Your search keyword '"Chaffey, P. M."' showing total 4 results

1. The Geographic Distribution of Boulder Halo Craters at Mid-to-High Latitudes on Mars

Author

Rader, L. X, Fassett, C. I, Levy, J. S, King, I. R, Chaffey, P. M, Wagoner, C. M, Hanlon, A. E, Watters, J. L, Kreslavsky, M. A, Holt, J. W, and Dyar, M. D

Subjects

Lunar And Planetary Science And Exploration

Abstract

Extensive evidence exists for ground ice at mid-to-high latitudes on Mars, including results from neutron spectroscopy [1-3], thermal properties [4-5], geomorphology [e.g., 6-9], and the in situ observations of Mars Phoenix [10]. This ground ice has been hypothesized to be emplaced diffusively and fill pores [11], or to have accumulated by ice and dust deposition that draped or mantled the terrain [7, 12]. These two processes are not mutually exclusive; both potentially have occurred on Mars [5]. One of the landforms found in areas where ground ice is common on Mars are boulder halo craters [e.g., 13-15] (Figure 1), which are topographically muted impact craters that are filled by ice-rich regolith. They are outlined by boulders that trace a circular outline of the original crater rim. Boulder halos generally have distinctly higher boulder densities than the surrounding background plains and have few boulders in their interiors. The mechanism of boulder halo crater formation is somewhat uncertain. Our working model is that an impact event occurs with sufficient size to excavate to a depth greater than the boulder-poor, ice-rich soils. Excavated boulders are deposited around the crater's rim and in its proximal ejecta. Quite rapidly [14], the crater becomes infilled by icy soil. Rather than being buried, boulders in the halo remain at the surface, perhaps be-cause they 'float' relative to finer-grained materials [14, 16]. Regardless of the details of this process, the life-time of boulders at the surface is much greater than the timescale needed to remove most of the craters' topography. Physical weathering of rocks must be greatly out-paced by crater infilling (the opposite of what is typical, e.g., on the Moon [17]). The rapidity of this infilling is easiest to understand if icy mantling material is deposited and accumulates, rather than simply being added by pore filling of soils. If this model is correct, boulder halos only form when they excavate rock-producing materials from beneath the upper surface. Thus, the distribution and size of craters that result in boulders halos may provide in-sight into the thickness of the ice-rich surface layer in different locations. Note that this thickness is necessarily that of the ice-rich layer at the time of impact, not at present. This study is an initial survey of boulder halo crater locations in the 50deg to 80degN and 50deg to 80degS latitude bands on Mars.

Published

2017

2. Distribution and Characteristics of Boulder Halos at High Latitudes on Mars: Ground Ice and Surface Processes Drive Surface Reworking

Author

Levy, J. S., primary, Fassett, C. I., additional, Rader, L. X., additional, King, I. R., additional, Chaffey, P. M., additional, Wagoner, C. M., additional, Hanlon, A. E., additional, Watters, J. L., additional, Kreslavsky, M. A., additional, Holt, J. W., additional, Russell, A. T., additional, and Dyar, M. D., additional

Published

2018

3. GEOGRAPHIC DISTRIBUTION OF BOULDER HALO CRATERS AT MID-TO-HIGH LATITUDES ON MARS.

Author

Rader, L. X., Fassett, C. I., Levy, J. S., King, I. R., Chaffey, P. M., Wagoner, C. M., Hanlon, A. E., Watters, J. L., Kreslavsky, M. A., Holt, J. W., and Dyar, M. D.

Subjects

MARTIAN craters, MARTIAN geomorphology, MARTIAN exploration

Published

2017

4. Radon and health -- an update

Author

Chaffey, Caroline M. and Bowie, Cameron

Abstract

Background The National Radiological Protection Board (NRPB) estimated in 1990 that radon causes 5 percent of lung cancer in the United Kingdom. The estimate was not based on direct evidence. Since then a number of epidemiological studies have been reported. In addition, various policies have been formulated and some implemented, including the mounting of public campaigns to reduce radon in houses in parts of the United Kingdom. Methods A review of the scientific literature, policy documents and results of the campaigns has been undertaken. Results New data on miners support previous evidence that radon, at the levels found in mines, does cause lung cancer. The one study to add to the two previous case control studies looking at domestic radon tips the scales slightly towards radon being incriminated in homes as well. The effect of smoking, a multiplicative or additive risk with radon, is still unclear. Radon can be calculated to cause up to 383 lung cancer deaths per year in the five currently designated ‘radon affected’ areas. Approximately 287 of these deaths will be in cigarette smokers, and the most effective way for smokers exposed to radon to reduce their lung cancer risk is to stop smoking. Conclusion Evidence of the risk from residential radon is still insufficient to justify the current NRPB advice. If it were, a much more effective radon campaign would be needed. Such a campaign would concentrate on reducing lung cancer in people by tackling both radon exposure and cigarette smoking, rather than simply reducing radon in houses.

Published

1994