References

[1]
R. Pincus, E. J. Mlawer and J. S. Delamere. Balancing accuracy, efficiency, and flexibility in radiation calculations for dynamical models. Journal of Advances in Modeling Earth Systems 11, 3074–3089 (2019).
[2]
G. P. Anderson, S. A. Clough, F. X. Kneizys, J. H. Chetwynd and E. P. Shettle. AFGL atmospheric constituent profiles (0–120 km). Technical Report AFGL-TR-86-0110 (Air Force Geophysics Laboratory, 1986).
[3]
D. M. Frierson, I. M. Held and P. Zurita-Gotor. A gray-radiation aquaplanet moist GCM. Part I: Static stability and eddy scale. Journal of the Atmospheric Sciences 63, 2548–2566 (2006).
[4]
P. A. O’Gorman and T. Schneider. The hydrological cycle over a wide range of climates simulated with an idealized GCM. Journal of Climate 21, 3815–3832 (2008).
[5]
T. Schneider. The tropopause and the thermal stratification in the extratropics of a dry atmosphere. Journal of the Atmospheric Sciences 61, 1317–1340 (2004).
[6]
S. Manabe and R. F. Strickler. Thermal equilibrium of the atmosphere with a convective adjustment. Journal of the Atmospheric Sciences 21, 361–385 (1964).
[7]
S. Manabe and R. T. Wetherald. Thermal equilibrium of the atmosphere with a given distribution of relative humidity. Journal of the Atmospheric Sciences 24, 241–259 (1967).
[8]
L. Kluft, S. Dacie, S. A. Buehler, H. Schmidt and B. Stevens. Re-examining the first climate models: Climate sensitivity of a modern radiative-convective equilibrium model. Journal of Climate 32, 8111–8125 (2019).
[9]
T. W. Cronin. On the choice of average solar zenith angle. Journal of the Atmospheric Sciences 71, 2994–3003 (2014).
[10]
D. M. Romps. The Rankine-Kirchhoff approximations for moist thermodynamics. Quarterly Journal of the Royal Meteorological Society 147, 3493–3497 (2021).
[11]
L. Kluft, S. Dacie, M. Brath, S. A. Buehler and B. Stevens. Temperature-dependence of the clear-sky feedback in radiative-convective equilibrium. Geophysical Research Letters 48, e2021GL094649 (2021).
[12]
W. Meador and W. Weaver. Two-stream approximations to radiative transfer in planetary atmospheres: A unified description of existing methods and a new improvement. Journal of the Atmospheric Sciences 37, 630–643 (1980).
[13]
R. J. Hogan. What are the optimum discrete angles to use in thermal-infrared radiative transfer calculations? Quarterly Journal of the Royal Meteorological Society 150, 318–333 (2024).
[14]
Q. Fu, K. Liou, M. Cribb, T. Charlock and A. Grossman. Multiple scattering parameterization in thermal infrared radiative transfer. Journal of the Atmospheric Sciences 54, 2799–2812 (1997).
[15]
S. A. Clough, M. J. Iacono and J.-L. Moncet. Line-by-line calculations of atmospheric fluxes and cooling rates: Application to water vapor. Journal of Geophysical Research: Atmospheres 97, 15761–15785 (1992).
[16]
O. B. Toon, C. McKay, T. Ackerman and K. Santhanam. Rapid calculation of radiative heating rates and photodissociation rates in inhomogeneous multiple scattering atmospheres. Journal of Geophysical Research: Atmospheres 94, 16287–16301 (1989).
[17]
J. K. Shonk and R. J. Hogan. Tripleclouds: An efficient method for representing horizontal cloud inhomogeneity in 1D radiation schemes by using three regions at each height. Journal of Climate 21, 2352–2370 (2008).
[18]
A. A. Lacis and V. Oinas. A description of the correlated k distribution method for modeling nongray gaseous absorption, thermal emission, and multiple scattering in vertically inhomogeneous atmospheres. Journal of Geophysical Research: Atmospheres 96, 9027–9063 (1991).
[19]
P. Yang, L. Bi, B. A. Baum, K.-N. Liou, G. W. Kattawar, M. I. Mishchenko and B. Cole. Spectrally consistent scattering, absorption, and polarization properties of atmospheric ice crystals at wavelengths from 0.2 to 100 $\mu$ m. Journal of the Atmospheric Sciences 70, 330–347 (2013).
[20]
J. H. Joseph, W. Wiscombe and J. Weinman. The delta-Eddington approximation for radiative flux transfer. Journal of the Atmospheric Sciences 33, 2452–2459 (1976).
[21]
P. Ukkonen and R. J. Hogan. Twelve times faster yet accurate: A new state-of-the-art in radiation schemes via performance and spectral optimization. Journal of Advances in Modeling Earth Systems 16, e2023MS003932 (2024).
[22]
W. G. Zdunkowski, R. M. Welch and G. Korb. An investigation of the structure of typical two-stream methods for the calculation of solar fluxes and heating rates in clouds. Contributions to Atmospheric Physics, 147–166 (1980).