Earth & Planets Laboratory

The Earth and Planetary Science Interdisciplinary Internships (EPIIC) program at the Carnegie Science Earth and Planets Laboratory (EPL) offers a unique opportunity for undergraduate students to gain hands-on experience in the fields of Earth, planetary, and astronomical sciences. We are particularly interested in applications from freshman and sophomore students attending institutions with limited local research opportunities (e.g., community and liberal arts colleges) and/or those who have not conducted research before.

During the 10-week program (June 1 - August 7, 2026), interns will work under the supervision of experienced researchers in the fields of astronomy, astrobiology, biogeochemistry, cosmochemistry, data science, experimental geochemistry/petrology, geophysics, isotope geochemistry, high-pressure mineral physics, mineralogy, organic geochemistry, and petrology. 

Interns will work with their Carnegie mentor on an assigned research project with the ultimate goal of developing an original research finding that is suitable for presentation at a national scientific meeting during the following academic year. Interns are full members of their mentors’ research groups, participate in regular group meetings, and attend weekly seminars and social events at the EPL aimed at establishing a collegial cohort. EPIIC’s intensity and training will prepare its participants for graduate student life.

Program Dates: June 1 - August 7, 2026

Applications Due: January 30, 2026 
We expect to make a first round of offers on March 6th, with an acceptance deadline of March 15th. If there's a second round of offers, they'll be sent out shortly after March 15th. We’ll notify all applicants when the positions are filled. The selection process should be completed by the end of March

Move In: May 31, 2026

Move Out: August 8, 2026

• This is a paid, full-time position with a stipend of $6000 dispersed at the beginning and the  middle of the program. 

• The cost of housing (but not meals) at the nearby American University is included in the program and does not come out of the stipend. Move-in/out days from the AU dorms will be May 31st and August 8th.

• Interns will also have access to the Earth and Planets Laboratory facilities including the library and research facilities necessary for carrying out their research.
   
• Interns will be provided with necessary computing resources (e.g., a laptop, project-specific software).
   
• Interns can receive support for relocation expenses up to $300. 
   
• Funds are available for the interns to attend and present their work at professional meetings following the conclusion of the internship and in consultation with their research mentor(s).

Mentors: Anirudh Prabhu, Michael L. Wong
Subdisciplines: Astronomy, Planetary Science, Data Science

How do planetary systems form and evolve? What new exoplanets are waiting to be discovered? In this project, we will apply machine learning methods to large exoplanet datasets to identify patterns that reveal trends in planetary system architecture, predict the presence of undiscovered planets, and guide future astronomical observations. The intern will learn to curate data from the NASA Exoplanet Archive and utilize machine learning methods to explore exoplanet data. The intern will also develop a deeper understanding of state-of-the-art exoplanetary science, including exoplanet demographics, characterization, and formation. As a result, the intern will gain experience in all aspects of planetary informatics, including data resource management, data visualization, data analysis, the interpretation of machine learning models, and the communication of key scientific findings.

Recommended prerequisites: Experience in coding, preferably in R.

Mentor: Jennifer Kasbohm
Subdisciplines: Geochronology, Geology, Geochemistry

To better quantify timescales of how Earth will respond to anthropogenic climate change, we must investigate the timing and rates of environmental and ecosystem perturbations in the past. This internship will expose you to multiple aspects of geochronology, the science of applying ages to the rock record. You will gain laboratory experience in pursuit of quantifying the timing and climatic effect of volcanism around the Caribbean during the Cretaceous. You will also perform a literature-based investigation of hiatuses in the Early Miocene deep-sea sedimentary record to inform our understanding of the timing of changes in oceanographic processes across an interval of biotic transition. By the end of this internship, you will gain experience in mineral separation techniques, extracting information from scientific papers, analyzing and visualizing scientific data, talking with scientific collaborators, and the ways we make sure records from across the Earth system are temporally “on the same page.” 

Recommended prerequisites: The student is expected to have completed at least two geology courses prior to the start of the internship, with coursework in Earth system science, physical geology, stratigraphy/sedimentology, and/or oceanography preferred. No prior laboratory or research experience is required.

Mentors: Kevin Wong, Cian Wilson
Subdisciplines: Geodynamics, Geochemistry, Data Science

Global tectonics controls where elements are distributed on and within the Earth. Computational tools can allow geoscientists to relate Earth’s tectonic cycle to the evolution of long-term surface chemistry, with important implications for million-year-scale climate changes and the distribution of vital materials for economic geology. In this project, the student will use the GPlates software to relate global tectonics to literature-compiled Earth surface geochemistry datasets. There is scope for research paths tailored to the student’s interests, including tectonic controls on a) deep geochemical cycles (e.g., that of boron), and b) arc volcano geochemistry. During this project, the student will gain valuable skills in scientific computing using the Python coding language, data visualization, collaborative working, and the manipulation, processing, and analysis of large geoscientific datasets.

Recommended prerequisites: Basic knowledge of geology and Python coding is beneficial, but not necessary.

Mentors: Tim Strobel 
Subdisciplines: Materials, Chemistry, Physics

Materials underpin modern technology, from energy systems to information processing and sustainable infrastructure. However, many potentially useful compounds and structures remain inaccessible through conventional synthesis routes due to thermodynamic or kinetic limitations. High-pressure techniques offer a powerful route to overcome these barriers by stabilizing novel atomic arrangements, bonding motifs, and electronic states. By combining compression experiments with advanced characterization methods, this project seeks to discover and recover new materials formed under extreme pressure. The resulting materials—ranging from superhard solids to exotic superconductors—promise to expand our understanding of chemical bonding and to enable next-generation functional materials once thought unattainable.

Recommended prerequisites: Introductory knowledge of chemistry, physics, and materials science. 

Mentor: Alexander Goncharov
Subdiscipline: Mineral Physics

Understanding the thermal history and dynamics of Earth’s interior is one of the central challenges in geophysics. Processes such as planetary accretion, chemical differentiation, the long-term evolution of mantle and core temperatures, and the generation of Earth’s magnetic field all depend critically on how heat is transported through deep Earth materials.

Thermal conductivity in the mantle and core varies strongly with pressure, temperature, crystal structure, chemical composition, and electronic or spin state. This project will explore these dependencies through direct measurements of thermal conductivity in key Earth-forming minerals and metallic alloys subjected to extreme conditions using laser-heated diamond anvil cell techniques. Experiments will replicate pressures and temperatures characteristic of the lower mantle and core, enabling quantitative constraints on heat flow in Earth’s interior and its temporal evolution. 

Students participating in this project will gain experience with high-pressure experimental methods, optical and spectroscopic diagnostics, and analysis of heat transport in condensed matter systems.

Recommended prerequisites: Background in optics and spectroscopy is strongly recommended.