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JILA

JILA (formerly the Joint Institute for Laboratory Astrophysics), is a collaborative research institute between the National Institute of Standards and Technology (NIST) and the , dedicated to pioneering advancements in physics since its founding in 1962. Originally established to bridge laboratory experiments with astrophysical phenomena, JILA has evolved into a world-leading center for cutting-edge research in and technology, atomic, molecular, and optical physics, as well as . Located on the campus, JILA conducts fundamental studies on topics ranging from the evolution of stars and planet formation to the dynamics of black holes, while also developing precision measurement tools like atomic clocks and technologies that underpin modern scientific and technological progress. The institute's collaborative model fosters interdisciplinary work among a multidisciplinary team of scientists, including fellows from NIST and faculty from CU , leading to groundbreaking discoveries such as Bose-Einstein condensates and optical frequency combs. JILA's impact is underscored by its association with three Nobel Prize laureates: Eric Cornell and , who shared the 2001 Physics Nobel for achieving Bose-Einstein condensation in dilute gases of atoms, and Jan Hall, who received the 2005 Physics Nobel for contributions to laser-based precision spectroscopy, including the optical technique. These achievements highlight JILA's role in transforming theoretical concepts into practical innovations that advance fields from to precision timekeeping.

History

Founding and Early Years

JILA was established on April 13, 1962, as a collaborative venture between the National Bureau of Standards (now the National Institute of Standards and Technology, or NIST) and the . This joint institute, initially named the Joint Institute for Laboratory Astrophysics, represented one of the earliest formal partnerships between a federal research agency and a university to advance interdisciplinary physics. The idea for the institute originated in 1958 during discussions in between Lewis M. Branscomb, a physicist at the National Bureau of Standards, and Richard N. Thomas, a theoretical , with formal approval secured in Washington and implementation in . The institute's founding mission centered on pioneering laboratory astrophysics, an emerging field that integrated experiments with astrophysical observations to study processes in stellar atmospheres and other cosmic environments. This approach aimed to simulate astrophysical conditions—such as non-equilibrium gaseous systems and optical collision processes—in controlled laboratory settings, addressing gaps in understanding that traditional astronomical observations alone could not resolve. Early research emphasized atomic and molecular interactions relevant to stars, marking a novel shift toward experimental replication of celestial phenomena. Key early figures included Branscomb, who served as the inaugural chair, and , who co-founded the effort and focused on theoretical aspects. Experimental work featured involvement from in initial projects, notably the 1961–1962 giant interferometer experiment conducted in the Poorman Relief mine near to minimize vibrations and noise. This setup tested interferometric techniques for precision measurements, laying groundwork for astrophysical simulations. Other contributors, such as Jan Hall and Peter Bender, advanced related interferometer studies in the early 1960s. Organizationally, JILA operated without a formal director in its early years, instead governed by a self-appointed group of senior fellows who chaired rotating committees. A 1962 memorandum of understanding between the National Bureau of Standards and the University of Colorado Boulder defined the partnership, with staffing drawn from both institutions and funding supported by the agencies plus grants like $500,000 annually from the Advanced Research Projects Agency (in 1962 dollars). This structure fostered a collaborative environment dedicated to laboratory-based astrophysics research.

Expansion and Milestones

Over time, JILA retained its original name, the Joint Institute for Laboratory , even as its research scope broadened significantly beyond starting in the 1970s. In 1976, an addendum to the institute's founding formally expanded its mandate to encompass physics, precision measurements, and , reflecting the growing interdisciplinary nature of its work. This evolution culminated in 1994, when JILA Fellows voted to discontinue the full formal title, effective in 1995, adopting simply "JILA" as its non-acronymic name to better align with its diversified . By the 1980s and 1990s, JILA's research breadth further incorporated quantum physics, advanced laser technologies, and precision measurement techniques, driven by collaborative advancements in atomic and . This period marked a shift from its origins toward a wider array of physical sciences, with fellows increasingly exploring ultracold matter and optical innovations. Institutional developments during this era included deeper integration with the Boulder's Physics and departments, where CU faculty served as JILA Fellows alongside NIST scientists, fostering joint appointments and shared resources. Enhanced NIST collaboration was evident in initiatives like the 2005 partnership agreement, which emphasized creative interdisciplinary research among fellows from both institutions. Key milestones underscored JILA's growth and recognition. In 1988, celebrated its 25th with of the S-wing, providing a 40 percent increase in and office space to accommodate over 200 personnel. The 50th in 2012 featured the of the commemorative book JILA: The First 50 Years, of the X-wing expansion adding 56,065 square feet of advanced facilities funded jointly by NIST ($22.5 million) and CU ($10.2 million), and designation as an Physics for its enduring contributions to precision . In 2022, JILA marked its 60th with reflections on its evolution from astrophysics to a hub for quantum and frontiers, highlighting sustained CU -NIST synergy.

Organization and Facilities

Governance and Structure

JILA operates as a joint institute between the National Institute of Standards and Technology (NIST), a federal agency emphasizing measurement standards and technology, and the (CU Boulder), which prioritizes academic education and research training. This dual affiliation enables a collaborative federal-academic model that integrates government-supported precision science with university-led and . The governance of JILA is led by a Chair, currently John Bohn, who oversees daily operations and strategic direction, supported by a Vice Chair, Ralph Jimenez, acting as NIST Quantum Physics Division Chief. Core decision-making involves the JILA Fellows, a group of senior scientists from both NIST and CU , who guide research priorities and . An Executive Committee, comprising Fellows such as Adam Kaufman, Mitchell C. Begelman, and Heather Lewandowski, handles leadership functions, while advisory input from both partner institutions ensures alignment with federal standards and academic goals. JILA's staff comprises approximately 380 personnel, as of 2025, blending NIST scientists as permanent federal employees focused on applied with CU Boulder faculty holding tenured academic positions dedicated to theoretical and experimental advancements. This mix is supplemented by associates, postdoctoral researchers, graduate and undergraduate students, and administrative support, fostering an interdisciplinary environment. Funding for JILA primarily derives from NIST internal resources, (NSF) grants—such as the $25 million award to the JILA Physics Frontier Center—and U.S. (DOE) support for specific quantum and materials projects, reinforcing the institute's collaborative federal-academic framework.

Physical Facilities and Laboratories

JILA is primarily housed in the Duane Physics complex on the campus, where it operates as a collaborative facility jointly managed by the university and the National Institute of Standards and Technology (NIST). This integration allows seamless access to shared resources, including advanced experimental spaces tailored for precision physics research. In 2023, JILA received $2 million in federal funding for lab modernization, including upgrades to ventilation and temperature control systems, to address aging infrastructure. The JILA Keck Laboratory serves as a cornerstone of the institute's infrastructure, comprising the W.M. Keck Optical Metrology Laboratory and the JILA Micro and Nanofabrication Facility. The nanofabrication cleanroom, maintained at Class 1000/100 standards, equips researchers with tools such as Edwards 306 e-beam evaporators for thin-film deposition of materials like gold, silver, and titanium, as well as dual sputter chambers for metals and dielectrics. Adjacent to this, the metrology room houses specialized instruments including atomic force microscopes for surface characterization, J.A. Woollam VB-250 ellipsometers for measuring thin-film optical constants and thicknesses, and a Keyence digital microscope, with additional expertise in fiber optics metrology. Complementing these are the Instrument Shop and Electronics Shop, which provide essential custom fabrication and engineering support. The Instrument Shop utilizes CNC mills, lathes, and other precision machinery to construct complex components, including a dedicated cleaning room for compatibility and specialized techniques for working with ceramics, , and silica. The Electronics Shop focuses on designing analog and digital circuits, including low-noise and FPGA-based systems, supported by test equipment such as oscilloscopes and spectrum analyzers. In 2012, JILA expanded with the addition of a six-story X-wing, adding approximately 50,000 square feet of , , and collaboration optimized for high-precision measurements. This upgrade features basement built on 2-foot-thick concrete slabs to isolate vibrations and acoustics, enabling stable environments for sensitive optical and quantum experiments. Support infrastructure includes dedicated computing facilities, such as a general-purpose equipped with Windows and systems, printers, scanners, and a printer, alongside high-performance clusters for simulations in collaboration with the CU Research Computing Group. These resources, overseen by JILA's administrative structure, ensure robust operational efficiency across all laboratories.

Research Areas

Atomic, Molecular, and Optical Physics

JILA's research in atomic, molecular, and optical (AMO) physics centers on the fundamental interactions between light and matter at ultracold temperatures, where quantum effects dominate atomic and molecular behavior. Scientists at JILA employ both experimental and theoretical methods to investigate these systems, cooling atoms and molecules to temperatures just millionths of a degree above to enable precise control and observation of quantum phenomena. This work has pioneered techniques for producing and studying ultracold ensembles, laying the groundwork for advances in quantum simulation and precision spectroscopy. A landmark achievement in this field was the first production of a Bose-Einstein condensate (BEC) at JILA on June 5, 1995, by Eric Cornell, , and their team, using evaporative cooling of in a magnetic trap to achieve densities of approximately 10^15 atoms per cubic centimeter. This dilute gas BEC demonstrated macroscopic quantum coherence, confirming theoretical predictions from the 1920s and enabling studies of and collective excitations in atomic ensembles. The technique involved magneto-optical followed by forced , reducing the temperature to 170 nanokelvin and marking a new phase of matter that has since influenced ultracold gas research worldwide. Ongoing BEC studies at JILA explore properties like vortex formation and coherence in optical lattices, using and other alkali atoms. Light-matter interactions form another cornerstone of JILA's AMO efforts, particularly through where atoms couple strongly to optical fields. Researchers demonstrated continuous recoil-driven lasing using laser-cooled strontium-88 atoms in a high-finesse ring , achieving hours-long coherent emission by leveraging to maintain without external pumping. This setup, involving up to 10^5 atoms, pinned the cavity frequency and produced milliwatt-level output, advancing superradiant lasers for potential use in precision sensing. Complementary work includes atom- coupling in systems, where collective strong coupling enhances light-matter entanglement. Molecular spectroscopy at JILA leverages optical frequency combs for high-resolution analysis of complex molecules, revealing rovibrational structures at unprecedented detail. Using mid-infrared combs, teams have resolved the rovibrational quantum states of the lowest-energy infrared-active mode of C60 , assigning hundreds of transitions and enabling tests of anharmonic potentials in carbon cages. This approach, combined with buffer-gas cooling, achieves sensitivities down to 10^-9 absorption, facilitating studies of transient intermediates in chemical reactions. For ultracold molecules, JILA researchers develop association techniques from ultracold atoms, producing ground-state diatomic molecules like KRb at densities of 10^12 per cubic centimeter for investigating dynamics. Optical trapping and cooling techniques at JILA enable manipulation of individual atoms and molecules, using dipole traps and to isolate quantum systems. Single neutral atoms, such as , are trapped in focus spots with lifetimes exceeding seconds, allowing state-selective imaging and coherent control via Raman transitions. For molecules, magneto-optical trapping on quasi-cycling transitions cools species like CaF to 50 microkelvin, followed by transfer to optical lattices for studies of rotational coherence. These methods, rooted in slowing and evaporative cooling, support applications in chemical dynamics by isolating reaction pathways at the single-particle level.

Quantum Physics and Information

JILA's research in quantum physics and information emphasizes the manipulation of quantum states to enable advanced information processing and simulation. A key focus is on quantum entanglement, where researchers have demonstrated enhanced precision in atomic clocks by entangling ensembles of atoms to surpass the standard quantum limit, reducing measurement noise through correlated quantum states. Qubit manipulation techniques at JILA involve precise control of individual neutral atoms as qubits, leveraging cryogenic environments to achieve high-fidelity operations and long coherence times for quantum computing applications. In quantum simulation of materials, JILA scientists use ultracold atoms and molecules to emulate complex many-body systems, providing insights into condensed matter phenomena inaccessible to classical computation. Theoretical models developed by Ana Maria Rey and her group explore quantum many-body physics with ultracold polar molecules, predicting exotic phases such as quantum magnetism and enabling simulations of strongly interacting systems in optical lattices. These efforts build on atomic, molecular, and optical techniques to create programmable quantum simulators that reveal emergent behaviors in materials like superconductors. Optical lattice clocks serve as a for at JILA, with Jun Ye's team achieving record stability using strontium atoms confined in one-dimensional lattices, allowing precise engineering of collective quantum states for and . Complementary to this, optical tweezer arrays enable single-atom , with Cindy Regal's group demonstrating rapid loading efficiencies exceeding 90% for arrays of atoms, facilitating scalable arrays and entanglement distribution. For quantum networks, James Thompson's research on cold-atom advances repeater protocols, using atomic ensembles to generate and store entanglement over fiber-optic links, paving the way for distributed quantum information systems. As of 2025, JILA's initiatives in quantum sensing extend to biological and chemical applications, exemplified by Jun Ye's AB Nexus grant-funded project developing quantum optical breath tests to differentiate from viral infections and through detection. Participation in the DOE's Accelerator via the Q-SEnSE further emphasizes precision quantum sensors for molecular analysis in and .

Astrophysics and Cosmology

JILA's astrophysics and cosmology research integrates laboratory-based techniques with theoretical modeling to explore cosmic phenomena, emphasizing simulations that bridge atomic, molecular, and optical (AMO) physics with large-scale universe dynamics. Researchers at JILA investigate processes such as star and planet formation, the 14-billion-year evolution of the cosmos, and black hole behaviors, using computational frameworks to test hypotheses against astronomical observations. This approach leverages precision AMO tools to simulate conditions unattainable in direct observation, providing insights into fundamental astrophysical questions. In star and planet formation, JILA scientists model the assembly of planetary systems from protoplanetary disks surrounding young stars, focusing on how dust and gas coalesce into rocky and gaseous bodies. For instance, simulations demonstrate how gravitational instabilities and pebble accretion influence growth, determining the architecture of inner and outer in emerging systems. JILA Ann-Marie Madigan's group examines stellar and gas in galactic environments that affect formation, linking local processes to broader evolution. These models highlight the role of cosmic pebbles in initiating formation, offering a theoretical basis for observed diversities. Cosmic evolution studies at JILA trace the universe's development over its 14-billion-year history, employing theoretical methods to analyze galaxy surveys and extract parameters like and matter distribution. Andrew , a JILA Fellow, develops analytical tools for processing large observational datasets, revealing how initial fluctuations evolved into the cosmic web of . His work on formation pathways identifies superhighways of gas inflow that fueled early growth, connecting primordial conditions to modern structures. These efforts provide a framework for understanding the universe's expansion and large-scale . Contributions to black hole imaging represent a high-impact area, with JILA Fellow Jason Dexter playing a key role in the Event Horizon Telescope (EHT) collaboration. Dexter's radiative transfer models simulate the shadows and emissions around supermassive black holes, aiding the 2019 imaging of M87* and the 2022 capture of Sagittarius A*. His general relativistic magnetohydrodynamic (GRMHD) simulations predict the polarized light from accretion disks, enabling comparisons between theory and EHT observations to probe black hole spin and surrounding plasma. This work has earned recognition, including a share of the 2020 Breakthrough Prize in Fundamental Physics. Laboratory simulations of astrophysical plasmas and radiation at JILA emphasize computational modeling of magnetized flows and radiative processes, informed by AMO precision measurements. Mitchel Begelman's group conducts radiation GRMHD simulations to study hot accretion flows collapsing onto black holes, exploring plasma stability and energy transport in extreme environments. These models simulate conditions in galactic centers, testing theories of jet formation and disk evolution against X-ray binary observations. Theoretical modeling of galaxy dynamics complements this, with simulations of gas inflows and stellar collisions providing insights into supermassive black hole growth and feedback mechanisms.

Precision Measurement and Lasers

JILA's precision measurement efforts center on developing advanced technologies that enable unprecedented accuracy in probing physical phenomena. Researchers at JILA have pioneered optical and designs, including compact tabletop sources that generate coherent beams for high-resolution imaging and . These lasers, driven by pulses, facilitate the production of and soft light, allowing investigations into electron dynamics at timescales. In November 2025, the groups of Margaret Murnane and Henry Kapteyn reported significant progress toward realizing tabletop free-electron lasers, enabling compact sources of coherent for imaging and . A cornerstone of JILA's work involves frequency combs, which serve as precise optical rulers for measuring light frequencies. Developed through mode-locked lasers emitting pulses, these combs span hundreds of thousands of modes and underpin applications in by linking optical and microwave domains. JILA scientists have extended frequency combs into the regime, enabling direct of short-wavelength transitions with sub-hertz resolution. Atomic clock development at JILA represents a pinnacle of precision timekeeping, with innovations in optical clocks that thousands of atoms using visible waves. In Jun Ye's group, strontium-based optical clocks have achieved systematic uncertainties as low as 8×10⁻¹⁹, surpassing previous benchmarks by leveraging shallow lattices within in-vacuum cavities to minimize perturbations. These clocks utilize laser-cooled atoms in one-dimensional optical lattices, enabling simultaneous interrogation of large ensembles for enhanced stability. Laser stabilization techniques are critical to these advancements, with JILA employing methods like the Pound-Drever-Hall scheme to lock to high-finesse optical cavities, achieving millihertz-level linewidths. Building on legacy work, researchers have integrated acousto-optic modulators to suppress residual , tailoring stability for coordinating interactions in clocks and sensors. These techniques reduce to , supporting record-breaking references. In pulse generation, the groups of Margaret Murnane and Henry Kapteyn have generated isolated soft pulses as short as tens of s, driven by few-cycle lasers via high-harmonic generation. These pulses, reaching photon energies up to 180 , probe ultrafast motion in materials, revealing at extreme wavelengths. Quantum limits in , governed by the , constrain simultaneous measurements of like and , yet JILA's approaches push these boundaries through entanglement-enhanced sensing. For instance, spin-squeezed states in atomic clocks have demonstrated precision beyond the , achieving stabilities at the 10⁻¹⁷ level. These laser technologies find applications in redefining timekeeping standards, where optical clocks contribute to the potential redefinition of the second with accuracies rivaling tests at millimeter scales. In technology, coherent sources enable nanoscale imaging of charge transport and defects, while interfaces with nanoscience leverage probes for studying quantum in nanostructures.

Notable Achievements and Impact

Awards and Recognitions

JILA affiliates have been awarded Nobel Prizes in Physics, with three laureates underscoring the institute's leadership in precision measurement and quantum phenomena. In 2001, JILA Fellows Eric A. Cornell and Carl E. Wieman shared the Nobel Prize in Physics for their pioneering work on Bose-Einstein condensation in dilute atomic gases, conducted at JILA. In 2005, JILA Fellow John L. Hall received the Nobel Prize in Physics, jointly with Theodor W. Hänsch, for contributions to the development of laser-based precision spectroscopy, including the optical frequency comb technique, advanced through JILA's facilities. Other prestigious individual awards highlight JILA's impact in atomic, optical, and quantum physics. JILA Margaret Murnane was awarded a Fellowship in 2000 for her innovative research in and ultrafast . In 2013, JILA Ana Maria Rey received a Fellowship for her theoretical work bridging atomic, molecular, and . JILA Jun Ye earned the 2022 (announced in 2021) for the invention and development of the optical lattice clock, enabling unprecedented precision in timekeeping. JILA Adam M. Kaufman was awarded the 2023 in Physics Prize for developing optical tweezer arrays to control individual atoms for applications. Additionally, JILA Jason Dexter shared in the 2020 as a key member of the Event Horizon Telescope Collaboration, which produced the first image of a . Institutional recognitions further affirm JILA's enduring contributions to physics. In 2012, on its 50th anniversary, JILA was designated a Physics Historic Site by the American Physical Society for its groundbreaking achievements across astrophysics, atomic and molecular physics, and precision measurement. In 2017, JILA received the CO-LABS Governor's Award for High-Impact Research, honoring collaborative projects with significant societal benefits, presented to JILA Fellow Tom Perkins and team. As of 2025, JILA continues to garner acclaim for quantum advancements. JILA and NIST Fellow Jun Ye received the 2025 Berthold Leibinger Zukunftspreis for outstanding developments in light generation and application, particularly in ultrastable optical clocks. JILA Fellow and NIST Physicist Adam M. Kaufman was honored with the 2025 Presidential Early Career Award for Scientists and Engineers (PECASE) for his innovative contributions to and using neutral atoms. In 2025, JILA Fellow Cindy Regal was named a Brown Investigator for her pioneering work in quantum research. These recent awards exemplify JILA's ongoing prestige in quantum science.

Key Discoveries and Contributions

One of JILA's landmark achievements was the first experimental realization of a Bose-Einstein condensate (BEC) in a dilute atomic vapor, accomplished in 1995 by Eric Cornell, , and their team using rubidium-87 atoms cooled to near via and evaporative cooling techniques. This breakthrough, conducted at JILA's facilities, confirmed a quantum phenomenon predicted over 70 years earlier by and , enabling the study of matter waves in a coherent macroscopic . The work earned Cornell and Wieman the 2001 , shared with , and laid the foundation for ultracold atom research in quantum simulation and . In the realm of precision spectroscopy, JILA researchers John L. Hall and Jun Ye pioneered the optical frequency comb, a revolutionary tool using mode-locked femtosecond lasers to generate evenly spaced spectral lines that link microwave and optical frequencies with unprecedented accuracy. Hall's development of stable continuous-wave lasers, combined with Ye's advancements in self-referenced frequency combs, allowed direct measurement of optical frequencies, transforming time and frequency metrology. This innovation, recognized by the 2005 Nobel Prize in Physics shared with Theodor Hänsch, has enabled applications in absolute optical frequency synthesis and high-resolution spectroscopy. JILA's contributions to technology, particularly through NIST collaborations, have advanced optical lattice clocks using and atoms, achieving stability and accuracy that surpass traditional cesium clocks and underpin global positioning systems (GPS) by providing the precise time synchronization needed for satellite-based navigation. These clocks, with uncertainties below 10^{-18}, support relativistic tests and fundamental physics measurements while serving as NIST time standards that enhance GPS positional accuracy to meters. Ongoing refinements, such as entanglement-enhanced clocks, push beyond the for even greater precision. In science, JILA's theoretical and experimental efforts, led by groups like Jaron Becker's, have advanced the use of attosecond laser pulses (durations of 10^{-18} seconds) to probe ultrafast electron dynamics in atoms and molecules, revealing nonadiabatic processes and electron correlations on their natural timescales. Key demonstrations include angle-resolved photoelectron spectroscopy to image sub-femtosecond electron motion and control, providing insights into light-matter interactions at the quantum level. These techniques have enabled real-time observation of phenomena like Auger decay and charge migration, influencing fields from to . JILA has extended quantum control to macroscopic scales through microwave electromechanics, where researchers demonstrated preparation and readout of nonclassical states in mechanical oscillators, such as nanomechanical resonators cooled to their . This work, including of macroscopic objects, bridges and , with applications in quantum sensing and hybrid quantum systems. techniques have further optimized control protocols for these systems, enhancing times and enabling scalable quantum interfaces. In , JILA Fellow Jason contributed algorithms and predictive models for imaging that informed the Event Horizon Telescope (EHT) collaboration, aiding the interpretation of the first shadow images of M87* in 2019 and Sagittarius A* in 2022 by simulating emissions and gravitational lensing effects. These computational tools, grounded in , helped validate observations and earned a share of the Breakthrough Prize in Fundamental Physics. These discoveries have profoundly impacted quantum technologies, with JILA's innovations informing NIST standards for timekeeping, metrology, and processing, while fostering advancements in secure communications and sensing platforms. Since its founding in , JILA has produced thousands of peer-reviewed publications that drive these fields forward. Additionally, JILA's educational programs train a diverse for the National Quantum Initiative, preparing students and researchers for emerging quantum industries through hands-on quantum experimentation and interdisciplinary curricula.

People

Fellows and Leadership

JILA's leadership is provided by a team that includes the JILA Chair, currently John Bohn, a fellow specializing in theoretical and focused on molecules. Bohn oversees the institute's strategic direction in collaboration with representatives from NIST and the (). Fellows often hold joint appointments, with many serving as NIST Fellows or CU Boulder professors, reflecting JILA's collaborative structure between the two institutions. The core of JILA's research is driven by approximately 29 active fellows, comprising a balanced mix of experimentalists and theorists who lead interdisciplinary groups in areas such as , , astrophysics, and precision measurement. Experimentalists, who develop advanced systems and quantum devices, outnumber theorists slightly, but both contribute to JILA's emphasis on fundamental and . Prominent fellows include Eric Cornell, a NIST Fellow and CU Boulder professor known for his pioneering work in ultracold atoms and Bose-Einstein condensates, for which he shared the 2001 . John Hall, a in physics (2005) for laser stabilization techniques, serves in an emeritus capacity, continuing to influence precision measurement efforts. Jun Ye, a JILA and NIST and physics professor, leads research on optical atomic clocks and frequency combs, earning the 2025 Berthold Leibinger Zukunftspreis for advancements in laser-based timekeeping. Margaret Murnane, a JILA and distinguished professor, directs science initiatives using ultrafast lasers to probe electron dynamics in materials. Ana Maria Rey, a JILA and NIST , advances theoretical quantum physics, modeling ultracold molecules for quantum simulation and computing applications. Adam Kaufman, a JILA , NIST , and professor, specializes in quantum simulation with neutral atoms, receiving the 2025 Presidential Award for Scientists and Engineers (PECASE) for his contributions to many-body quantum systems. Jason Dexter, a JILA and astrophysicist, develops theoretical models of accretion and sources. In August 2025, JILA welcomed Dr. Taeho Ryu as an Associate and Assistant Professor in the Department of Astrophysical and Planetary Sciences. In 2025, JILA saw notable honors for its fellows, including Ye's selection as a Highly Cited Researcher for the 12th year and his AB Nexus grant for quantum collaborations, alongside Kaufman's PECASE recognition, highlighting the institute's ongoing impact in quantum and precision sciences.

Education and Training

JILA plays a central role in graduate and postdoctoral education, primarily through its partnership with the (CU Boulder). Doctoral training occurs via CU Boulder's Physics and Chemistry departments, where students pursue degrees while conducting research at JILA under the supervision of JILA fellows. These programs emphasize interdisciplinary work in atomic, molecular, and optical physics, , and precision measurement, integrating theoretical and experimental approaches. Postdoctoral fellowships are supported through multiple channels, including appointments via CU Boulder and the National Research Council (NRC) Research Associateship Program administered by NIST, as well as NSF-funded positions. These opportunities enable early-career researchers to engage in cutting-edge projects, often bridging JILA's core research areas with broader applications in . Key initiatives enhance collaborative training. The JILA Physics Frontier Center (PFC), funded by the NSF, fosters student involvement in multi-investigator projects that develop novel light sources and control , promoting shared expertise among graduate students and postdocs. The Quantum Systems through Entangled Science and Engineering (Q-SEnSE) center, an NSF Challenge Institute led by CU Boulder and JILA, prioritizes and through targeted programs like internships, adaptation, and studies on student learning in quantum courses. JILA's contributions to the National Quantum Initiative further support these efforts by aligning training with national priorities in , including workshops on , communication, and technical skills such as nanofabrication. JILA trains dozens of graduate students and postdocs annually, contributing to a skilled workforce in quantum and precision sciences. Alumni frequently secure positions in academia as faculty or researchers, in industry at quantum technology firms developing sensors and computing systems, and in government laboratories advancing national innovation. Students and postdocs gain hands-on experience through access to JILA's specialized facilities, including the W.M. Keck Laboratory for optical metrology and micro/nano fabrication, as well as instrument shops that support custom device construction for experiments in quantum sensing and ultracold atoms. This practical training equips trainees with essential skills for independent research and interdisciplinary collaboration.

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