Field-linked resonances of polar molecules

Scattering resonances are an essential tool for controlling interactions of ultracold atoms and molecules. However, conventional Feshbach scattering resonances [1], which have been extensively studied in various platforms [1–7], are not expected to exist in most ultracold polar molecules due to the fast loss that occurs when two molecules approach at a close distance [8–10]. Here, we demonstrate a new type of scattering resonances that is universal for a wide range of polar molecules. The so-called field-linked resonances [11–14] occur in the scattering of microwave-dressed molecules due to stable macroscopic tetramer states in the intermolecular potential. We identify two resonances between ultracold ground-state sodium-potassium molecules and use the microwave frequencies and polarizations to tune the inelastic collision rate by three orders of magnitude, from the unitary limit to well below the universal regime. The field-linked resonance provides a tuning knob to independently control the elastic contact interaction and the dipole-dipole interaction, which we observe as a modification in the thermalization rate. Our result provides a general strategy for resonant scattering between ultracold polar molecules, which paves the way for realizing dipolar superfluids [15] and molecular supersolids [16] as well as assembling ultracold polyatomic molecules.

[1]  W. Ketterle,et al.  A Feshbach resonance in collisions between triplet ground-state molecules , 2022, Nature.

[2]  T. Pfau,et al.  Observation of a molecular bond between ions and Rydberg atoms , 2022, Nature.

[3]  I. Bloch,et al.  Evaporation of microwave-shielded polar molecules to quantum degeneracy , 2022, Nature.

[4]  B. Lev,et al.  Dipolar physics: a review of experiments with magnetic quantum gases , 2022, Reports on progress in physics. Physical Society.

[5]  T. Langen,et al.  Self-bound dipolar droplets and supersolids in molecular Bose-Einstein condensates , 2021, Physical Review Research.

[6]  W. Ketterle,et al.  Control of reactive collisions by quantum interference , 2021, Science.

[7]  M. Zwierlein,et al.  Resonant and first-order dipolar interactions between ultracold Σ1 molecules in static and microwave electric fields , 2021, Physical Review A.

[8]  I. Bloch,et al.  Transition from a polaronic condensate to a degenerate Fermi gas of heteronuclear molecules , 2021, Nature Physics.

[9]  K. Ni,et al.  Bimolecular Chemistry in the Ultracold Regime. , 2021, Annual review of physical chemistry.

[10]  M. Tomza,et al.  Observation of Feshbach resonances between a single ion and ultracold atoms. , 2021, Nature.

[11]  J. Bohn,et al.  Anisotropic thermalization of dilute dipolar gases , 2021, 2104.00724.

[12]  W. Ketterle,et al.  Observation of microwave shielding of ultracold molecules , 2021, Science.

[13]  Jun Ye,et al.  Resonant collisional shielding of reactive molecules using electric fields , 2020, Science.

[14]  G. Groenenboom,et al.  Imaging the onset of the resonance regime in low-energy NO-He collisions , 2020, Science.

[15]  S. Will,et al.  Resonant Dipolar Collisions of Ultracold Molecules Induced by Microwave Dressing. , 2020, Physical review letters.

[16]  D. Blume,et al.  Observation of resonant scattering between ultracold heteronuclear Feshbach molecules , 2019, Physical Review A.

[17]  G. Groenenboom,et al.  Quasiclassical method for calculating the density of states of ultracold collision complexes , 2019, Physical Review A.

[18]  D. Stamper-Kurn,et al.  Quantum gas microscopy of Rydberg macrodimers , 2018, Science.

[19]  Jian-Wei Pan,et al.  Observation of magnetically tunable Feshbach resonances in ultracold 23Na40K + 40K collisions , 2018, Science.

[20]  G. Quéméner,et al.  Controlling the Scattering Length of Ultracold Dipolar Molecules. , 2018, Physical review letters.

[21]  J. Hutson,et al.  Microwave Shielding of Ultracold Polar Molecules. , 2018, Physical review letters.

[22]  K. Ni,et al.  Dipolar exchange quantum logic gate with polar molecules , 2018, Chemical science.

[23]  N. Balakrishnan Perspective: Ultracold molecules and the dawn of cold controlled chemistry. , 2016, The Journal of chemical physics.

[24]  S. Kokkelmans,et al.  Feshbach resonances in ultracold gases , 2014, 1401.2945.

[25]  M. Costes,et al.  Observation of Partial Wave Resonances in Low-Energy O2–H2 Inelastic Collisions , 2013, Science.

[26]  A. Henson,et al.  Observation of Resonances in Penning Ionization Reactions at Sub-Kelvin Temperatures in Merged Beams , 2012, Science.

[27]  P. Zoller,et al.  Condensed matter theory of dipolar quantum gases. , 2012, Chemical reviews.

[28]  M. Mayle,et al.  Statistical Aspects of Ultracold Resonant Scattering , 2012, 1203.6868.

[29]  M. Lukin,et al.  Tunable superfluidity and quantum magnetism with ultracold polar molecules. , 2011, Physical review letters.

[30]  N. Cooper,et al.  Topological px + ipy superfluid phase of fermionic polar molecules , 2011, 1103.3859.

[31]  J. Ye,et al.  Dipolar collisions of polar molecules in the quantum regime , 2010, Nature.

[32]  P. Julienne,et al.  Universal rate constants for reactive collisions of ultracold molecules. , 2009, Physical review letters.

[33]  N. Cooper,et al.  Stable topological superfluid phase of ultracold polar fermionic molecules. , 2009, Physical review letters.

[34]  Jun Ye,et al.  Cold and ultracold molecules: science, technology and applications , 2009, 0904.3175.

[35]  C. Ticknor,et al.  Quasi-universal dipolar scattering in cold and ultracold gases , 2009, 0901.1281.

[36]  J. Dalibard,et al.  Many-Body Physics with Ultracold Gases , 2007, 0704.3011.

[37]  J. Hutson Feshbach resonances in ultracold atomic and molecular collisions: threshold behaviour and suppression of poles in scattering lengths , 2006, physics/0610210.

[38]  C. Ticknor,et al.  Long-range scattering resonances in strong-field-seeking states of polar molecules , 2005, physics/0506104.

[39]  J. Herbig,et al.  Observation of Feshbach-like resonances in collisions between ultracold molecules. , 2004, Physical review letters.

[40]  Markus Greiner,et al.  Emergence of a molecular Bose–Einstein condensate from a Fermi gas , 2003, Nature.

[41]  A. Avdeenkov,et al.  Field-linked states of ultracold polar molecules , 2003, physics/0309004.

[42]  A. Avdeenkov,et al.  Linking ultracold polar molecules. , 2002, Physical review letters.

[43]  M. Baranov,et al.  Superfluid pairing in a polarized dipolar Fermi gas , 2001, cond-mat/0109437.

[44]  D. DeMille Quantum computation with trapped polar molecules. , 2001, Physical review letters.

[45]  Dong,et al.  Resonance-mediated chemical reaction: F+HD-->HF+D , 2000, Physical review letters.

[46]  A. Rau,et al.  Collisions near threshold in atomic and molecular physics , 2000 .

[47]  L. You,et al.  PROSPECTS FOR P-WAVE PAIRED BARDEEN-COOPER-SCHRIEFFER STATES OF FERMIONIC ATOMS , 1999, cond-mat/9906250.

[48]  D. Colbert,et al.  A novel discrete variable representation for quantum mechanical reactive scattering via the S-matrix Kohn method , 1992 .

[49]  Henry Margenau,et al.  Theory of intermolecular forces , 1969 .