I: Remote spectroscopic measurements of atmospheric HDO/H_2O and column CO_2. II: Interannual variations of the earth's reflectance
The theme of this thesis is to apply remote sensing data on problems concerning the climate system. It is grouped into two parts. Part I (Chapters 1, 2) is devoted to spectroscopic measurements of HDO, H2O and column CO2, and Part II (Chapters 3-5) is devoted to variations in the Earth's reflec...
| Main Author: | |
|---|---|
| Format: | Thesis |
| Language: | English |
| Published: |
California Institute of Technology
2003
|
| Subjects: | |
| Online Access: | https://dx.doi.org/10.7907/q9tp-rr97 https://resolver.caltech.edu/CaltechETD:etd-06022003-114148 |
| Summary: | The theme of this thesis is to apply remote sensing data on problems concerning the climate system. It is grouped into two parts. Part I (Chapters 1, 2) is devoted to spectroscopic measurements of HDO, H2O and column CO2, and Part II (Chapters 3-5) is devoted to variations in the Earth's reflectance. In Chapter 1, we derive the first simultaneous measurements of HDO and H2O in the tropical upper troposphere and lower stratosphere. This is made possible by extending the retrievals of the Atlas-3 Atmospheric Trace Molecule Spectroscopy (ATMOS) data deeper into the troposphere. The derived HDO/H2O ratio demonstrates that convection has a major influence on the moisture budget and the dehydration processes in this region. The objective of Chapter 2 is to determine the precision to which column averaged CO2 volume mixing ratio (VMR) can be measured by near-infrared (NIR) spectrometry of reflected sun light. The key idea in this study is the simultaneous use of the CO2 (1.58-μm and 2.06-μm) and O2 (0.76-?m) bands. This approach allows small changes in the spectrum arising from variations of column CO2 VMR to be distinguished from those arising from variations of other atmospheric/surface parameters. Using prototype retrieval simulations based on a practical satellite instrument design, we show that the 3-band, high-resolution, spectrometric approach using NIR reflected sunlight has the potential for highly accurate column CO2 VMR measurements. In Chapters 3-5, we examine the interannual variations in the Earth's reflectance. Chapter 3 introduces the Nimbus-7 TOMS reflectance measurements and provides an overview on the interannual variability of the Earth's reflectance. Variations in the globally averaged reflectance are also used to examine a postulated cosmic ray-cloud-climate connection. In Chapter 4, we relate interannual reflectance variations over the summertime polar icy areas to variations in the microwave-derived sea ice concentration. The results provide independent confirmation on sea ice variations observed by microwave instruments, and quantify the role of clouds in shielding the reflectance effect of sea ice variations. An interesting hemispheric asymmetry is found: a 1% change in the sea ice concentration is related to a significantly larger reflectance change in the Antarctic than in the Arctic icy areas. Chapter 5 is devoted to interannual reflectance variations over the northern midlatitude oceans. We find that interannual reflectance variations in these regions are, to a large extent, related to variations in the large scale circulation, mostly through variations in the storms tracks. The findings in this chapter suggest that the response of clouds to climate change may be better viewed from a large-scale circulation perspective, other than a purely thermodynamic one (such as in the cloud-temperature relations), a stand many previous investigations have taken. |
|---|