Surface-based Radiation Observations ( primarily broadband w/ a climate bias)

1. Surface-based Radiation Observations (primarily broadband w/ a climate bias) Ellsworth G. Dutton NOAA, Earth System Research Laboratory Boulder, Colo ells.dutton@noaa.gov Outline • Observable Radiation Quantities (review) • General and Specific Applications • Applied Radiometry • Incoming (downwelling) Solar Irradiance • Downwelling Thermal Infrared • Reflected and Surface-emitted Upwelling Irrad. • Remote Sensing of the Atmosphere at Solar Wavelengths • Recent Advances • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

2. R E T A Observable Radiation Quantities(energy per unit time per unit area) • Emitted • Absorbed • Reflected • Transmitted E = A + R + T, 1.0 = a + r + t SI Units W m-2 (Joules sec-1 m-2) • Two Types of Radiation Emission Sources • Full-spectrum - Black and grey bodies (opaque mass/objects) • Molecular emission lines (semi-transparent gases/mediums) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

3. Opaque Solid Kirchoff’s LawMass emits the same as it absorbs • Opaque bodies, such as a hot, dense gas or solids produce a continuous spectrum – Known as a blackbody if absorption at all wavelengths is 100% • A hot transparent gas produces an emission line spectrum – a series of bright spectral lines against a dark background. • A cool, transparent gas in front of a source of a continuous spectrum produces an absorption line spectrum – a series of dark spectral lines among the colors of the continuous spectrum. physics.unl.edu/~klee/ast204/lectures/Ast204_lecture14_01.ppt • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

4. Planck’s Law for Full-spectrum Emission Stephan-Boltzman Law (ideal BB) ∫Idλ = σ T4 (realistic, grey) ∫ Idλ = εσ T4 ε=0→ <1.0 I -- Radiation (W m-2 nm-1) c -- speed of light h -- Planck constant K -- Boltzman constant T -- Temperature λ -- Wavelength I (relative units λ-1) Wein’s Law • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

5. Some Terminology • Radiance – Radiant power per unit area per steradian (3-D conical solid angle) W m-2 ster-1 (remote sensing, mapping) • Irradiance – Radiant power per unit area W m-2 (fluxes) Either can be specified spectrally as per unit wavelength or integrated over some spectral interval • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

6. Note: 0.3 μm to 3.0 μm (includes downward scattering) Illustration only ModTran 5.0 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

7. Note: 3.5 μm to >50 μm ModTran 5.0 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

8. Examples of Applications for Radiation Observations • Satellite observed constraints on inversions • Model (rad transfer, Wx, Climate) comparisons • Surface and boundary layer energy budgets, dynamics and surface flux partitioning • Vertical profiles for flux divergence (heating rates) • Radiation climatology • IR trends related to Global Warming • Solar Dimming & Brightening variations • Estimating cloud and aerosol effects • International cooperative observational programs • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

9. Trenberth et al 2009 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

10. Surface Radiation Budget Observations and Research An Integrated approach … RT Retrieval Validation Assimilation Models Climate-quality surface observations Validation BSRN More accurate radiative transfer in weather, and climate simulations Improvement Direct Observations • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

11. Measurements • Direct & diffuse solar* • Downward infrared * • Upwelling rad. • PAR & UV • Aerosol optical depth • Surface meteorology* • Upper air met. • * all sites • Data Applications • GCM comparisons • Satellite validation • Regional climatologies • Global radiation budget • Radiation model testing Regions Oceanic Tropics Desert Polar Coastal Rain forest Agricultural Prairie EG Dutton, 4Oct2007 Baseline Surface Radiation Network • Features • Site scientists • 18+ countries • Stand. Specs. • Long-term • Central archive • Ref. Std. Devlp. • GRP review • GCOS Goal: To acquire the highest possible quality, climati-cally-diverse, surface-based radiation measurements for climate research IOC WMO Archiving Provisional

12. Radiation Budget Components, time averaging LW  LW SW  SW  Erie Tower NOAA/CMDL STAR • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

13. BSRN ISCCP Sat. constrained model Comparison of Satellite vs. Ground-based Surface Irradiance Products NASA / CERES / SOFA – D. Kratz BSRN NASA / GEWEX / SRB - P. Stackhouse SW bias <2. LW bias <2. NASA / CERES / SARB - T Charlock / D. Rutan NASA / WCRP / ISCCP - Zhang et al • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

14. Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

15. Compared to Observations BSRN 251 BSRN – International Baseline Surface Radiation Network s E.G. Dutton Pan-GEWEX Mtg 10 Oct 2006 Frascati, Italy • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

16. BSRN (344 W m-2) Model Avg. (329) Circa 1999 GCM models (global means) BSRN (344) Avg. (337) Circa 2005 GCM models (global means) Over Last 6 Years, Climate Models Approach BSRN Downwelling IR Results M. Wild 2001& 2005 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

17. Long Term Variability Longest Surface Solar records, Europe Ohmura 2009, JGR Early Brightening Dimming Brightening • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

18. Observations Confirming Surface IR Global Warming Increases w/ Feedbacks BSRN Observed ~2.5 W m-2/dec IPCC AR4 GCM Means ---- GHG forcing only ---- GHG + direct aerosol foricing ---- GHG + direct and Indirect aerosol forcing GHG forcing • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

19. “It can be a lot easier to measure something than it is to know what it is that you measured!” Particularly true in radiometry. ∫∫∫∫∫∫∫ I(t,z,x,y,θ,φ,λ)dtdθdφdλdzdxdy = 7.38 mV • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

20. Generic Radiometer and View-Scene Components Radiometer • Desirable • Characteristics • Stable w/ time • Defined spectral • response • Defined geometry • Linear output • Fast response • Low cost  (x), T(x) T,  Signal processor Intervening medium (possible sources and sinks) View limiter Source Detector May or may not have all these components Spectral selection (filter) Detector typesSpectral selectionView limiters Photo multiplier Detector sensitivity Adjustable aperture Photoelectric cell Interference filter Fixed aperture Thermopile Absorption filter Flat plate Pyroelectric Prism/Grating Optics Cavity Shutter • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

21. Common Surface-based Broadband Radiometers for Surface Radiation Budget Measurements • Pyrheliometer – Direct solar beam (on a perpendicular surface) • Pyranometer – Total (diffuse+ direct, Global) solar on a horizontal surface • Shaded pyranometer – Diffuse solar (horizontal surface) • Pyrgeometer – Thermal IR “ “ Previously widely used by surface energy budget community* • Net radiometer – single element • Subtraction to get IR or solar from total spectrum *generally sub-standard accuracy by today’s standards - lacking component resolution and calibration reference standards. Notes: Total solar = Normal Direct ∙ cos(θ) + Diffuse, θ = solar zenith angle Surface Rad. Bud. (net) = Total solar + sky LW - reflected solar - surface emitted LW • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

22. C B D A SOLAR E THERMAL INFRARED Obs. Site Surface Radiation Budget Component Quantities (A-E) SPACE Θ A – Diffuse solar B -- Direct solar, normal C – Reflected solar D – Downward IR E – Upward IR Total Downward Solar = A + cos (Θ) *B EARTH • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

23. Direct Solar Irradiance 5.7 º • Easiest component to model • High sensitivity to attenuators • Dominant component of total solar when sky is clear Measurement • Relatively easy and accurate to calibrate by absolute cavity • Alignment and tracking required • 0.28 μm to ~3.5 μm Declination axis (manual on this tracker) Clock motor on equatorial (right ascension) axis Eppley Labs pyrheliometer (NIP) & tracker • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

24. Typical Pyrheliometer (with spectral filter → sun photometer) Solar Im = cc ·V V = f(ΔT,T) ΔT = ε· nIi Im -- Measured direct solar Irradiance cc -- Assigned linear calibration constant V -- Output voltage T -- Temperature ΔT -- Thermopile T – Ref T ε -- Proportionality “constant” nIi -- Net incident irradiance at detector = Id + Is – Ir + LWi – LWo Id = Direct solar irradiance Is = Scattered solar Ir = Reflected solar LWi = Incoming thermal LW (IR) LWo = Outgoing thermal LW (IR) View limiting aperture Clear glass window (filter and Wx protect) Baffles Thermopile Electronics Temp. Comp. • Instrument design requirement: • Id proportional to V • General User application: • Find cc and assume that Im = Id • Reality for the most accurate meas.: • Id = f(Im) Ref Temp. - + Connector (to voltmeter) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

25. Error sources in Pyrheliometer Meas. Alignment aid (diopter) Instrument Characteristics • Calibration stability • Linearity • Window spectral transmission • Sensitivity temperature dependency • … User Characteristics • Calibration reference & transfer • Alignment & obstructions • Window cleanliness • Data collection system • … Kipp& Zonen CH-1 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

26. Diffuse Solar Irradiance • Information on downward scattering, high sensitivity to scatters • Difficult to model, other than Rayleigh • Sometimes is 100% of total solar component • Sensitive to surface albedo Measurement issues • No universal calibration reference • Calibration: transfer from calibrated pyranometer under diffuse conditions, or as total pyranometer • Direct solar blockage required, tracking disk highly preferred • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

27. Error Sources in Diffuse Meas. • Same as direct component plus: • Unknown absolute reference • Dome thermal offsets (black thermopile detectors) • Shade geometry • Cosine response of flat plate • Subtle obstructions • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

28. Total (Global) Solar Irradiance • Primary desired quantity in radiation budget • Sensitivity to forward scatters is reduced • Difficult to model –absorption and scat. phase • Sensitive to surface albedo • Many other applications – agriculture, renewable energy… Measurement issues • No absolute calibration reference • Very serious cosine (non-linearity) response issues • Calibration: transfer of WRR by shade-cal, component sum cal in clear sky, or laboratory reference source • Lots of instrument choices, some quite bad • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

29. Typical Pyranometer Direct IT = cc · V Solar LW (IR) exchange Diffuse SW = cc ∙Voltage Clear glass domes Ref Temp. Temp. Comp. - + • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

30. Error Sources in Total Solar(measured by a single pyranometer) • Same as direct and diffuse, minus tracking • Cosine error aggravated by large direct component • Leveling • Proliferation of cheap sensors • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

31. Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

32. Thermal IR Meas. • Typically measured over ~3.5μm to ~50 μm • Difficult to model (clouds and cloud bases, H2O) • Generally hemispherically diffuse • Downwelling is total “greenhouse” effect • Detector elements emitting at measured wavelengths • Blackbody references possible • Trends predicted • Routine measurements maturing Eppley PIR • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

33. Typical Pyrgeometer IR↓ = cc · V + σTc4 + kσ(Tc4-Td4) Incident LW Solar . Silicon dome (silver) Tdome LW exchange Tcase Ref Temp. Temp. Comp. - + Connector • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

34. Error Sources in IR Meas • Contamination from instrument elements • Absolute calibration • No universal reference other than BB • Instrument noise • Source definition (solar source included?) • Spectral definition • Data system, obstructions, etc • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

35. Upwelling irradiances • The other “half” of the problem • Same instrumentation, inverted • Completely diffuse fields • Better constrained (near the surface) • Representativeness & interpretation issues • Instrument deployment problems (shadows, height, service) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

36. END(sort of) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

37. Remote Sensing of the atmosphere at Solar Wavelenghts • Spectral Aerosol optical depth • Total column attenuation • Relative size distribution • Scattering angle (phase function or asymmetry factor • Absorption • Ozone • Water Vapor • NO2 • Exotic trace species • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

38. Sprectral Optical Depth Remote Sensing Basics AOD = Aerosol Optical Depth = τλa Beer’s Law Iλ/I0λ = exp(-τλmr) Iλ= cc ∙ Vλ Vλ/V0λ = exp(-τλmr) τλ= τλH2O + τλO3 + τλaerosol +… • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

39. Silicon cell response (RHS) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

40. Recent Advances In Direct Solar Meas. • Sustained definition of World Radiation Reference scale, since 1976 • Better solar tracking, circa early 1990s (computerized/interactive) • Introduction of calcium fluoride (CaF4) windows, high trans. to 10μm • All-weather cavity radiometers • New understanding of thermal off-sets and non-linearities in operational pyrheliometers • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

41. Recent Advances in Solar Diffuse Meas. • Better tracking of shade disk • Comparisons to the Rayleigh limit • Corrections and reductions of thermal offset error • Revival of black and white detectors • Consensus intercomparisons • Recommend Reference Stnd. -- Michalsky et al 2007 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

42. Recent Advances in Total Solar Meas. • Refined “shade/unshade” calibration • Improved cosine response • Reduced dome thermal offset • Ventilation “conditioning” • Dome thermal contact to base • Correction algorithms • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

43. Recent Advances in IR Meas. • Proper dome temperature correction • Pyrgeometer tracking shading • Absolute scanning reference radiometer • Isothermal domes • “Flatter” domes • Ventilation of domes • Interim International Reference Standard established (World Radiation Center, Davos, Switzerland) • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

44. Example BSRN SITES Barrow Barrow, Alaska Boulder, Colorado Kwajalein, M.I. Boulder - BAO Kwajalein E.G.Dutton NOAA/CMDL

45. The Three Ways to Transport Thermal Energy • Convention/Advection • Conduction • Electromagnetic Radiation

46. Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

47. General Applications for Measured E/M Radiation in Atmos Sci. • Account for amount of heat energy transferred from a source to a surface or volume of interest • Determine temperature of emitting sources/gases • Determine quantity and type of emitting gases or absorbing gases between source and receiver • Determine quantity and/or some characteristics of intervening suspended particulates (scattering and absorption) • Mapping of emission, reflection and/or absorption Remote Sensing • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009

48. Selected references – Related to Broadband Surface Radiation Measurements - Ells Dutton CSU/AT650 23Sept2007(Also look under Publications at http://bsrn.ethz.ch) Solar, direct and diffuse • Hengstberger, F., (ed.) 1989: Absolute Radiometry – Electrically Calibrated Thermal Detectors for Optical Radiation Academic Press, Boston, 266p. • Frohlich, C., 1991: History of solar radiometry and the World Radiometric Reference. Metrologia 3, 111-15. • Romero, J., et al., 1991: First comparison of the solar and SI radiometric scale. Metrologia, 28, 125-128. • Romero, J. et al., 1995: Improved comparison of the World Radiometric Reference and the SI radiometric scale Metrologia, 32, 523. • Michalsky, J., et al., 1999: Optimal measurements of surface shortwave irradiance using current instrumentation. J. Tech., 16, 55-69 • Bush, B.C. and F.P.J. Valero, 1999: Comparison of ARESE clear sky surface radiation measurements. J. Quant. Spectrosc. Radiat. Transfer, 61, 249-264. • Bush, B.C., et al., 2000: Characterization of thermal effects in pyranometers: A data correction algorithm for improved measurement of surface insolation. J. Tech. 17, 165-175. • Halthore, R. et al., 1997: Comparison of model estimated and measured direct-normal soar irradiance. JGR 102, 29,991-20,002. • Halthore, R., et al., 1998: Models overestimate diffuse clear-sky surface irradiance: a case for excess atmospheric absorption. GRL 25, 3591-3594. • Kato, S., et al., 1997: Uncertainties in modeled and measured clear-sky surface shortwave irradiances. JGR 102, 25,882-25,898. • Kato, S. et al., 1999: a comparison of modeled and measured surface shortwave irradiance for a molecular atmosphere. J Quant. Spectrosc. Radiat. Transfer 61, 493-502 • Dutton, E. G., et al., 2001: Measurement of broadband diffuse solar irradiance using current commercial instrumentation with a correction for thermal offset errors. J. Tech. 18, 297-314. • Haeffelin, M., et al., 2001: Determination of the Thermal Offset of the Eppley Precision Spectral Pyranometer , Applied Optics-OT, Volume 40, Issue 4, 472-484. • Cess, R. D., et al, 2000: Consistency tests applied to the measurement of total, direct, and diffuse shortwave radiation at the surface. JGR 105, 24,881-24,887. • Ohmura, A., et al., 1998: Baseline Surface Radiation Network (BSRN/WCRP): New precision radiometry for climate research. BAMS, 79, 2115-2136. • Philipona R, 2002:Underestimation of solar global and diffuse radiation measured at Earth's surface J. Geophys. Res.VOL. 107, NO. D22, 4654, doi:10.1029/2002JD002396, 2002 • Zamora, R.J., et al., 2002: Comparing MM5 radiative fluxes with observations gathered during the 1995 and 1999 Nashville Southern Oxidants Studies, J Geophys. Res. 108, D2,4050,doi:10.1029/202JD002122. • Dutton, E.G., A. Farhadi, R.S. Stone, C. Long, and D. W. Nelson: 2004: Long-term variations in the occurrence and effective solar transmission of clouds determined from surface irradiance observations.J. Geophys. Res., Vol. 109, No. D3, D0320410.1029/2003JD003568. • Michalsky, J.J., et al., 2003: Results from the first ARM diffuse horizontal shortwave irradiance comparison. J. Geophys. Res. 108, D3, 4108, doi:10.1029/2002JD002825. • Augustine, J. A., et al.,, An update on SURFRAD—The GCOS surface radiation budget network for the continental United States, J. Atmos. Ocean. Tech., 22, 1460-1472, 2005. • Michalsky, J. J., et al., Toward the development of a diffuse horizontal shortwave irradiance working standard, J. Geophys. Res., 110, D06107, doi:10.1029/2004JD005265, 2005. • Michalsky, J. J., et al,, Shortwave radiative closure studies for clear skies during the Atmospheric Radiation Measurement 2003 Aerosol Intensive Observation Period, J. Geophys. Res., 111, D14S90, doi:10.1029/2005JD006341, 2006. • Pinker R.T., B. Zhang, and E. G. Dutton, 2005: Do Satellites Detect Trends in Surface Solar Radiation? Science, Vol 308, Issue 5723, 850-854 , 6 May 2005 • Wild, M., et al.,. (2005). From Dimming to Brightening: Decadal Changes in Solar Radiation at Earth's Surface. Science,308: 847-850. • Zamora, R.J., et al., 2005: The accuracy of solar irradiance calculations used in mesoscale numerical weather prediction. Mon. Wea. Rev., 133, 783-792. • Reda, I., et al 2005: Using a blackbody to calculate net-longwave responsivity of shortwave solar pyranometers to correct for their thermal offset error during outdoor calibration using the summation method, J. Oceanic and Atmos. Tech.22, 1531–1540. • Dutton E.G., et al., 2006: Decadal Variations in Surface Solar Irradiance as Observed in a Globally Remote Network. 2006:  J. Geophys. Res., 111, D19101, doi:10.1029/2005JD006901. • J. J. Michalsky, et al., 2007: A proposed working standard for the measurement of diffuse horizontal shortwave irradiance. J GEOPHYS RES 112, D16112, doi:10.1029/2007JD008651, 2007 Longwave (thermal IR) • Albrecht, B., et al., 1974: Pyrgeometer measurements from aircraft. Rev Sci. Instrum., 45, 33-38. • Albrecht, B., and S. Cox, 1977: Procedures for improving pyrgeometer performance. JAM, 16, 188-197. • Dutton, E., 1993: An extended comparison between LOWTRAN7-computed and observed broadband thermal irradiance: Global extreme and intermediated surface conditions. J. Tech. 10, 326-336. • Philipona, R., et al., 1995: Characterization of pyrgeometers and the accuracy of atmospheric long-wave radiation measurements. App. Optics 34, 1598-160. • Philipona, R. et al., 1998: The Baseline Surface Radiation Network pyrgeometer round robin calibration experiment. J. Tech. 15, 687-696. • Fairall, C.W., et al., 1998: A new look at the calibration and use of Eppley precision infrared radiometers. Part I Theory and applications. J. Tech. 15, 1229-1242. • Philipona, R. et al., 2001 Atmospheric longwave irradiance uncertainty: Pyrgeometer compared to an Absolute sky-scanning radiometer, AERI and radiative transfer model calculations. J. Geophys. Res. 106, 28,129-28,141. • Marty, C., R. etal., 2002: Longwave irradiance uncertainty under arctic atmospheres: Comparisons between measured and modeled downward longwave fluxes. J. Geophys. Res., VOL. 108, NO. D12, 4358, doi:10.1029/2002JD002937, 2003 • Philipona, R, et al.: Radiative forcing - measured at Earth's surface - corroborate the increasing greenhouse effect GEOPHYS RES LET, 31 (3): Art. No. L03202 FEB 6 2004 • Ells Dutton NOAA/ESRL NCAR/ASP 1 June 2009