Best practices for estimating near‐surface air temperature lapse rates. (8th June 2020)
- Record Type:
- Journal Article
- Title:
- Best practices for estimating near‐surface air temperature lapse rates. (8th June 2020)
- Main Title:
- Best practices for estimating near‐surface air temperature lapse rates
- Authors:
- Lute, A. C.
Abatzoglou, John T. - Abstract:
- Abstract: The near‐surface air temperature lapse rate is the predominant source of spatial temperature variability in mountains and controls snowfall and snowmelt regimes, glacier mass balance, and species distributions. Lapse rates are often estimated from observational data, however there is little guidance on best practices for estimating lapse rates. We use observational and synthetic datasets to evaluate the error and uncertainty in lapse rate estimates stemming from sample size, dataset noise, covariate collinearity, domain selection, and estimation methods. We find that lapse rates estimated from small sample sizes (<5) or datasets with high noise or collinearity can have errors of several °C km −1 . Uncertainty in lapse rates due to non‐elevation related large‐scale temperature variability was reduced by correcting for spatial temperature gradients and restricting domains based on spatial clusters of stations. We generally found simple linear regression to be more robust than multiple linear regression for lapse rate estimation. Finally, lapse rates had lower error and uncertainty when estimated from a sample of topoclimatically self‐similar stations. Motivated by these results, we outline a set of best practices for lapse rate estimation that include using quality controlled temperature observations from as many locations as possible within the study domain, accounting for and minimizing non‐elevational sources of climatic gradients, and calculating lapse ratesAbstract: The near‐surface air temperature lapse rate is the predominant source of spatial temperature variability in mountains and controls snowfall and snowmelt regimes, glacier mass balance, and species distributions. Lapse rates are often estimated from observational data, however there is little guidance on best practices for estimating lapse rates. We use observational and synthetic datasets to evaluate the error and uncertainty in lapse rate estimates stemming from sample size, dataset noise, covariate collinearity, domain selection, and estimation methods. We find that lapse rates estimated from small sample sizes (<5) or datasets with high noise or collinearity can have errors of several °C km −1 . Uncertainty in lapse rates due to non‐elevation related large‐scale temperature variability was reduced by correcting for spatial temperature gradients and restricting domains based on spatial clusters of stations. We generally found simple linear regression to be more robust than multiple linear regression for lapse rate estimation. Finally, lapse rates had lower error and uncertainty when estimated from a sample of topoclimatically self‐similar stations. Motivated by these results, we outline a set of best practices for lapse rate estimation that include using quality controlled temperature observations from as many locations as possible within the study domain, accounting for and minimizing non‐elevational sources of climatic gradients, and calculating lapse rates using simple linear regression across topoclimatically self‐similar samples of stations which are roughly 80% of the station population size. Abstract : The near‐surface temperature lapse rate is the predominant source of spatial temperature variability in mountains. In many environmental models, the lapse rate alone dictates the spatial temperature field, thereby controlling snowfall and snowmelt regimes, glacier mass balance, and species distributions. However, there is little guidance on best practices for estimating lapse rates and the uncertainty of such estimates. We evaluate the error and uncertainty in lapse rate estimates and outline a set of best practices. … (more)
- Is Part Of:
- International journal of climatology. Volume 41(2021)Supplement 1
- Journal:
- International journal of climatology
- Issue:
- Volume 41(2021)Supplement 1
- Issue Display:
- Volume 41, Issue 1 (2021)
- Year:
- 2021
- Volume:
- 41
- Issue:
- 1
- Issue Sort Value:
- 2021-0041-0001-0000
- Page Start:
- E110
- Page End:
- E125
- Publication Date:
- 2020-06-08
- Subjects:
- climate -- elevation‐dependent warming -- error -- lapse rate -- linear regression -- temperature -- uncertainty
Climatology -- Periodicals
Climat -- Périodiques
Climatologie -- Périodiques
551.605 - Journal URLs:
- http://onlinelibrary.wiley.com/ ↗
- DOI:
- 10.1002/joc.6668 ↗
- Languages:
- English
- ISSNs:
- 0899-8418
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 4542.168000
British Library DSC - BLDSS-3PM
British Library STI - ELD Digital store - Ingest File:
- 15715.xml