### Abstract

Planetary boundary layer (PBL) CO_{2} mole fraction data are needed by transport models and carbon budget models as both input and reference for validation. The height of in situ CO_{2} mole fraction measurements is usually different from that of the model levels where the data are needed; data from short towers, in particular, are difficult to utilize in atmospheric models that do not simulate the surface layer well. Tall-tower CO_{2} mole fraction measurements observed at heights ranging from 10 to 115 m above ground level at a rural site in Hungary and regular airborne vertical mole fraction profile measurements (136 vertical profiles) above the tower allowed us to estimate how well a tower of a given height could estimate the CO_{2} mole fraction above the tower in the PBL. The statistical evaluation of the height-dependent bias between the real PBL CO_{2} mole fraction profile (measured by the aircraft) and the measurement at a given elevation above the ground was performed separately for the summer and winter half years to take into account the different dynamics of the lower troposphere and the different surface CO_{2} flux in the different seasons. The paper presents (1) how accurately the vertical distribution of CO_{2} in the PBL can be estimated from the measurements on the top of a tower of height *H*; (2) how tall of a tower would be needed for the satisfaction of different requirements on the accuracy of the estimation of the CO_{2} vertical distribution; (3) how accurate of a CO_{2} vertical distribution estimation can be expected from the existing towers; and (4) how much improvement can be achieved in the accuracy of the estimation of CO_{2} vertical distribution by applying the virtual tall-tower concept.

Original language | English |
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Pages (from-to) | 1657-1671 |

Number of pages | 15 |

Journal | Atmospheric Measurement Techniques |

Volume | 8 |

Issue number | 4 |

DOIs | |

Publication status | Published - Apr 7 2015 |

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### ASJC Scopus subject areas

- Atmospheric Science

### Cite this

*Atmospheric Measurement Techniques*,

*8*(4), 1657-1671. https://doi.org/10.5194/amt-8-1657-2015

**How well do tall-tower measurements characterize the CO2 mole fraction distribution in the planetary boundary layer?** / Haszpra, L.; Barcza, Z.; Haszpra, T.; Pátkai, Z. S.; Davis, K. J.

Research output: Contribution to journal › Article

*Atmospheric Measurement Techniques*, vol. 8, no. 4, pp. 1657-1671. https://doi.org/10.5194/amt-8-1657-2015

}

TY - JOUR

T1 - How well do tall-tower measurements characterize the CO2 mole fraction distribution in the planetary boundary layer?

AU - Haszpra, L.

AU - Barcza, Z.

AU - Haszpra, T.

AU - Pátkai, Z. S.

AU - Davis, K. J.

PY - 2015/4/7

Y1 - 2015/4/7

N2 - Planetary boundary layer (PBL) CO2 mole fraction data are needed by transport models and carbon budget models as both input and reference for validation. The height of in situ CO2 mole fraction measurements is usually different from that of the model levels where the data are needed; data from short towers, in particular, are difficult to utilize in atmospheric models that do not simulate the surface layer well. Tall-tower CO2 mole fraction measurements observed at heights ranging from 10 to 115 m above ground level at a rural site in Hungary and regular airborne vertical mole fraction profile measurements (136 vertical profiles) above the tower allowed us to estimate how well a tower of a given height could estimate the CO2 mole fraction above the tower in the PBL. The statistical evaluation of the height-dependent bias between the real PBL CO2 mole fraction profile (measured by the aircraft) and the measurement at a given elevation above the ground was performed separately for the summer and winter half years to take into account the different dynamics of the lower troposphere and the different surface CO2 flux in the different seasons. The paper presents (1) how accurately the vertical distribution of CO2 in the PBL can be estimated from the measurements on the top of a tower of height H; (2) how tall of a tower would be needed for the satisfaction of different requirements on the accuracy of the estimation of the CO2 vertical distribution; (3) how accurate of a CO2 vertical distribution estimation can be expected from the existing towers; and (4) how much improvement can be achieved in the accuracy of the estimation of CO2 vertical distribution by applying the virtual tall-tower concept.

AB - Planetary boundary layer (PBL) CO2 mole fraction data are needed by transport models and carbon budget models as both input and reference for validation. The height of in situ CO2 mole fraction measurements is usually different from that of the model levels where the data are needed; data from short towers, in particular, are difficult to utilize in atmospheric models that do not simulate the surface layer well. Tall-tower CO2 mole fraction measurements observed at heights ranging from 10 to 115 m above ground level at a rural site in Hungary and regular airborne vertical mole fraction profile measurements (136 vertical profiles) above the tower allowed us to estimate how well a tower of a given height could estimate the CO2 mole fraction above the tower in the PBL. The statistical evaluation of the height-dependent bias between the real PBL CO2 mole fraction profile (measured by the aircraft) and the measurement at a given elevation above the ground was performed separately for the summer and winter half years to take into account the different dynamics of the lower troposphere and the different surface CO2 flux in the different seasons. The paper presents (1) how accurately the vertical distribution of CO2 in the PBL can be estimated from the measurements on the top of a tower of height H; (2) how tall of a tower would be needed for the satisfaction of different requirements on the accuracy of the estimation of the CO2 vertical distribution; (3) how accurate of a CO2 vertical distribution estimation can be expected from the existing towers; and (4) how much improvement can be achieved in the accuracy of the estimation of CO2 vertical distribution by applying the virtual tall-tower concept.

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U2 - 10.5194/amt-8-1657-2015

DO - 10.5194/amt-8-1657-2015

M3 - Article

VL - 8

SP - 1657

EP - 1671

JO - Atmospheric Measurement Techniques

JF - Atmospheric Measurement Techniques

SN - 1867-1381

IS - 4

ER -