<p>Detecting single photons is a crucial process in quantum science, quantum networking, biology, and advanced imaging. To detect the small quantum of energy carried in a photon, conventional mechanisms rely on energy excitation across either a semiconductor bandgap or superconducting gap that hinders their applications to low-energy photons. Here, we detect single near-infrared photons using the thermal properties of Dirac fermions in graphene. By exploiting the extremely low heat capacity of Dirac electrons near its charge neutrality point, we observe a temperature rise up to &#xa0;~&#xa0;2 K using a hybrid Josephson junction. In this proof-of-principle experiment, we achieve an intrinsic quantum efficiency of 87% (75%) with dark count &#xa0;&lt; 1 per second (per week), reaching an effective noise equivalent power of 2&#xa0;×&#xa0;10<sup>−22</sup> W/<InlineEquation ID="IEq1"> <EquationSource Format="TEX">\(\sqrt{{{{\rm{Hz}}}}}\)</EquationSource> <EquationSource Format="MATHML"><math> <msqrt> <mrow> <mi mathvariant="normal">Hz</mi> </mrow> </msqrt> </math></EquationSource> </InlineEquation>. The highest operation temperature is 1.2 K. Our results highlight the potential of graphene bolometers for detecting lower-energy photons from the mid-IR to microwave regimes, opening pathways to study space science in far-infrared regime, to potential applications in dark matter searches, and to advance quantum technologies across a broader electromagnetic spectrum.</p>

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Thermal detection of single photons using Dirac fermions

  • Bevin Huang,
  • Ethan G. Arnault,
  • Woochan Jung,
  • Caleb Fried,
  • B. Jordan Russell,
  • Kenji Watanabe,
  • Takashi Taniguchi,
  • Erik A. Henriksen,
  • Dirk Englund,
  • Gil-Ho Lee,
  • Kin Chung Fong

摘要

Detecting single photons is a crucial process in quantum science, quantum networking, biology, and advanced imaging. To detect the small quantum of energy carried in a photon, conventional mechanisms rely on energy excitation across either a semiconductor bandgap or superconducting gap that hinders their applications to low-energy photons. Here, we detect single near-infrared photons using the thermal properties of Dirac fermions in graphene. By exploiting the extremely low heat capacity of Dirac electrons near its charge neutrality point, we observe a temperature rise up to  ~ 2 K using a hybrid Josephson junction. In this proof-of-principle experiment, we achieve an intrinsic quantum efficiency of 87% (75%) with dark count  < 1 per second (per week), reaching an effective noise equivalent power of 2 × 10−22 W/ \(\sqrt{{{{\rm{Hz}}}}}\) Hz . The highest operation temperature is 1.2 K. Our results highlight the potential of graphene bolometers for detecting lower-energy photons from the mid-IR to microwave regimes, opening pathways to study space science in far-infrared regime, to potential applications in dark matter searches, and to advance quantum technologies across a broader electromagnetic spectrum.