphere and its role in our changing global climate.

Dr. Ulyana Horodyskyj demonstrates use of the ASD TerraSpec Halo 

The Project PoSSUM program utilizes scientific procedures to drive technology maturation, and this course taught surface geology to twelve PoSSUM citizen-scientists who came from all over the world to learn procedures and develop tools that will influence the design of EVA space suits. Class participants had the assignment of coming up with a concept of a field tool that they were to design and have 3D printed or otherwise assembled; additionally, standard geologic tools such as rock hammers, rock kits and hardness tests were involved. It was Uly’s suggestion to incorporate and include the use of the ASD TerraSpec Halo VIS-NIR-SWIR (visible – near-infrared – short-wave infrared) spectrometer in the teaching of the course, as the instrument can measure the spectrum of rocks and identify alteration minerals, which are key for when scientists and astronauts eventually do get back to the Moon and/or go to Mars, and are looking for traces of water.

With NASA ramping up to go back to the Moon, to Mars and beyond, there is a need for people to be well versed in planetary field geology. Use of the TerraSpec Halo to identify alteration minerals is a great way to do analog testing on Earth, before committing to future missions to the Moon and Mars. – Uly Horodyskyj

Project PoSSUM citizen-scientists take turns using the ASD TerraSpec Halo in the field 

The course culminated in a one-week capstone field experience at the San Francisco Volcanic Field in Northern Arizona; this location was selected as areas of the volcanic field have been used by NASA for testing techniques for exploration in a simulated extraterrestrial terrain environment. The ASD TerraSpec Halo instrument was provided on behalf of Malvern Panalytical as part paid rental / part sponsorship.

The ASD TerraSpec Halo is like a tool out of Star Trek. The students – some college, but the majority post-docs and beyond – had some experience with mass spectrometers and spectroradiometers, but nothing like the use of this ASD mineral analyzer before. The ease of use of the instrument, and the software, was amazing. The battery life of the spectrometer was incredible. In my teaching, I was able to point out absorption features to the students, as the TerraSpec Halo shows you not just minerals, but also the measured spectrum; I was not familiar with some of the alteration minerals that came up on the instrument’s screen, so the students and I would look this up together, which proved to be a good learning opportunity for myself as well.” – Uly Horodyskyj


A NASA-sponsored research project, the GeoHeuristic Operational Strategies Test (GHOST), including CU Boulder’s Department of Geological Sciences Associate Professor Dr. Brian Hynek, selected the VIS-NIR-SWIR ASD TerraSpec Halo to maximize the speed, efficiency and scientific return of Mars rover sample collection. The instrument was sponsored and provided on behalf of Malvern Panalytical. The project used the spectrometer to simulate the function of the Mars Science Laboratory (MSL) ChemCam and Mars 2020 rover SuperCam.

Rather than using mechanical rovers or replica Mars instrumentation, GHOST utilizes human “rovers” and off-the-shelf field portable instruments to isolate the variable of the scientific decision-making process. This eliminates the need for mission-specific instrumentation, communication and data relays, or complex engineering requirements, while still providing the same basic information, such as mineralogy.

During the research project, the TerraSpec Halo allowed for rapid data acquisition of in-situ outcrops, similar to the data gathered by Mars rovers, and allowed the rover operations team to rapidly traverse the field site near Salt Lake City, Utah, maximizing the number of data points gathered.

Full range spectroscopy provides a wealth of compositional information and is a valuable tool in planetary exploration. The use of the ASD TerraSpec Halo, and field-portable VIS-NIR-SWIR, as an analog for rover instrumentation was sufficient for science team operations; the teams were able to efficiently conduct their site investigation and analysis of operational methods using terrestrial analog instrumentation. – Brian Hynek

Why is this research important? 

Mineralogical variations are significant because geochemical differences contain clues regarding whether a geologic environment was habitable or capable of preserving evidence of prior life. Without in-situ VIS-NIR-SWIR data, there could be missed critical information for scientific missions and interpretations. The selection of the ASD TerraSpec Halo for these research projects to measure compositional information represent some of the initial steps towards advancing scientific study and exploration of Mars.

The best we can do, at the moment, is study extreme environments on Earth that are going to be the most similar to Mars. Places like Iceland, the Atacama Desert in Chile, these volcanic fields in Arizona… these are excellent analogs where you cannot only test the equipment but also look at these markers of weathering and presence of water. If we find something similar on Mars, we know what the Earth equivalent is – we can match it and we know exactly what that geochemical history is.” – Uly Horodyskyj


Written by: Malvern Panalytical – (

NEW Copper CRMs

ARMI MBH excited to add five new copper CRMs to their product portfolio. Copper can be alloyed with a wide range of elements enabling highly specific functions and applications. The large compositional range of copper alloys means that high-quality, matrix-matched reference materials are needed for proper analysis of each alloy.

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In addition to their structural properties, CDA 510, CDA 655, and CDA 955 are EPA-registered as antimicrobial alloys. More information on the antimicrobial properties of copper, including a complete list of EPA-registered alloys, can be found at the EPA Antimicrobial Stewardship Website for Copper Alloys.

CDA 510 (IARM-Cu510-18) is a phosphor bronze, which is commonly used for fasteners and spring components. It is also excellent for soldering and brazing applications and has high conductivity, which lends itself well to electrical connectors and other electronic usages. CDA 510 has certified values for the grade-specified elements Cu, Pb, Sn, Zn, and P and a reference value for Fe. Additionally, certified values are provided for Ag, C, Ni, and O, and reference values are given for 32 more elements.

A high silicon bronze, CDA 655 (IARM-Cu655-18) is widely appreciated for its aesthetic and its antimicrobial properties in architectural and decorative applications. Its high resistance to corrosion means that it is often used for fasteners, piston rings, and other hardware in marine applications. In addition to the specified elements, Cu, Pb, Fe, Zn, Mn, Si, and Ni, this CRM is also certified for Al and Sn, and has reference data for 21 more elements.

CDA 955 (IARM-Cu955-18) is a nickel aluminum bronze alloy. In addition to being another EPA-registered alloy for microbe resistance, it is one of the strongest non-ferrous alloys, thanks to its high Ni content. The high hardness rating and good corrosion resistance makes this a common choice for marine and aircraft parts, in addition to high wear and high impact applications. This CRM has certified values of the grade-specified components Cu, Fe, Al, Ni, and Mn, as well as Ag, Co, Cr, P, Pb, Si, Sn, and Zn. Reference values are provided for an additional 18 elements.

A tin bronze alloy also known as Navy G is CDA 903 (IARM-Cu903-18). CDA 903 is a type of gear bronze, a family of bronze alloys used for wear resistance in high velocity situations. Gear bronzes compose most of the non-ferrous alloys for these applications. As the name implies, Navy G is widely used in marine environments because of its strong corrosion resistance. The new CRM has certified values for alloy-specified elements, Cu, Sn, Pb, Zn, Ni, Co, Fe, and Pb. Good reference values are given for the elements Sb, S, Al, and Si, which have maximum values specified. A certified value is also given for O, and reference values for 18 other elements.

Lastly, we are adding CDA 360 (IARM-Cu360-18) to our portfolio, which is a free cutting brass. Thanks to its high Pb content, CDA 360 is an excellent machining alloy with a 100% machinability rating and it is used as a comparison for the machinability of all other alloys. It is an excellent choice for use in applications that require drilling, turning, milling and other high-speed machining processes.

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The grade specifications for CDA 360 Grade include values for Cu, Fe, Pb, and Zn. Our CRM has certified values for the four specified elements, as well as Ag, Al, As, Bi, C, Cd, Co, Cr, Mn, Ni, P, Sb, Si, and Sn. Reference values are given for 14 more elements.

If you have any questions about these new products or other products, please reach out to our experts for help.

Written by: James Haddad PhD  – Posted by: ARMI MBH (