audit algoritma rtp stabilitas visual engine pg soft evaluasi gameplay mahjong ways pg soft pola sesi analisis mahjong ways pragmatic play respons sistem harian strategi analitik sistem rtp game digital modern kalkulasi peluang logika engine mahjong ways 2 pola wild bandito rtp live mahjong wins pola scatter wild logika scatter hitam mahjong wins analisis algoritma mahjong ways 2 dinamika frame emas mahjong ways misteri frekuensi scatter hitam komparatif mahjong wins vs ways navigasi sesi stabil mahjong ways transformasi intensitas tumble mahjong probabilitas scatter hitam 2026 pengaruh latensi server mahjong ways evaluasi mekanik mahjong wins aws analisis jam hoki rtp olympus aws era multiplier turbo starlight olympus aws fase transisi mahjong pgsoft algoritma aws komputasi data rtp mahjong ways aws mitos fakta jam hoki olympus aws momentum scatter merah mahjong ways aws rekapitulasi data log mahjong ways aws rotasi fitur captains bounty analisis aws strategi transparan rtp starlight princess aws visual turbo lucky neko starlight 256 257 258 259 260 261 262 263 264 265 e5 peran strategis rtp live evolusi online e5 pola mahjong wins terlihat mengandung scatter e5 rahasia alur simbol mahjong wins e5 rahasia mahjong simbol scatter mahjong e5 rtp live pilar penting kasino online e5 teknik cerdas pola algoritma waktu aws algoritma mahjong ways fluktuasi simbol teknis aws cara ukur efisiensi pola mahjong aws integrasi otomatis manual mahjong ways aws kalibrasi strategi mahjong wild rtp gates olympus aws kalkulasi rtp mahjong wins tiga teknis aws observasi teknis simbol mahjong wins aws pola trik rtp mahjong ways aws strategi awet mahjong black scatter aws tren dominasi fitur black scatter aws trik pola naga emas mahjong analisis algoritma pola mahjong ways 2026 teknik baca grafik volatilitas pragmatic sinkronisasi jam main analis profesional bedah mekanik wild bounty showdown framework manajemen risiko sesi panjang psikologi fitur tumble pergerakan simbol dialektika rtp vs hit rate digital studi kasus starlight princess 1000 masa depan algoritma hiburan digital 2026 audit mandiri evaluasi strategi bermain analisis mekanik scatter hitam mahjong wins dinamika pengali mahjong ways 2 sinyal transisi sesi mahjong wins struktur probabilitas mahjong ways evolusi engine scatter hitam 2026 aws algoritma fortune tiger pola presentatif platform aws epistemologi mahjong ways dua intuisi algoritma aws keamanan jaringan rtp fortune olympus ekosistem terkini aws perilaku pengguna komunitas mahjong wins retensi aktif aws rtp live mahjong ways pola komunitas hari ini aws rtp tertinggi mahjong ways premium peluang presisi aws sinyal balikan mahjong ways pola rahasia aws transformasi big bass bonanza sistem realtime gameplay aws update berkala gates olympus rtp scatter akurasi aws validitas data rtp mahjong ways transparansi global teknologi provably fair keamanan digital update android performa game mobile analisis matematika bonus hunter psikologi live streaming game online rahasia hemat kuota game pg soft fenomena gamer fatigue digital integrasi blockchain gaming 2026 tren visual mitologi game asia proteksi ganda akun game 2026 regulasi game online internasional aws data rtp live mahjong ways dua strategi malam aws fenomena selayar mahjong ways ritme interaksi akurat aws jembatan algoritma roulette rtp mahjong ways wildwest aws keabsahan informasi kinerja keterbukaan mahjong sistem global aws logika algoritma rtp simbol wild pg soft caishen wins terbaru aws metode baccarat mahjong ways rtp live akurat aws observasi lapangan rtp mahjong wins komunitas focus aws penyebaran simbol mahjong ways struktur presisi terbaca aws perilaku kolektif anggaran pergerakan nilai gates terkendali aws teknologi keadilan rtp live gates olympus transparansi aws pemanfaatan informasi kuantitatif mahjong ways perspektif objektif aws pendekatan global inovasi fitur gates olympus pasar aws pendekatan interpretatif mahjong fortuna pola interaksi mendalam aws penyesuaian strategi mahjong wild deluxe gates olympus presisi aws perhitungan presisi mahjong wins dinamika sistem terukur aws rahasia pola simbol mahjong ways aws sintesis ilmu gerak perhitungan mahjong wildwest terintegrasi aws sistem teknologi modern integritas gates olympus transparansi aws statistik terapan mahjong ways keragaman ikon terbaca aws taktik eskalasi modal baccarat pola mahjong ways 2 pg soft slot thailand slot gacor/ https://www.thewayofthespirit.com/contact/ magic134 STC76 https://ampabc1131.com/ https://www.abc1131.it.com/ hksbet pondok88 mpo slot asiaklub macauklub pondok88 garuda76 heylink macauklub heylink asiaklub heylink hksbet kapten76 heylink garuda76 heylink pondok88 heylink timpondok88 heylink mpoxo rawit303 viral asiaklub viral macauklub viral garuda76 viral pondok88 ASLI777 sakura76 baru rtp mpoxo

Science Report – July 25th

 In Science Report
0

REGOLITH-LANDFORM UNITS AT HAUGHTON CRATER

Jonathan Clarke

WHAT IS REGOLITH?

“Regolith” is a general term used to refer to all weathered earth surface materials extending from the interface with unweathered bedrock at depth to the surface (Eggleton 2001). It includes in situ weathered material derived directly from the underlying bedrock, and transported material derived from both bedrock and other regolith materials, and in many ways is similar in its usage to “surficial material”. Integrated regolith studies are relatively new (Ollier and Pain 1996, Eggleton and Taylor 2001) but regolith materials have been studied in a number of disciplines for some time. These disciplines include pedology, geomorphology and aspects of sedimentology, but rarely traditional geology. Regolith Regolith is very closely associated with landforms, which makes a landscape approach to regolith mapping most appropriate6. Landforms and regolith are formed by essentially the same groups of processes, and once the inter-relationships between regolith and landforms are understood, landforms can be used to predict regolith patterns. Thus landforms are used as a proxy for the largely hidden regolith. This means understanding the dynamics of the present landscape. It also means understanding the dynamics under which relict landforms and regolith materials formed.

REGOLITH-LANDFORM MAPPING

Regolith-landform mapping is an approach to describing the earth’s surface in terms of both landforms and the surface materials, whether of transported material, weathered rocks, duricrust, or fresh bedrock. The techniques of regolith landform mapping have been developed in Australia (Pain et al., 2007, Pain 2008), and have proved an important part of terrestrial field study of surface materials, landscape, biota, and hydrogeology. It is also an essential platform on which to base more specific applications, such as civil engineering, hydrology, resource extraction, landscape ecology, or geophysical and geochemical research. Regolith-landform mapping can be readily applied to the regional to the site scale.  The method can also be applied in Mars analogue environments and to the surface of that planet (Clarke and Pain 2004).  Regolith-landform mapping has been developed largely in temperate, arid, and tropical environments, one of my aims while at FMARS is to extend the technique to cold climate environments, building on experience gained in Ladakh in the Karakoram in NW India in 2016.  Improved mapping in such environments is especially relevant to characterizing sites on Mars.

METHODOLOGY

On arriving at a site a reconnaissance of the area gives a good idea of the general features of the landscape, and allows you to place the different regolith materials in context. It also allows you to check the general relationships between regolith and geology. Observations of the landscape (in its broadest sense) can give a lot of detail that is useful for explanations of the landscape – its origins, active and relict geomorphic and weathering processes, and any information that will allow extrapolation to areas you will not be able to visit. In most cases it is possible to extrapolate your observations from accessible areas into areas that cannot be reached. Wherever possible, use riverbanks or other exposures for your observations of rock types and regolith.

EXAMPLE

An example of regolith-landform mapping in a cold climate is shown in Figures 1 and 1.  Both are from the Ladakh region, using public available data. Figure 1 is a map of an area, and Figure 2

Figure 1 shows an interpreted ground level image of a steep, glacier headed valley, Figure 2 is an interpeted Google Earth image of the same area.  The units consistent in each Figure.

Each unit consists of regolith defined by a single landform and are homogeneous composition at the scale of mapping.  Regolith landform units are characterised by three properties: a landform descriptor in lower case letters forming a prefix, a regolith material descriptor in upper case letters with lower case letters in brackets to describe intersitial ices, salts and carbonates (if present), and a numerical modifier for periglacial modification (if present) as a suffix. Each descriptor is unique.

Figure 1. Site-scale regolith-landform units mapped onto a ground level photograph from Phyang glacier terminus, Ladakh (source image http://www.panoramio.com/photo/33652395).

The units in Figures 1 and 2 are as follows:

  • gvfPM = glacial valley floor, polymict materials
  • gvsPM = glacial valley sid,e polymict materials
  • glGLI = glacier, glacial ice
  • lmPM = lateral moraine, polymict materials
  • knUN = knob, undifferentiated materials
  • rgPM(i) = rock glacier, polymict materials, ice cemented
  • speSN = snow patch, seasonal snow
  • taPM = talus apron, polymict materials
  • tcPM = talus cone, polymict materials
  • tmPM = terminal moraine, polymict materials

Figure 2.  Regolith-landform map of the Phyang glacier in Ladakh.   Location 34° 17′ 33.66″ N  77° 33′ 12.69″ E. 

Figure 3. Hierarchical networks of sorted stone polygons on the slopes of Haughton crater.  Larhe rocks define larger polygons, smaller polygons are defined by smaller rocks within the larger polygons.  Features such as these are the focus of study by Paul Knightly on this expedition

APPLICATION

This methodology will be used to characterize the regolith landform units of specific sites at Haughton Crater from data collected during our expedition and building on earlier work in the area such as that of Lacelle et al. (2008) on the polar desert landscape of Haughton crater and Dyke (2001) on regional mapping of the surficial geology.  Examples of some of the local regolith landscape elements are shown in figures 3 and 4.

Figure 4.  Frost shattered dolostones reworked into block streams for many of the steeper slopes in Haughton crater. Relict snow and ice patches persists well into summer and alluvial deposits mantle valley floors.

REFERENCES

Clarke, J. D. A. and Pain, C. F.  2004.  From Utah to Mars: regolith-landform mapping and its application.  In Cockell, C. S. (ed.) Mars Expedition Planning.  American Astronautical Society Science and Technology Series, 107: 131-160.

Dyke, A. S. 2001. Surficial geology, western Devon Island, Nunavut.  Geological Survey of Canada Map 1972A, scale 1:250,000.

Eggleton, R.A. (compiler) 2001. Regolith Terminology. Cooperative Research Centre for Landscape Evolution and Mineral Exploration, Perth/Canberra, 375p.

Eggleton, R. A. and Taylor, G. 2001. Regolith geology and geomorphology. John Wiley & Sons.

Lacelle, D., Juneau, V., Pellarin, A., Lauriol, B., and Clark, I. D. 2008.  Weathering regime and geochemical conditions in a polar desert environment, Haughton impact structure region, Devon Island, Canada.  Canadian Journal of Earth Sciences 45, 1139-1157.

Ollier, C. D. and Pain, C. F. 1996. Regolith, Soils and Landforms. Chichester: Wiley.

Pain, C.F. 2008. Field Guide for Describing Regolith and Landforms CRC LEME, c/o CSIRO Exploration and Mining, PO Box 1130, Bentley WA 6102, Australia, 94pp.

 

Science Report – July 23rdScience Report
Science Report – August 4thScience Report