modern arctic podocopid ostracode database · (1977) and from penney (1989). this report describes...
TRANSCRIPT
DEPARTMENT OF THE INTERIOR U.S. GEOLOGICAL SURVEY
Modern Arctic Podocopid Ostracode Database
byThomas M. Cronin1 , William M. Briggs, Jr. 2 , Elisabeth M. Brouwers 3 , Robin C. Whatley4 ,
Adrian Wood4 , and Mathew A. Cotton5
Open-File Report 91-385
This report is preliminary and has not been reviewed for conformity with U.S. Geological Survey editorial standards and stratigraphic nomenclature.
1U.S. Geological Survey, Reston, Virginia 22092; Institute of Arctic and Alpine Research, University of Colorado, Boulder, Colorado 80309-0450; 3U.S. Geological Survey, Denver, Colorado 80225; ^Institute of Earth Studies, University College, Aberystwyth, Wales, United Kingdom; 5Field Museum of Natural History, Chicago, Illinois 60605-9410
INTRODUCTION
Ostracodes form a group of small, benthic crustaceans with a bivalved calcareous carapace that is readily fossilized. Ostracodes respond to ambient aquatic conditions and are especially valuable in paleoenvironmental reconstructions. Marine ostracodes are useful in determining water mass characteristics because of the sensitivity of species to environmental parameters such as water temperature, dissolved oxygen, and salinity. Until recently, however, most attempts to apply ostracodes to paleoceanographic problems have been hampered by inconsistent taxonomy, limited analysis of modern material, and qualitative methodology.
Recent studies have developed large sample data bases for modern shallow water marine ostracodes from the western North Atlantic (Cronin and Dowsett, 1990) and for deep water environments from the Atlantic (Dingle and Lord, 1990) which are suitable for application to large scale paleoceanographic problems. This report describes a new data base of modern ostracode species that is being developed for application to paleoceanographic conditions of the Arctic Ocean and surrounding high latitude seas.
The Neogene paleoceanographic history of the Arctic Ocean and adjacent high latitude seas is poorly known, in part because Arctic planktic foraminifer assemblages are absent in shallow water Neogene-Quaternary deposits and absent or monospecific in the few available Arctic Ocean cores. Ostracodes, in contrast, are common and often diverse in shallow (McDougall and others, 1986; Repenning and others, 1987; Brouwers and others, 1991) and deep water (Joy and Clark, 1977; Clark and others, 1990) Neogene and Quaternary deposits, and many species are restricted to specific environments and distinct water masses. In order to develop a standardized data base of ostracode species abundances and the zoogeographic and bathymetric distribution of species in the Arctic Ocean and surrounding seas, each of us assembled and re-studied the modern ostracode samples available in our collections to produce a Modern Arctic Ostracode Database (MAOD). We are including in MAOD published data from Joy and Clark (1977) and from Penney (1989). This report describes the contents of the MAOD for samples from shallow water environments of Northern Hemisphere high latitudes (Figure 1).
MATERIALS AND METHODS
The material for the MAOD comes from a number of sources of modern samples that were collected over the last 60 years, with most of the samples taken in the last 20 years. MAOD is divided into two Microsoft Macintosh EXCEL files: one file contains latitude, longitude, water depth, and other locality information (the LATLONG file), and the second file contains species occurrences, or counts (the SPOC file). Appendices 1 and 2 consist of printouts of the LATLONG and SPOC files, respectively.
Column A of Appendix 1 gives the sample name and/or sample number. Column B denotes the summer bottom temperature for the locality, which was obtained from two types of sources: one source consists of unpublished oceanographic parameters that were measured in the region or actually at the sample location (items 3, 11, and 15 in Table 1), and a second source consists of physical oceanographic data from 22 published references given in Table 1. Column I
denotes the specific source of temperature given for a locality. Table I gives the full citation for the 22 published references. Summer bottom water temperatures (°C) were obtained by identifying the temperature for the warmest time of the year, usually August, at a location and water depth close to the ostracode sample. In some cases, water temperature estimates were derived from multi-year averages, and in other cases only a single summer's values were used. In all cases, an attempt was made to obtain the most up-to-date water temperature estimate available for a sample location.
Column C in Appendix 1 gives the general region for the sample, and columns D and E give latitude (in degrees north) and longitude (in degrees; negative numbers denote the Western Hemisphere and positive numbers denote the Eastern Hemisphere), respectively. Column F provides the sample locality water depth in meters.
Most of the samples that we examined were originally collected as part of biological and/or sedimentological sampling programs on oceanographic cruises. Column 6 in Appendix 1 gives the source of the samples, which in turn are keyed to Table 2, which gives the cruise name and number and/or a reference in which sampling methods and cruise data are given. Column H gives the location of the author responsible for the sample, which in most cases is also the location of the micropaleontological slide containing the ostracodes from the sample (A - Aberystwyth, B = Boulder; D = Denver; R = Reston; O = other).
The 550 samples studied herein (329 samples in the MAOD SPOC file) were obtained from a wide variety of sampling programs for which there were thousands of samples available. We include in MAOD only those samples for which there was an adequate representation of ostracode population structure. A qualitative assessment of species populations based on the presence of the last two to three molt stages (see Whatley, 1983; Brouwers, 1988) or the more obvious presence of soft parts allowed us to determine that no samples were included in MAOD that show signs of major transport or reworking of fossil specimens.
MAOD SPECIES OCCURRENCES
Of the total 550 samples in the MAOD LATLONG file, we have identified the ostracode species from 329 shallow water samples, and we present the raw occurrence data (counts of individuals) for the SPOC file in Appendix 2. A total of 100 taxonomic categories (generally species) were tabulated, of which we used 99 categories in this report, and these categories are identified in Table 3 (the categories include "other" and "indeterminate"). The MAOD SPOC file has a total of 82,152 ostracode specimens. The file provides ample zoogeographical and ecological information for our quantitative analyses of Neogene and Quaternary paleoenvironments for high latitude deposits. In the future, the SPOC file will be expanded to include species occurrences in intermediate and deep water Arctic environments, and we are adding new shallow water samples from new areas as well.
TAXONOMIC NOTES
There is general consensus among the five authors and, indeed, among most ostracode taxonomists having experience in Arctic assemblages, about the identification of most shallow water high latitude species. This is due mainly
to the detailed taxonomic studies using scanning electron photomicrographs that have been published in the last 15 years (Neale and Howe, 1975; Whatley and Masson, 1979; McDougall and others, 1982; Whatley, 1982; Cronin, 1988; Penney, 1989) and others. Brief taxonomic notes about several of the ostracode taxa are given below.
Acanthocythereis dunelmensis. Two morphotypea are present in our data set, a large form and a small form. The two forms are lumped into one species for this study. A number of authors have recognized the two morphologies (Elofson, 1941; Athersuch and others, 1989), but they are not yet consistently differentiated and described.
Cluthia cluthae. A second species of Cluthia is suggested from the samples examined from Chesterfield Inlet, Hudson Bay.
Cytheromorpha macchesneyi. The relationship between Pteroloxa and C. macchesneyj. should be examined in detail, as the general morphology and ecology of the two species suggests that they are congeneric. Gradational morphological variation in carapace ornament has been observed in C. macchesneyi between shallow and deeper water populations. The C. macchesneyi populations appear to intergrade with populations of Pteroloxa.
Cytheropteron spp. This is a diverse and generally well understood genus that is very common in high latitude temperate to frigid environments. Some additional work is required on the relationships between true arctic populations and related species or subspecies that live in subarctic and cold temperate areas.
Elofsonella concinna group. Abundant, well-preserved populations from Chesterfield Inlet show that there are two distinct species of E. concinna: Elofsonella concinna (called E. concinna concinna in the literature by some authors) and Elofsonella neoconcinna (called B. concinna neoconcinna in the published literature by some authors).
Finmarchinella angulata. This taxon is morphologically very closely related to F. japonica, as noted by Cronin and Ikeya (1987).
Semicytherura spp. This genus needs detailed study of several of the species complexes, particularly the relationship within the 5. affinis f S. mainensis, and S. undata species groups.
Other. This category lumps together species of Microcythere, Cytherois, Paracytherois, Sclerochilus, and myodocopids.
ACKNOWLEDGEMENTS
Assembling this large data base required the cooperation and assistance of many colleagues to whom we are greatly indebted. Among them, thanks are due to: B.R. Pelletier, G. Vilks, F.J.E. Wagner, and A. Sherin of the Geological Survey of Canada and E. Reimnitz, P.W. Barnes, E.W. Kempera, and J. Trumbull of the U.S.
Geological Survey for locality information and sediment samples from the Beaufort Sea; W.P. Budgell, D.J. Brooks, N. Watson, and N. Freeman of the Fisheries and Oceans, Canada, the officers and crew of the M/V Petrel V for their cooperation in the 1978 oceanographic survey of Chesterfield Inlet, and L.D. Delorme of the Canada Centre for Inland Waters, Burlington, Ontario for help on the Chesterfield Inlet material; G.F. Rogers of the University of Guelph for salinity and temperature data; J.A. Westgate of Scarborough College and J.T. Andrews and R.H. Kihl of the University of Colorado for laboratory facilities for W.M. Briggs Jr.; Q.A. Siddiqui and U.M. Grigg of St. Mary's University for taxonomic discussions; I.J. Ralph, J.E. Whittaker (British Museum of Natural History), D.R. Wall (Geological Survey of Canada) and A. Moguilevsky (University of Aberystwyth) for access to samples; M.A. Buzas of the Smithsonian Institution for the loan of Bartlett cruise samples; C. Hans Nelson of the U.S. Geological Survey for sediment samples from Norton Sound; J.V. Gardner and W.E. Dean of the U.S. Geological Survey for sediment samples from the Pribilof Islands; B.F. Molnia of the U.S. Geological Survey for sediment samples from the Gulf of Alaska; Paul Carlson of the U.S. Geological Survey for sediment samples from Kodiak Shelf; Jackie Grebmeier of the University of Tennessee for Alpha-Helix samples from the Bering Sea; David Penney of the University of Aarhus, Denmark for ostracode data from Greenland; A. Loeblich of the University of California at Los Angeles and Ruth Todd for information on the Bartlett and Wort/wind samples; and David Clark of the University of Wisconsin for helpful discussion on deep Arctic core samples.
This work was carried out as part of the USGS PRISM (Pliocene Research, Interpretation and Synoptic Mapping) Project. Financial assistance for W.M. Briggs Jr. included grants to J.C. Ritchie (Scarborough College) from Energy, Mines and Resources, Canada and Fisheries and Oceans, Canada, National Science Foundation Grant DPP 81-06802 to Briggs, and a 1991 U.S. Geological Survey grant from the Global Climate Change Program to Briggs.
REFERENCES
At her such, J., Home, D.J., and Whittaker, J.E., 1989, Marine and brackishwater ostracodes (Superfamilies Cypridacea and Cytheracea), in Kermack,D.M. and Barnes, R.S.K., eds., Synopses of the British Fauna (New Series)no. 43: E.J. Brill, 343 p.
Brouwers, E.M., 1988, Sediment transport detected from the analysis of ostracodpopulation structure: an example from the Alaskan continental shelf, in DeDeckker, P., Colin, J.-P., and Peypouquet, J.-P., eds., Ostracoda in theEarth Sciences: Elsevier, p. 231-244.
Brouwers, E.M., Jorgensen, N.O., and Cronin, T.M., 1991, Climatic significanceof the ostracode fauna from the Pliocene Kap Kobenhavn Formation, northGreenland: Micropaleontology, v. 37, no. 3.
Clark, D.L., Chern, L.A., Hogler, J.A., Mennicke, C.M., and Atkins, E.D., 1990,Late Neogene climate evolution of the central Arctic Ocean: MarineGeology, v. 93, p. 69-94.
Cronin, T.M., 1988, Paleozoogeography of postglacial Ostracoda from northeasternNorth America, in Gadd, N.R., ed., The Late Quaternary Development of theChamplain Sea Basin: Geological Association of Canada, Special Paper 35,p. 125-144.
Cronin, T.M. and Ikeya, N., 1987, The Omma-Manganji ostracod fauna (Plio-Pleistocene) of Japan and the zoogeography of circumpolar species:Journal of Micropalaeontology, v. 6, p. 65-68.
Cronin, T.M. and Dowsett, H.J., 1990, A quantitative micropaleontologic methodfor shallow marine paleoclimatology: application to Pliocene deposits ofthe western North Atlantic Ocean: Marine Micropaleontology, v. 16, p.117-147.
Dingle, R.V. and Lord, A.R., 1990, Benthic ostracods and deep water-masses inthe Atlantic Ocean: Palaeogeography, Palaeoclimatology, Palaeoecology, v.80, p. 213-235.
Elofson, O., 1941, Zur kenntnis der marinen Ostracoden Schwedens mit besondererberucksichtigung des Skageraks: Zool. Bidrag Uppsala, v. 19, p. 217-534.
Joy, J.A. and Clark, D.L., 1977, The distribution, ecology and systematics ofthe benthie Ostracoda of the central Arctic Ocean: Micropaleontology, v.23, p. 129-154.
McDougall, K., Brouwers, E.M., and Smith, P.A., 1986, Micropaleontology andsedimentology of the PB borehole series, Prudhoe Bay, Alaska: U.S.Geological Survey Bulletin 1598, 62 p.
Neale, J.W. and Howe, H.V., 1975, The marine Ostracoda of Russian Harbour,Novaya Zemlya and other high latitude faunas: Bulletins of AmericanPaleontology, no. 65(282), p. 381-431.
Penney, D.N., 1989, Recent shallow marine Ostracoda of the Ikerssuak(Bredefjord) District, Southwest Greenland: Journal ofMicropalaeontology, v. 8, p. 55-75.
Repenning, C.A., Brouwers, E.M., Carter, L.D., Marincovich, L., Jr., and Ager,T.A., 1987, The Beringian ancestry of Phenacomys (Rodentia: Cricetidae)and the beginning of the modern Arctic Ocean borderland biota: U.S.Geological Survey Bulletin 1687, 31 p.
Whatley, R.C., 1982, Littoral and sublittoral Ostracoda from Sisimiut, WestGreenland, in Fox, A.D. and Stoud, D.A., eds., Report of the 1979Greenland White-Fronted Goose Study Expedition to Eqalungraint Nunal, WestGreenland: University of Wales Press, p. 269-284.
Whatley, R., 1983, Some simple procedures for enhancing the use of Ostracoda inpalaeoenvironmental analysis, in Costa, L.I., ed., Palynology-Micropalaeontology: Laboratories, Equipment and Methods.: NPD Bulletin2, Oljedirektoratet, p. 129-146.
What ley, R.C. and Masson, D.C., 1979, The ostracod genus Cytheropteron from theQuaternary and Recent of Great Britain: Revista Espanola deMicropaleontologia, v. 11, p. 223-277.
Whittaker, J.E., 1981, The living Ostracoda of Christchurch Harbour, Dorset, inNeale, J.W. and Brasier, M.D., eds., Microfossils from Recent and fossilshelf seas: Ellis Horwood Limited, p. 293-303.
Table 1. Key to sources of physical oceanography data used in MAOD LATLONO file (Appendix 1, column B, and cited in column I).
1. Cronin, T.M. and Dowsett, H.J., 1990, A quantitative micropaleontologic method for shallow marine paleoclimatology: application to Pliocene deposits of the western North Atlantic: Marine Micropaleontology, v. 16, p. 117-147.
2. Prinsenberg, S.J., 1986, Salinity and temperature distributions of Hudson Bay and James Bay, in Martini, I.P., ed., Canadian Inland Seas: Elsevier Oceanography Series, v. 44, p. 163-186.
3. Unpublished data from W.M. Briggs, Jr.4. Penney, D.N., 1989, Recent shallow marine Ostracoda of the Ikerssuak
(Bredefjord) District, Southwest Greenland: Journal of Micropalaeontology, v. 8, p. 55-75.
5. Prinsenberg, S.J., 1986, On the physical oceanography of Foxe Basin, in Martini, I.P., ed., Canadian Inland Seas: Elsevier Oceanography Series, v. 44, p. 217-236.
6. Drinkwater, K.F., 1986, Physical oceanography of Hudson Strait and Ungava Bay, in Martini, I.P., ed., Canadian Inland Seas: Elsevier Oceanography Series, v. 44, p. 237-264.
7. Dietrich, G., 1969, Atlas of the Hydrography of the northern North Atlantic Ocean: Conseil International pour 1'Exploration de la Mer Service Hydrographique, Charlottenlund Slot, Danemark.
8. U.S. Navy Hydrographic Office, 1958, Oceanographic Atlas of the Polar Seas, Part II, Arctic: H.O. Publication No. 705.
9. Aagaard, K., Coachman, L.K., and Carmack, E., 1981, On the halocline of the Arctic Ocean: Deep-Sea Research, v. 28A, p. 529-545.
10. U.S. Naval Oceanography Command Detachment, 1981, U.S. Marine Climatic Atlas of the World, volume 9, World-wide Means and Standard Deviations: Washington, D.C.
11. Unpublished data summarized by Adrian Wood.12. Vilks, G., 1989, Ecology of Recent Foraminifera on the Canadian
continental shelf of the Arctic Ocean, in Herman, Y., ed., The Arctic Seas, p. 497-569: Van Nostrand Reinhold Co., New York.
13. Bourke, R.H., Newton, J.L., Paquette, R.G., and Tunnicliffe, M.D., 1987, Circulation and water masses of the East Greenland Shelf: Journal of Geophysical Research, v. 92, C7, p. 6729-6740.
14. International North Pacific Fishereis Commission, 1962, Bulletin no. 13.15. National Oceanographic and Atmospheric Administration data set for the
Beaufort Sea and Bering Sea continental shelf, Alaska (Brouwers unpublished data).
16. Fissel, D.B., Lemon, D.D., and Birch, J.R., 1981, The physical oceanography of western Baffin Bay and Lancaster Sound: Canadian Minister of Indian and Northern Affairs, Northern Affairs Program, Environmental Studies no. 25.
17. Coachman, L.K., Aagaard, K., and Tripp, R.B., 1975, Bering Strait The regional physical oceanography: University of Washington Press, Seattle, 172 p.
18. Johannessen, O.M., 1986, Brief overview of the physical oceanography, in Hurdle, B.G., ed., The Nordic Seas, p. 103-127: Springer-Verlag, New
York.19. Aagaard, K., 1984, The Beaufort Undercurrent, in Barnes, P.W., Shell,
D.M., and Reimnitz, E., eds., The Alaskan Beaufort Sea: Ecosystems and Environments, p. 47-71: Academic Press, New York.
20. Hansell, D.A., Goering, J.J., Walsh, J.J., McRoy, C.P., Coachman, L.K., and Whitledge, T.E., 1989, Summer phytoplankton production and transport along the shelf break in the Bering Sea: Continental Shelf Research, v. 9, no. 12, p. 1085-1104.
21. Walsh, J.J., McRoy, C.P., Coachman, L.K., Goering, J.J., and others, 1989, Carbon and nitrogen cycling within the Bering/Chukchi Seas: Source regions for organic matter effecting AOU demands of the Arctic Ocean: Progress in Oeanography, v. 22, no. 4, p. 277-359.
22. Codispoti, L.A. and Richards, F.A., 1968, Micronutrient distributions in the East Siberian and Laptev Seas during the summer 1963: Arctic, v. 21, p. 67-83.
23. Aagaard, K. and Coachman, L.K., 1968, The East Greenland Current north of Denmark Strait Part II: Arctic, v. 21, p. 267-290.
24. Vilks, G., Wagner, F.J.E., and Pelletier, B.R., 1979, The Holocene marine environment of the Beaufort Shelf: Geological Survey of Canada Bulletin 303, 43 p.
25. Coachman, L.K. and Aagaard, K., 1974, Physical oceanography of Arctic and Subarctic Seas, in Herman, Y., ed., Marine geology and oceanography of the Arctic Seas: Springer-Verlag, New York, p. 1-72.
Table 2. Source of ostracode samples and/or species data (see Appendix 1, column 6).
1. Ralph, I.J., 1983, Recent and late Quaternary ecology, distributions and provincialism of Ostracoda in the North Atlantic and Arctic Oceans: Ph.D. thesis, University of Keele, United Kingdom.
2. Various sources cited in Cronin and Dowsett (1990).3. R/V Discoverer cruises, 1979-1980 (DC1-79-EG and DC2-80-EG); F.R.S.
Tovnsend Cromwell cruise, 1975 (EGAL-75-KC), both to the Gulf of Alaska.4. Capt. William Bartlett cruises, 1930's-1940's, to Canadian Arctic and
Greenland (samples stored in Cushman collection, Department of Paleobiology, National Museum of Natural History).
5. Penney, D., 1989, Journal of Micropalaeontology.6. Alpha-Helix 139 cruise, 1990, Bering Strait (samples courtesy of J.
Grebmeier).7. M/V Petrel V cruise, 1978, Chesterfield Inlet, Hudson Bay.8. U.S. Coast Guard Northwind cruise, 1963 (U.S. Coast Guard Oceanographic
report no. 6; Codispoti and Richards, 1968).9. Ernest Holt cruise, 1963, Norwegian Sea.
10. H.M.S. Vidal cruise, 1955, Barents Sea.11. Bedford Institute of Oceanography Hudson cruises to Beaufort Sea and other
areas.12. U.S. Coast Guard Vorthwind cruise, 1965, to Kara and Greenland Seas.13. Ostracode samples studied by Joy and Clark (1977).14. R/V Sea Sounder cruises, 1976 and 1978 to Norton Sound, Alaska, collected
by C. Hans Nelson, U.S. Geological Survey.15. Samples from western Beaufort Sea collected by Peter Barnes and Erk
Reimnitz, U.S. Geological Survey, during 1971-1972, 1980-1982.16. Bedford Institute of Oceanography Parizeau cruises 1970-1972. O. Other sources.
Table 3. Ostracode taxonomic groups used in MAOD SPOC file, refers to Brady, Crosakey and Robertaon, 1874).
(B,C&R, 1874
11111111112
2
2
2
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
Acanthocythereia dunalmenais (Norman, 1865)
Argillo&cia conoidaa Sars, 1923
Aurila convexa - (Baird, 1850)
Baffinicythera howei Hazel, 1967
Bythocypris bosquetiana (Brady. 1866)
Bythocythare constricta Sars, 1866
Cluthia duthaa (B. C. & R.. 1874)
Cythera lutaa Mueller, 1785
Cytharatta teshekpukensis Swain, 1963
Cytheromorpha macchasneyi (Brady & Crosskey, 1871]
Cytharopteron alatum Sars, 1866
Cytharopteron angulatum Brady & Robertson, 1872
Cytharopteron arcticum Neale & Howe, 1973
Cytheropteron arcuatum B. C. 4 R., 1874
Cyttleropteron biconvexum Whalley & Masson, 1979
Cytherapteron champlainum Cronin, 1981
Cytheroptaron alaeni Cronin, 1988
Cytherapteron excavoaiatum Whalley & Masson. 1979
Cytheropteron hamatum Sars. 1866
Cytherapteron inflatum B. C. & R., 1874
Cytherapteron latissimum (Norman, 1865)
C/theropteron montrosianse B. C. & R., 1874
Cytheropteron nodosoaJatum Neale & Howe, 1973
Cytherapteron nodosum Brady, 1868
Cytheropteron paralatissimum Swain, 1963
Cythercptaron pararcticum Whatley & Masson. 1979
Cytheropteron punctatum Brady, 1868
Cytheropteron pyramidaJe Brady, 1868
Cythercpteron sedovi Lev, 1969
Cytheropteron simplex Whatley & Masson, 1979
Cytheropteron sulense Lev, 1972
Cytheropteron suzdalskyi Lev, 1972
Cytheropteron pseudomontrosiense Whatley & Masson, 1979
Cytheropteron tumefactum Lev, 1972
Cytheropteron n. sp. B see Cronin, 1988
Cytheropteron spp.
Cytherura sp.
lofsonella concinna (Jones, 1857)
Icfsanefta neoconcinna Bassiouni. 1965
'jcythere argus (Sars. 1866)
jcythera declivis (Norman, 1865)
FinmarcfiineJJa barentzovoensis (Mandelstam, 1957)
'n march inella finmarchica (Sars. 1866)
^nmardiineUa angutata (Sars. 1866)
nmarchinella logani (Brady & Crosskey. 1871)
emicythere borealis (Brady, 1868)
emicythera emarginata (Sars. 1866)
emicythera villosa Sars, 1866
amicytherjra cellulosa (Norman. 1865)
emicvtherura clathrata (Sars, 1866)
t
c
e
5
c
5
5
5
5
6
6
6
6
6
6
6
6
6
6
7
7
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
Heterocyprideis fascis (Brady 4 Norman. 1889)
Heterocyprideis sorbyana (Jones. 1857)
Hirschmannia viridis (Mueller. 1785)
Jones* simplex (Norman, 1865)
Keijia? mananensis ' (Hazel & Valentine. 1969)
Kritha gfaciaiis B. C. & R.. 1874
Loxoconcha venepidermoidea Swain, 1963
Muetterma abyssicola (Sars. 1866)
Neonasidea inflata (Norman, 1862)
Normanicythere leioderma . (Norman, 1869)
Paimenelia limicola (Norman, 1865)
Palmoconcha guttata (Norman, 1865)
Paracyprideis psaudopunctillata Swain, 1963
Paracyttteridea norvegica Neale, 1972
Paradoxostoma ensiforme Brady, 1868
Paradoxostoma spp.
Patagonacythera dubia (Brady, 1868)
Patagooacythera robusta Tabuki, 1986
Pectocythere sp.
Pontocythere alongata (Brady, 1868)
PontocytherB sp. A
Psaudotythere caudata Sars, 1866
Pteroloxa cumuloidea Swain, 1963
Pterygocythereis mucronata (Sars, 1866)
Rabiiimis mirabilis (Brady, 1868)
Rabilimis septentrionalis (Brady, 1866)
Robertsonites tubarculatus (Sars, 1866)
Roundstonia globulifera (Brady, 1868)
Sarsicytheridea bradii (Norman, 1865)
Sarsicytheridea macrolaminata (Elolson, 1939)
Sarsicytheridea punctillata (Brady, 1865)
Schuocythere sp.
Sclaroctulus contortus (Norman, 1861)
Semicytherura aff. complanata (B. C. & R., 1874)
Semicytherura affinis (Sars, 1866)
Semicytherura complanata (B. C. & R.. 1874)
Semicytherura concentrica (B. C. & R., 1874)
Semicymerura mainansis (Hazel & Valentine, 1969)
Semicytherura nigrescens (Baird, 1838)
Semicytherura rudis (Brady, 1868)
Semicymerura sella (Sars, 1866)
emicymerura spp.
emicytherura striata (Sars, 1866)
emicytherura undata (Sars, 1866)
etracytherura? sp. A
Tnaeroeythara crenulata (Sars, 1866)
estoleberis depressa Sars, 1866
ther
determinate
Figure 1. Locality map illustrating sites mentioned in this report.
10
Appendix 1. Modern Arctic Ostracode Database latitude-longitude file (MAOD LATLON6 file). Column A, sample name and/or sample number; column B, summer bottom water temperature; column C, general region of sample; column D, latitude in degrees north; column E, longitude in degrees (negative numbers denote Western Hemisphere, positive numbers denote Eastern Hemisphere); column F, water depth in meters; column G, source of sample (see Table 2); column H, location of author responsible for sample (A=Aberystwyth, B=Boulder, D=Denver f R=Reston, O=other); column I, source of water temperature. Sample numbering in Appendix 1 does not correspond to sample numbers in Appendix 2. Bold numbers in column A indicates that raw data for that sample is given in Appendix 2.
11
Appendix 1. MAOD LATLONG Rte
1234567890123456789
2021222324252627282930313233343536373839404142434445464748495051525354555657585960616263
AAW-OM1&2AW-S745
White Bear Hazel 18AW-2399AW-2839AW-2365AW-2789
AW-2905AW-2904AW-2375AW-2819AW-3143S4-76-29
GV83033*45GV83033#44
S6-77-6
LA-81 -NA-009AW-3101A
LA-81-NA-059
AW-3161AW-3154S4-76-14
GV83033*30Alaska 66AW-JH25
DC-1-79-EG-1DC2-80-EG-73
DC2-30-EG-186Bart. LT 29 Hazel 16
Bart.LT30EGAL-75-KC-53
BFM-78-1
Bcerssauk 15
HX-139NUN1Dcerssauk 5
Ikerssauk #1Dcerssauk 2Ikerssauk 4HX-139SIK7HX-139 PUNSHX-139NUN3
HX-139SLI2HX-139SIK5
HX-139VNG1
HX-139 SMI6
HU85-027-89HX-139SIK3
HX-139 SIK2
HX-139 NUN7HX-139 SMMHX-139 SLI6HX-139 SMI3
Bart LT 22
Bart. Crystal.GV82027-45
Chest Inlet 11
HX-139SMI2Bart LT 21 Hazel 12
Bart 20 LT 42 Hazel 11K1-78-BS-22
SEA-5-76-156
HU85-027-76SEA-5-76-145
B11.5129.4
10.510.511.111
10.510.510.811.7
10.55
0-1.6
4.79
10.3
911
9.73
29
9.4
121313-1
-1
13124.644
3.2554
4
4
24
1
2
04
44222
22
-1.3
Z16
200
8.8
8.8
010
cEnglish ChannelSt Georges Chn.
LabradorIrish SeaIrish SeaIrish SeaIrish SeaIrish SeaIrish SeaIrish SeaIrish SeaIrish Sea
Bering SeaLabradorLabrador
Bering SeaN.Aleutian I.Malin Sea
N.Aleutian 1.
Malin SeaMalin Sea
Bering SeaCanada
Kodiak ShelfInner HebridesGulf of AlaskaGulf of Alaska
Gulf of AlaskaUngava BayUngava Bay
Gulf of Alaska
PW SoundSW Greenland
Bering SeaSW Greenland
SW.GreenlandSW GreenlandSW Greenland
Bering Sea
Bering SeaBering Sea
Bering SeaBering Sea
Bering Sea
Bering Sea
Hudson Strait
Bering Sea
Bering SeaBering SeaBering SeaBering SeaBering Sea
Frobisher BayFrobisher Bay
Hudson BayHudson Bay
Bering SeaFrobisher BayFrobisher Bay
Norton Sound
Bering Sea
Hudson StraitNorton Sound
D50.7452.4152.7852.9753.1453.1553.5
53.5753.653.653.7653.8154.13
54.3554.3854.8
55.2955.44
55.79
55.9155.9256.2356.9
57.9257.9459.0859.46
59.5660
60.13
60.13
60.2960.8360.87
60.9360.9760.9760.9761.13
61.4261.761.83
61.93
62.02
62.33
62.4562.46
62.7362.862.8
62.8762.97
62.98
63
63.0263.09
63.1363.1763.18
63.27
63.32
63.3563.35
E-2.38-4.08
-56.12
-4.77-4.67-6.02-6.03-5.7
-5.67-6.09-5.82-7.87
-166.2
-57.5-56.93
-164.99-169.9-6.56
-163.25-7.57
-7.78-169.83-60.58
-150.96-6.24
-138.67-139.84-141.42
-68
-67.78
-146.87
-148.35-46.8-169
-46.06-46.53-46.53-46.25
-170.54
-167.83-169.23
-171.76-170.35
-175.05
-172.58
-69.59
-170.25
-170.22-169.5-171.9
-170.93-171.6-67.47
-67
-77.87-91.03
-171.35-67.75-67.83
-163.25
-165.33-73
-163.12
F1017
44
4018878124
55146
86
5513712070.555
86.6
128170.1126146
?
9077104
1326673
156
201138
1
861551
2740
5544
7955143
36444252465334
26
10555
5155146
8
17230
8
GOO2111
111
111
14
221401
01
114
20033344
3O5655556
666
6
6
611
6666664
4
27
644
14
14
1114
HAARAAAAAAAAADRRDRAR
A
ADRRADRRRR
RDOROOOOR
RR
R
RRR
R
R
RRRRR
RR
R
BRRR
D
DRD
11111
111111111111111111114
1.71
14101110
7.11111471011101010
66
10104
214
444
21
2121
2021
20
20
6.7212121202020
6,7
6.7
1.23
206.76,7
15
15
615
12
Appendix 1. MAOD LATLONG Rte
646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126
AChest. Inlet 95aCh«st. Inlet 3
Bart. LT20HazeMOChest. Inlet 2
Chest. Inlet 14Chest. Inlet 1Chest. Inlet 7Chest. Inlet 6Chest. Inlet 5Chest. Inlet 4Chest. Inlet 9S5-77-BS-29
SEA-5-75-1 69 A
Chest. Inlet 15Chest. Inlet 17Chest. Inlet 18Chest. Inlet 16Chest. Inlet 20Chest. Inlet 19SEA-5-76-125A
GV82027-67SEA 5-1 25 AHU81-045-20S5-77-BS-17
Bart. Coral harborS5-77-BS-16S5-77-BS-18
Bartlett 98Bartlett 97
S5-77-BS-27SEA-5-76-174
SEA-5-76-1 31 DAIpha-H #9Alpha-H #4
SEA-5-76-72A
Chest. Inlet 8Penney274101Northwind63 #5
Bart. 19Northwind63 46
Bart. 47Bart. 49Bart. 46
Bart. 30Bart. 33
Bart. 5Bart. 48Bart. 29Bart. 31Bart. 55
AW-37-161-51
Bart. LT34 Hazel #9North wind63 #10Nortnwind63#11AW-V6-33-78-21
North wind63 #13
AW-NNAW-62-1 60-11AW-57-328-70
AW-62-1 60-10AW 57-328-28AW-57-328-80
AC- 71- 27
B-1
1.66
01.851.97-1
1.241.2
0.67
1.09-0.5
1010
1.991.26Z040.831.46
1.3212
-1.5
11
114
10
10-0.5
0.5111111
8
88.5
-0.49
33-1
3111
1
111111
21
338
3
8788584
cHudson BayHudson Bay
Frobischer BayHudson BayHudson BayHudson BayHudson BayHudson BayHudson BayHudson BayHudson Bay
Norton SoundBering SeaHudson BayHudson BayHudson BayHudson BayHudson Bay
Hudson BayNorton SoundHudson Bay
Norton SoundBaffin Bay
Norton Sound
Hudson BayNorton SoundNorton SoundFoxe ChannelFoxe ChannelNorton SoundNorton SoundNorton Sound
AlaskaAlaska
Norton SoundHudson BayE.GreenlandChukchi Sea
Foxe Channel
Chukchi SeaCape Marti neau
Cape Marti neauCape Martineau
Hurd ChannelMelville Penin.
Hurd ChannelLyon Inlet
Hurd ChannelHurd ChannelMelville Penin.
E. Iceland
Foxe BasinChukchi SeaChukchi Sea
Norwegian Sea
Chukchi Sea
Norwegian Sea
Norwegian SeaNorwegian Sea
NE IcelandBarents sea
Norwegian Sea
Canadian Beaufort
D6037863.4
63.4263.4263.4263.4363.4663.4763.4863.4963.5163.5363.5863.5963.6163.6163.6263.6663.6863.6863.864
73.7664.0864.13
64.1564.1864.264.2
64.2264.3564.464.6
64.6
65.1365.5165.5865.99
66
66.02
66.1266.1266.12
6622
66.22662266.566.566.5
66.53
66.6
66.7267.0267.0767.15
67.3167.4
67.4867.5367.6
68.0368.24
E-90.6-90.8
-68.32-90.75-91.15-90.73-90.92-90.88-90.87-90.83-90.97
-165.73-166.09-91.25
-91.32-91.35-91.33
-91.57-91.46
-161.22-77.83
-162.4281.5
-165.48-83.07
-165.39
-165.53-76.5
-76.5-164.34
-165.01-161.85-165.5-165.5-167.6-90.95-37.18
-168.46-85
-168.71-83.7
-83.7-83.7
-83.58-84.58
-84.58
-83.5-83.83-84.83-83.88
-13.66-80.12
-168.58-169.88
12.17
-170.78
12.72
12.3511.08-10.5541.3411.16
68.5 -134.53
F5255
101749154385468
62589
27727636
821073814
25018
26018309
?25259
36177
?3456
3055
2551
25-27
5025-27
26
262625262625139
2004148120
46
120
158152
188.542145
1
G774777777771414
77777
71421411
14414
14441414
14
O
OO708
4
84
44
44444
44
O4880
8
0
91091010
O
HBR.BRBBB
BBBBBDD
BBBBB
BDRRRRR
D
DRRDDDR
RDB0R
R
R
RR
RR
RRRRRR
ARRR
AR
A
AAAAA
B
I23
6,733
23333
215153333
3310215
152
15155
515151510
101534
17
517
55
55
5555557
517177
17
10
777187
24
13
Appendix 1. MAOD LATLONG Rle
127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189
AAC- 71- 24
AW-62-160-9
AC- 71- 14
WJ69-050.825
AC- 71- 6
AC- 71- 7
Bart.CTO
HU69-050.826
AC- 71 -8
HU69-050.834
HU69-050.804AW-57-328-32
AC- 71- 3
HU69-050.827
HU69-0 50.805
HU69-050.833
PRZO 70-22-23
AC- 71- 10AW-62-160-8
HU69-050.802
81-APB-13
81-APB-12
AC- 71- 50
HU69-050.806
PRZO 70-22-49
81-APB-11
AC- 71- 31AC-71-35
HU69-050.819
HU69-050.824AC- 71-1
81-APB-36
AC- 71- 32
HU69-050.803
HU69-050.840
PRZO 70-22-74
PRZO 70-22-82
81-AER-35
AC- 71- 51
RICH 1970-22
HU69-0 50.832
AC- 71- 36
AC- 71- 38
81-AER-34
AC- 71 -53
PRZO 71 -94
81-AER-33AW-62-160-7
HU69-050.812
PRZO 70-22-90
Norttiwind63 #56
HU69-0 50.839
HU69-0 50.897
AC- 71- 52
HU69-0 50.862
81-AER-31
81-AER-32
HU69-050.814
HU69-050.818
AC- 71- 37
PRZO 70-22-94
RJCH 1970- 41
HU69-050.813
B2.5
8
3-1
1
1
2-1
1.5
0.5
-1.25
5
1.5
-1.25
-1.25-1.3
-1.25
0
8-1.3
2
2
2.5-1.5
0
2-1.3
2.6-0.5
-1
-0.3
1
2.3-1.5
0-1.5
-1
1.3
2
2.5-1
225
3
0.3
1.5-1
-1
7-1.5
-1.5
1.6-1
1.3
2
1-1
1-1.6
-1.3
2-1
-1
-1.5
cCanadian Beaufort
Norwegian SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Melville Penin.Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Barents SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Norwegian SeaCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian BeaufortCanadian Beaufort
Beaufort SeaNorwegian Sea
Canadian BeaufortCanadian Beaufort
E.Siberian SeaCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
DGflLTS
68L78
69.01
69.18
69-29
69.36
69.37
6O37
69.44
69.45
69.47
69.48
69.53
69.55
69.6
69.6
69.6
69.62
69.63
69.63
69.655
69.656
69.66
69.67
69.67
69.675
69.68
69.68
69.7
69.71
69.71
69.739
69.74
69.75
69.75
69.75
69.75
69.754
69.77
69.77
69.78
69.78
69.78
69.786
69.79
69.79
69.818
69.82
69.83
69.83
69.83
69.85
69.85
69.86
69.87
69.882
69.885
69.89
69.9
69.91
69.92
69.92
69.93
E-135.49
13.05
-136.74
-137.95
-137.08
-136.08
-81.8
-138.08
-136.52
-137.17
-138.8
43.58
-137.06
-138.2
-138.4
-137.33
-138.2
-135.87
13.2
-138.75
-141.356
-141.281
-130.57
-138.23
-136.42
-141.319
-137.07
-132.88
-139.7
-140.62
-136.13
-141.464
-135.4
-138.57
-136.62
-138.3
-136.65
-141.444
-130.17
-132.7
-137.53
-132.84
-132.07
-141.37
-129.74
-135.52
-141.259
17.63
-138.3
-136.87
165.02
-136.8
-135.33
-129.23
-133.33
-141.147
-141.242
-139.08
-139.47
-132.82
-137.1
-134.7
-138.91
F2
136
2
33
3
2
25
42
6
24
49
42
8
100
124
44
128
3
134
47
4
4
8
139
17
5
32
2
25
26
20
12.5
6
177
18
165
22
16.5
10
7
66
8
3
23
14
22
30
184
198
33
27
27
16
10
16
34
32
60
44
10
43
23
200
G9
9
0
11
0
o4
11
0
11
11
10
0
11111116
0
9
11
15
15
0
11
16
15
O
O
11110
15
0
11
11
16
16
15
O
0
11
O
o15
O
16
15
9
11
16
8
11
11
O
11
15
15
11
11
0
16
O
11
HB
A
B
B
B
B
R
B
B
B
B
A
B
B
B
B
B
B
A
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
B
A
B
B
R
B
B
B
B
B
B
B
B
B
B
B
B
1
24
7,18
24
24
24
24
5
24
24
24
24
18
24
24
24
24
24
24
7.18
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
24
7,18
24
24
8
24
24
24
24
12
12
24
24
24
24
24
24
14
Appendix 1. MAOO LATLONG Rle
190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241242243244245246247248249250251252
AHU69-050.896PRZO71-33PRZO71-37
HU69-050.838PRZO 71 -61
PR20 71-13681-APB-21
HU69-050.823AC- 71- 39
Bart. LT 27 Hazel 8HU69-050.861
PRZO 70-22-11 2PRZO 70-22-1 20
HU69-0 50.84572ABP20A81-APB-20
HU69-050.831HU69-0 50.856
AC- 71- 40
HU69-050.86381-APB-1981-APB-18AC- 71- 42
PRZO 70-22-1 11PRZO 70-22-1 24PRZO 70-22-1 25PRZO 70-22-1 26PRZO 70-22-1 30
PRZO- 72-1
HU69-0 50.86081-APB-17
Barnes 18-80Barries 19-80HU69-050.851
79-ABP-14
72-ABP-12HU69-050.817HU69-050.837
HU69-050.858PRZO 71-138
80PB2AW-62-160-3
Northwind63 «45
72-ABP-11Barries 16-80HU69-050.822HU69-050.830HU69-050.844
79-ABP-15Bames 17-80
72-AJT-26
HU69-050.809AC- 71- 43
PRZO- 72-2
Bames 22-30AC- 71- 49
71-ABP-2372-ABP-1
72-ABP-13PRZO 71 -42
Barnes 34-3072-ABP-34
HU69-050.816
B31
-1
-1.25-1.5
0-1.53-1.3
4
30.3
0-1.75-1.3-1.3
-0.350
-1.3
3.5-1.3
-0.57-0.57
20.5-1
-1.6-1.3-1.3
1-0.6
-0.43 n
1
0.05-1.2
-0.18-0.43-0.5-1.3
-0.5
-1.5
-0.18
7
0-0.18
0.3-1.4-1.3-1
-0.181.25
-1.67
0-0.5
00.051.5
1
-1.45-1.45-1.2
-1.45
10.4
cCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian BeaufortCanadian Beaufort
W Greenland
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort Sea
Beaufort SeaCanadian BeaufortCanadian Beaufort
Canadian BeaufortCanadian Beaufort
Beaufort SeaNorwegian SeaE.Siberian SeaBeaufort Sea
Beaufort SeaCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Beaufort SeaCanadian Beaufort
Canadian BeaufortCanadian Beaufort
Beaufort Sea
Canadian BeaufortBeaufort Sea
Beaufort SeaBeaufort Sea
Canadian BeaufortBeaufort Sea
Beaufort SeaCanadian Beaufort
D69.9469.9669.9669.9769.9769.9769.98969.9969.99
70
7070
7070.0170.01770.01770.0270.02
70.0270.0370.03170.056
70.0770.0870.0870.0870.0870.0870.11
70.1270.12770.1370.1370.1370.133
70.1470.14
70.14
70.1470.1470.146
70.1570.1570.158
70.1670.1770.1870.1870.18670.19
70.203
70.21
E I F-134.55 16
-132.91 21-133.43 | 23
-137
-134.74-135.79-142.518-140.26-132.05
-52.5
-132.53-138.47-137.33
-135.65
3814227
516?19
27066
28-146.417 i 905-142.522 16-137.95 109-134.95 146
-132.05 11-133.76 30-142.536 18.5-142.488 23.5
-131.2 12-138.5 296-138.3 255
-138.03 200-137.83 115-137.55 66-131.23 15.9-131.58 24
-142.5 35-146.66 4.5-147.03 5.5-134.9 37
-145.558 ! 13.5
-145.483 39-139.27 i 211
-137.26 I 47
-132.8 25-136.06 42-145.755 | 5
17.2 182175 I 37
-144.367 16
-146.09 2.5-139.88 62
-137.99 I 240-135.91-145.804-146.38
-146.5
-138.67
70.21 -131.2270.21 -131.2570.22 -147.54
70.22 -128.3670.22 -148.07
70.22 -143.4370.228 -145.570.23 -133.41
46
14
34
390
2422.9
31227
2525
3770.24 -146.03 I 1970.24 -148.533 | 99570.26 -139.21 I 451
G1116161116161511O4
1116161115151111
O111515
O16161616161611
15151511
15
151111
11
1615
9815
1511111115
15O
11
O16
15
O15151516
151511
HBBBBBBBBBR
BBBBB
BBBBBB
BBBBBBBBBBDDB
B
BBB
BBBAR
B
DB
BBBR
BB
B
BDBD
DBBDBB
124
24242424241524247,824
242424
15152424
242415152424
2424242424241515152415
15
2424
2424
15
72215
1524242415
91524
24
241524
19151524
151924
15
Appendix 1. MAOD LATLONG Flte
253254255256257258259260261262263264265266267268269270271272273274275276277278279280281282283284285286287288289290291292293294295296297298299300301302303304305306307308309310311312313314315
AAC- 71- 4571-ABP-1
79-ABP-2272-AJT-20A79-ERK-12
72-AER-151Barnes 21-80HU69-050.854
79-ABP-23Barnes 20-80HU69-050.850HU69-050.843
71-ABP-1272-AER-150
PRZO- 72- 6172-AER-149PRZO 71 -6472-ABP-26
PRZO 71 -12872-ABP-10
Bames 23-8071-ABP-13A72-ABP-25
72-AER-147Bames 26-80HU69-050.836HU69-050.815HU69-050.88672-AER-14679-ABP-27
70BS18PRZO- 72- 19PRZO- 72-18
71-ABP-2
79-ABP-2572-ABP-14
HU69-050.869PRZO 71-72
PRZO- 72- 53
71-AJT-45
AC- 71- 46
AC- 71- 48
PRZO 71-1 1671-ABP-11
71-ABP-38ABames 25-80
72-AER-94HU69-0 50.849
72-AER-8372-AER-9572-AER-99
72-AER-162
HU69-050.85372-AER-88
72-AER-10072-AER-103
HU69-050.80771-ABP-3
72-AER-10971-AJT-3480-ER-53
Barnes 27-8072-AER-72
B2.3
-1.45-1.67-1.67-1.07-0.05-0.05-1.3
-0.05
0.5-1.2-1.2
-1.32
-0.053
-0.05-1
-0.05-1.5
-0.430.5
-1.38-1.38
-1-0.3-0.3
0.3
2-1-1
-0.83-1.2
1-1.45
-0.52-1.44
-1-1.3
1.7
-1.39
2.3
1.7-1.2
-1.44-1.39
-1
-1.39-1.5
-1.39-1.39-1.39-1.39-1.2
-1.39
-1.39-1.39
0.2-1.45
-1.39
0.7-0.1
-1
-0.83
CCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortBeaufort Sea
Canadian BeaufortBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort Sea I
Canadian BeaufortCanadian Beaufort <Canadian Beaufort '
Beaufort SeaCanadian BeaufortCanadian BeaufortCanadian Beaufort '
Beaufort Sea IBeaufort Sea !Beaufort Sea IBeaufort Sea i
Canadian BeaufortBeaufort Sea !Beaufort Sea iBeaufort Sea iBeaufort Sea i
Canadian BeaufortBeaufort Sea !Beaufort Sea iBeaufort Sea i
Canadian BeaufortBeaufort Sea 'Beaufort Sea iBeaufort Sea <Beaufort Sea >Beaufort Sea :Beaufort Sea
D70.2670.2670.26670.26770.27270.27870.2870.2870.28770.2970.2970.370.3
70.30370.31
70.31670.3270.32770.3370.34270.35
70.3570.35770.35970.3670.3670.3770.3770.37470.37570.37870.3870.3970.3970.39470.470.470.4
70.4
70.4
70.41
70.41
70.4170.4270.4270.4370.4370.4370.4470.4470.4470.4470.44
70.4570.4570.45
70.4570.45
70.4670.467
70.46870.47
70.47
E I F-130.08 j 8-143.67-146.608-146.5
-146.85-147.405-147.36
2612.51i4
66.27
-134 | 45
-146.703 I 13-147.03 | 5-135.18 | 55-136.25 ! 57-146.08 I 26-147.497 | 6.5-128.34 i 8.5-147.557 | 5.8-136.33 I 59-146.5 | 17
-135.26 I 55-144.06 37-147.89 6-146.57 31
-146.6 26-147.697 6
-147.5 7.1-137.55 322-139.09 610-130.52 18-147.737 3.5-147.418 | 6-148.163 2-131.27 31.4-130.73 19.8-143.55 44-147.21 15
-145.663 I 37-133.15 *2-136.6 67
-128.6 12.2
-148.25 39-130.13
-128.79
-133.67-146.13-148.37-147.52-148.67-135.45
-148.83-148.66-148.73-148.785
-134.29
-148.9
-148.73-148.75
-138.95-143.57
7
1369333113
1.8
62
2.53.6
21.5
62
23.8
1740
45
-148.77 | 4-150
-151.75
18
2.3148.4 | 8
-148.72 I *9
G015150151515111515111115
15161516151516151515
15151111111515
016161515
1511
16
16
O
O
O16151515
151115151515
11
151515
1115
15
0151515
H
BDBBBBDBB
DBB
DBBBBBBB
DDB
B
DBBBBBBBB
DB
BBB
B
DB
B
BDDD
BBBBBB
B
BBB
B
DB
BBD
B
12415151515151524151524241515241524152415151515
15152424
241515
1524241515
15
2424
2415
24
24
2415151515
241515
1515
2415
1515
2415
1515
151515
16
Appendix 1. MAOD LATLONG File
316317318319320321322323324325326327328329330331332333334335336337338339340341342343344345346347348349350351352353354355356357358359360361362363364365366367368369370371372373374375376377378
A72-AER-85
72-AER-10472-AER-10772-AER-108
AW-EH-2
70-AER-10572-AER-10672-AER-141
HU69-050.878AC- 71- 47
PRZO71-8072-AER-165PRZO71-8472-ABP-9
72-AER-13880PB50
AW-62-160-1
HU69-0 50.842HU69-050.875HU69-050.885
80PB52Bames 47-80
80PB46
80ER5272-AER-12772-AER-12172-AER-12372-AER-122
80ER4772-AJT-40
70BS172-AER-12472-ABP-2472-AER125
PRZO-72-4471-ABP-5
72-ABP-1571-AJT-32
72-AER-70
79-ABP-3472-AER-12679-ABP-33
70BS4Barnes 58-80
79-ABP-32Bames 28-80
81-APB-24
81-APB-2570BS5
HU69-0 50.848HU69-0 50.868
80ER5571-ABP-10
72-AJT-4172-ABP-8
80ER68HU69-050.879
82-AER-1272-ABP-23
80ER69PRZO-72-4171-AJT-33
HU69-050.877
B-0.83-0.83-0.83-0.83
63.913.91-0.831.31.50.4
-0.830
0.36-1.46-0.83
70.2-1.3
0.5-0.83
-1
-0.83
20.70.70.70.7-0.1
10.70.7
-1.190.7
1.50.36
-1.42
1
1
0.70.70.70.7
10.70
-0.76-0.76
0.7-1.3-2
-0.6
-1.43
0-0.360.71.4
-1.75-0.71
-1.061.2
1-1
cBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
NorwegianSeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort Sea
Norwegian SeaCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort Sea
Canadian Beaufort
D70.4770.4770.4770.4770.4870.4870.4870.570.570.570.5
70.50470.5170.51370.517
70.51970.5370.53
70.5370.5370.53370.5470.54570.54570.55870.5670.56170.56270.56270.56770.5770.57370.57370.579
70.5870.58
70.58270.583
70.5970.593
70.59470.60570.60770.6170.617
70.62
70.62
70.6270.6370.6370.63
70.63570.64
70.64270.6570.65
70.6570.66370.66770.667
70.6770.67570.68
E-148.85
-148.72-148.77-148.783
17.45-144.72-144.72-147.927-129.38-130.18-136.61-148.32-135.54-143.45-147.818-148.173
18.38-136.67
-132.17-130.69-148.13-148.16
-148.148-151.642-149.457-149.45
-149.457-149.455-152.02
-150
-149.883-149.447-146.55-149.44
-129.41-143.63
-145.6-150
-151.96
-149.273-149.43 i-149.658 !-149.897 !-150.41 I-149.725 !-150.48 !
-148.127 I-148.146 !
-149.905 i
-135.79 I-133.48 !-152.337 !
-146.02 !
-150.5 i-143.55 I-149.287 I-129.66 I-148.297 I-146.667 i
-149.197 !
-128.53 !-150 i
-128.32
F1.57.56
4.5??5.510.2
8r^r~20
43910.56651
19.514.1193
700
6325
15.213
17.3
1.8
55.879
2.6
62.511
3612.5ia7106
378.5
1.813.5
1413.51013
ias318
1812
87
62
249
1413519.5
2224
4714.7
19.51R2
29
G15
1515151515151511
O161516151515
9111111151515
151515151515OO151515
16
15
15
O
15
151515O151515
15
15
O111115
15
O151511
1515
15
16
O11
HB
BBBA
BBBBBBBBBBBAB
BBBD
BBBBBBBBBBBB
B
D
BB
B
BBBBRBD
BB
BBBB
D
BBBBBBB
BB
B
115151515101515152424241524151515
72424242415
151515151515151515151515
24
15
1515
1515
1515151515
15
15
1515
242415
15
15151524151515
2415
24
17
Appendix 1. MAOD LATLONG File
379380381382383384385386387388389390391392393394395396397398399400401402403404405406407408409410411412413414415416417418419420421422423424425426427428429430431432433434435436437438439440441
APRZO-71-181
HU69-050.852HU69-050.884
71-ABP-69Bames 56-80
72-AJT-42Bames 66-30Bames 71-80HU89-050.847
71-ABP-3780ER73
AW-57-328-1771-ABP-9
71-ABP-3480ER78
71-ABP-5080ER78
72-ABP-18
HU69-050.874PRZO- 72- 71
PRZO- 72- 72HU69-050.841
80ER7480ER72
HU89-050.857HU69-050.867
80ER7571-ABP-8
80ER7972-AJT-3171-ABP-33
71-ABP-51AAW-57-326-91
80ER80
HU69-050.866
HU69-050.891HU69-050.846PRZO- 71- 187
82AER1172-ABP-17
71-ABP-39A
80ER77HU69-050.876
71-AJT-3580ER81
71-ABP-40B
E. of Drew Pt.Barnes 35-80
72-ABP-2271-ABP-52
HU89-050.873HU69-0 50.883
HU69-050.89082-AER-10
80PB4080PB36
72-ABP-21Barnes 38-80Bames 44-80Barnes 45-30
72-ABP-6172-ABP-43
Bames 57-80
B0
-1.5-0.5
-1.75-0.15
0-1-1
3-1.75
-1
3-1.351.95-0.3
1.92-0.3
-1.07-1
-0.75-1
-0.5-0.4
-0.4-1.5-1.7-0.4
-1.25-0.3
-0.3
Z451.34
7-0.3-1.3
-1.4
0-1.75-1.66-1.2
-1.66
asa-1.2
0.31-1.43
1.1
1
-0.21-1.48
1.1-2
-1.5
1-0.23-1.43-1.430.050.16
0.38
0.380.210.16-0.25
cCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortBeaufort SeaBeaufort SeaBarents SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort Sea
Canadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Norwegian SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortAlaska Beaufort
Beaufort SeaBeaufort Sea
N. AlaskaBeaufort SeaBeaufort SeaBeaufort Sea
Canadian BeaufortCanadian BeaufortCanadian Beaufort
Beaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort SeaBeaufort Sea
0TOM70.6070.6870.6870.7
70.70870.7170.7170.71
70.71870.723
70.7370.7370.7370.733
70.73370.741
70.747
70.7570.7570.7570.76
70.751
70.782
70.7870.787QJR70.8t
70.81570.817
70.8270.32570.8370 JO
70.83
70.83
E-135.82-134.69-130.87-148.37-152.33-150.5
-149.27-149.43-135.87-148.317-149.527
36.75-145.87
-148.02-149.97-148.8
-149.755-145.367-132.46-130.5
-130.22-137.07-149.662-149.503-134.83
-133.78-149.69-145.93
-150.035-150
-148.05-148.833
18
-150.202
-133.98
-129.8770.8* 1 -136.370.8* | -133.89
70.846
70.8570.8570.858
70.8770.8770.91
70.91
70.32
70.92
70.32570.93370.9«
70.9*
70.95
-148.302
-145.233-148.4
-149.853
-128.55-150.5
-150.305-148.37
-153.63
-150.72-146.5
-148.833-132.78-131.41
-130.06
70.952 1 -148.27870.955 -150.63570.963 -150.71370.972 -146.570J8 -150.72
70.39 -150.82
70.99 -150.7970.» -150.53370.992 -149.567
7t -151.35
F3355832263.218
2119.847033
19.2160
5638
19.5242038
3235
30.51390
17
18.77370
23.581
22234132
1712385
29864
7840
300
3627
3619.824.537
2.6
25
109375054
3243
17.59.3364
17.2?
?193216
G16
111115150151511
15151015
1515151515
1116161115
1511111515
15015151015
11
111116151515
1511
015
15
O
1515
1511
11111515151515
15
15
151515
HBBBDDBDDBBBA
DDBBBBBBBBB
BBBBDBB
DBAB
B
BBBBB
DBBBBD
R
DB
BB
BB
BBBBD
D
DB
BD
I24
2424151515151524
1515715
1515
1515
152424242415
152424151515
151515715
24
24242415
1515
1524151515
8,10
1515
1524
24241515151515
15
15
15
1515
18
Appendix 1. MAOD LATLONG File
442443444445446447448449450451452453454455456457458459460461462463464465466467468469470471472473474475476477478479480481482483484485486487488489490491492493494495496497498499500501502503504
A72-ABP-48
71-ABP-53B
71-ABP-41A
Bames 30-80HU69-050.895
HU69-050.S72
HU69-050.88282-AER-9
71-ABP-30B
72-ABP-3782-AER-8
HU69-050.S89
71-ABP-90
72-ABP-44
HU69-050.894
HU69-050.871
71-ABP-61A
72-ABP-36
72-ABP-45B
72-ABP-45A
71-ABP-43
71-ABP-60
72-ABP-58
72-ABP-35
HU69-050.S81
B | C2.4 I Beaufort Sea
0.69 ' Beaufort Sea
0.69 I Beaufort Sea
-0.29 ! Beaufort Sea
0 i Canadian Beaufort
-1 I Canadian Beaufort
-1.2 I Canadian Beaufort
0.69 Beaufort Sea
0.56 ' Beaufort Sea
0.69 ! Beaufort Sea
0.69 > Beaufort Sea
-1 .2 Canadian Beaufort
-0.67 Beaufort Sea
-1.6 Beaufort Sea
-0.3 i Canadian Beaufort
0 I Canadian Beaufort
2 ' Beaufort Sea
0.22 I Beaufort Sea
-0.98 Beaufort Sea
0.3 : Beaufort Sea
-1.5 Beaufort Sea
-1 .6 ' Beaufort Sea
-1.4 : Beaufort Sea
0.48 Beaufort Sea
-1.3 Canadian Beaufort
71-ABP-75 -1.2 Beaufort Sea
HU69-050.888
Tapkaluk PassEluitkit Pass
HU69-050.892
HU69-0 50.898
Northwind63 #50
71-ABP-93
HU69-050.SSO
HU69-050.887
71-ABP-88A
Northwind63 #5170-ABP-1
Northwind 65 #1
Northwind63 #77
Northwind63 #79
Northwind63 #71
Northwind63#130
Northwind63 #83
Northwind63 #63
Bart. LT 33 Hazel 7Bart. LT 51 Hazel 6Northwind63 #95Northwind63 #97Northwind65#13AW-57-328-46
Bart. LT 35 Hazel 5FL71
Northwind63#165Northwind63#145NorthwindSS #41
FL75Northwind63 #139Bart. LT 31 Hazel 4
Bartlett #28FL63
AW-R-1
Northwind63#143
-1 Canadian Beaufort
1 ' N. Alaska
1 ' N. Alaska
-1 i Canadian Beaufort
-1 .3 i Canadian Beaufort
-1 ' E.Siberian Sea
-0.6 1 Beaufort Sea
0.3 1 Canadian Beaufort
-0.2 ! Canadian Beaufort
-1.4 ! Beaufort Sea
-1 i E.Siberian Sea
-1.46 . Beaufort Sea
0.5 t Kara Sea-1 I E.Siberian Sea-1 ! E.Siberian Sea-1 i E.Siberian Sea
-1 .5 ' Laptev Sea-0.5 ' E.Siberian Sea-0.5 i E.Siberian Sea-1 i NE Greenland-1 iE.Green, Clavering I.
-1.5 i New Siberian I.-1.5 i New Siberian).-1 i Greenland Sea5 ! Barents Sea-1 ! E Greenland
-0.75 i Arctic Basin-1.5 i Laptev Sea-1.5 ! Laptev Sea0.5 | Kara Sea
-0.75 ! Arctic Basin-1.5 I Laptev Sea-1 ! NW Greenland0 ! NW Greenland
-0.75 ! Arctic Basin4 I Kara Sea
-1.5 ! Laptev Sea
D71
71
71
71.01
71.02
71.05
71.06
71.087
71.09
71.103
71.12
71.12
71.125
71.13
71.13
71.16
71.17
71.182
71.19
71.195
71.2
71.2
71.212
71.217
71.24
71.247
71.28
71.33
71.36
71.42
71.42
71.42
71.42
71.43
71.45
71.54
71.57
71.583
72.!8
72.4
72.83
72.33
73.57
73.7
73.7
74.07
74.25
74.44
74.5
74.8
75. T9
75.33
75.73
75.75
75.73
75.33
75.88
76.02
76.!
76.1
76.21
76.22
76.43
E-150
-148.85
-148.27
-152.2
-128.83
-132.99
-131.71
-148.267
-147.97
-148.733
-148.243
-130.3-153
-149.633
-128.99
-133.12
-149.25
-148.55
-149.633
-149.633
-148.6
-149.25
-151.067
-148.533
-131.91
-150.467
-130.63
-156.09
-156.36
-129.45
-129.46
174.95
-154.47
-132.1
-130.9
-152.92
170
-155.833
57.17
155.23
155.33
160.25
131.42
155.4
155.4
-21.75-21
142.72
140.43
-10.57
22.23-19
-140.61
120
129.87
F28
37
47
15
40
80
62
49
93
43
70
44
24
46
45
346
50
307
95
353
118
63
53
490
104
140
62
4.5
?
69
225
37
31
580
314
58
37
78
499
21
26
26
22
36
33
26
91-104
15
25
3110
64
200
3709
53
42
71.6 223
-139.05 3678
134.05 35
-68.42 46-82
68.42 ?
-142.05
62.67
3707f
129.88 32
G15
15
15
15
11
11
11
15
15
15
15
11
15
15
11
11
15
15
15
15
15
15
15
15
11
15
11
O
0
11
11
8
15
11
11
15
8
15
8
8
8
8
8
8
8
4
4
8
8
12
10
4
13
8
8
12
13
8
4
4
13
O
8
HB
B
D
D
B
B
B
B
D
B
B
B
B
B
B
B
D
B
B
B
B
D
B
B
B
B
B
R
R
B
B
R
D
B
B
D
R
B
R
R
R
R
R
R
R
R
R
R
R
R
A
R
O
R
R
R
0
R
R
R
0
A
R
I
15
15
15
15
24
24
24
15
15
15
15
24
15
15
24
24
15
15
15
15
15
15
15
15
24
15
24
10
10
24
24
22,25
15
24
24
15
22,25
15
9
22,25
22,25
22,25
22,25
22,25
22,25
7,23
7.23
22,25
22.25
7,23
7.18
7.13
25
22.25
22.25
9,12
25
8
16
16
25
10
2225
19
Appendix 1. MAOD LATLONG Rte
505506507508509510511512513514515516517518519520521522523524525526527528529530531532533534535536537538539540541542543544545546547548549550
ABart. LT 23 Hazel 3Thule, N. Sta.BayBart. N.Omenolu
Bart LT 26 Hazel 2Northwind 65 #35Northwind 65 #53Northwind 65 #77
FL96FL123
Northwind 65 #22FL95
FL142FL178
Bartlett LT52FL184FL190FL206FL201
FL191AW-CF
FL214FL198
Northwind 65 #11 7Northwind65#106Northwind 65 #110Northwind 65 #11 5
Northwind 65 #11 3Northwind65#112
FL235FL241FL24
FL284FL323FL290FL365FL319FL296
FL423
FL294
FL343FL298FL316FL306FL304FL310FL429
B000
00
00.5-0.5-0.5-0.8-0.5-0.5-0.5-1.5
-0.75-0.78-0.78-0.75-0.5-1.5
-0.78-0.750.50.50.50.50.5
0-0.78-0.78-0.78-0.75-0.75-0.75-0.75-0.75-0.75-0.5
-0.75-0.5
-0.75-0.5
-0.75-0.75-0.75-0.75
cW.GreenlandN. Greenland
N.Star Bay, Green.N.Star Bay, Green.
Greenland SeaKara SeaKara Sea
Arctic BasinArctic Basin
Greenland SeaArctic BasinArctic BasinArctic Basin
NW GreenlandArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinBarents SeaArctic BasinArctic BasinKara SeaKara SeaKara SeaKara SeaKara SeaKara Sea
Arctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic BasinArctic Basin
D76.4576.576.5576.5576.85
77.5478.0678.1478.1778.3478.3778.6178.979.579.5379.5979.6879.91
79.9379.9580.2980.3780.9781.4681.5881.59
81.681.6281.9382.1982.4683.7984.3
84.3984.4784.8884.89
84.93
84.94
85.0885.13
85.1585.4285.47
85.7386.05
E | F-70 | 24-36-69
-68.82-68.87-7.1771.6
74.65-176.06-174.5-4.2
-176.3-175.93-176.45
-65
-174.13-172.49
-170.22-171.44-174.45
50.02-159.52-172.5769.57
?34
31322
223362
136317631645135114781592
22020952810324229621717
?30213198566
97.57 | 26579.87 203
67.53 567
73 64075.33 | 421
-157.57 3809-156.94 3812-162.06 3743-145.85 2681-135.1 2674
-143.85 2262-131.37-136.04
27322016
-143.31 2217
-126.72 1532
-145.57 2234
-130.63 1753-142.85 1971
-138.23 1785
-145.21 2263-143.14 2277-142.65 2424-133.92 2215
G4
4
4
4
12
1212
13131213131341313
1313
13
01313
1212
1212
12121313131313
1313131313
13
13131313
131313
HRRRRRR
R
O0R0OOR
00000A
00RRR
RRROOOO0
O0OO
0
0
OO
00000
I161616
16109
9
252572525258
25252525
25102599999
912252525252525252525
25
25
25252525252525
20
Appendix 2. Modern Arctic Qstracode Database species occurrence file (MAOD SPOC file) . Numbers refer to number of individuals; single valve or carapace each count as one. Sample numbering in Appendix 2 does not correspond to sample numbers in Appendix 1. Note that species number 2, Acetabulosa sp., is,suppressed for this appendix because it does not occur in any of the samples presented in this report. The taxon occurs in the Arctic and will be reported in future reports.
21
App
endi
x 2.
MA
OO
SP
OC
File
tll.W
* 1 2 3 4 5 6 7 8 9 10 11 12 14 15 17 18 19 20
21 23 24
25 26
27
28
29
30
31 32 33 34 35 36
37
38
39
40
41 42
43
44 45
47
48
49
50 51 52
53
54
55
56 57
58
59
60
61 62 64
65
Lo
calit
y/C
ate
go
ryA
W-O
M1&
2A
W-S
74
5W
hite
Bea
r H
azel
18
AW
-2399
AW
-2839
AW
-2365
AW
-2789
AW
-2905
AW
-2904
AW
-2375
AW
-2819
AW
-3143
GV
83033#45
GV
83
03
3#
44
LA
-81-N
A-9
AW
-3101A
LA
-81-N
A-5
9A
W-3
161
AW
-3154
GV
8303
3 #3
0A
lask
a 66
AW
-IH
25
DC
1-79
-EG
-1D
C2-
80-E
G-7
3
DC
2-8
0-E
G-1
86
Bar
t. LT
29
Haz
el
16B
art.L
TS
OE
GA
L-7
5-K
C-5
3B
FM
-78-
1ke
rssa
uk
15H
X 1
39 0
04 N
UN
1Ik
erss
auk
53e
nney
lk
erss
.#1
kers
sauk
2
Iker
ssau
k 4
HX
139
033
SIK
7H
X 1
39 0
14 P
UN
3H
X 1
39 0
06 N
UN
3H
X 1
39 0
35 S
LI 2
HX
139
030
SIK
5H
X 1
3905
6 V
NQ
1H
X 1
3905
1 S
MI6
HX
139
029
SIK
3H
X 1
39 0
27 S
IK 2
HX
139
0011
N
UN
7H
X 1
39
04
9S
MI4
HX
13
9 04
1 S
LI 6
HX
13
90
47
SM
I3B
art.
LT 2
2B
art.
Cry
stal
H
arbo
urQ
V82027-4
5C
hest
. In
let
11H
X 1
39
04
6S
MI2
Bar
t. LT
21
Haz
el
12B
art.
20
LT 4
2 H
azel
1
K1-7
8-B
S-2
2S
EA
-5-7
6-1
56
HU
85-0
27-7
6C
hest
. In
let
95a
Che
st.
Inle
t 3
um
tom
p11.5 12
9.4
10.5
10.5
11.1 11
10.5
10.5
10.8
11.7
10.5 0
-1.6 9
10.3 9 11 9.7 2 9
9.4 12 13 13 - 1
- 1
13 12 4.6 4 4
3.2 5 5 4 4 4 2 4 1 2 4 4 4 2 2 2 2 2
-1.3
2.1
6 2 0 08.
88.
8 0 - 1
1.66
1 1570
23 11 4
26 4 4
41 89
30
36
59 8 3 6 1
2 2 1 3
30 4
3 312 13 14 3 1
12 64 1
4 2 18 15
222 3
92 6 3
21 39 15
56
7 40 3 1 4 1 1
B 55 3 15 5 1 2 10 17
11 1 1 3 2 / t
9 1
10 1 1 4 9 1 1
12 t 1 1
1 1 44
12 13
2 10
8 1 1
1 3 9
41
5 1 9
1 4 1 1
1 5 2
16
17 8
61 12
1
18
19
Wl
1
20 4 1
21 6 3
104
29 1 1 5
64 3
13
0
23 25
55
22
App
endi
x 2.
MAO
D S
PO
C R
le
LLfiW 6
667
68
69
70
71 72
73
74
75
76
77
78
79
80
81 82
83
84
85
86
87
88
89
90
91 92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
Loca
lity/
Cat
egor
yB
art.
LT 2
0 H
azel
10
Che
st.
Inle
t 2
Che
st.
Inle
t 14
Che
st.
Inle
t 1
Che
st.
Inle
t 7
Che
st.
Inle
t 6
Che
st.
Inle
t 5
Che
st.
Inle
t 4
Che
st.
Inle
t 9
S5-
77-B
S-2
9S
EA
-6-7
5-16
9AC
hest
. In
let
15C
hest
. In
let
17C
hest
. In
let
18C
hest
. In
let
16C
hest
. In
let
20C
hest
. In
let
19S
EA
-5-7
6-1
37
GV
82027-6
7S
EA
5-1
25
AH
U8
1-0
45
-20
S5
-77
-BS
-17
tart.
C
oral
ha
rbor
S5-
77-B
S-1
6S
5-7
7-B
S-1
8B
art.
98B
art.
97S
5-7
7-B
S-2
7S
EA
-5-7
6-17
4S
EA
-5-7
6-1
31D
Alp
ha-H
#9
Alp
ha- H
#4
SE
A-5
-76-
72A
Che
st.
Inle
t 8
Pen
ney2
7410
1N
orth
wln
d 5
Bar
t. 19
Nor
thw
lnd
6B
art.
47B
art.
49B
art.
46B
art.
30B
art.
33B
art.
5B
art.
48B
art.
29B
art.
31B
art.
55A
W-3
7-1
61-5
1B
art.
LT34
H
azel
#9
Nor
thw
lnd
63 S
TA
10N
orth
wln
d 63
STA
1 1
AW
-V5
-33
-78
-21
Nor
thw
lnd
63 S
TA
13A
W-N
NA
W-6
2-15
0-11
AW
-57
-32
8-7
0A
W-5
2-1
60-1
0A
W-5
7-3
28
-28
AW
-57
-32
8-8
0
um
tem
p 01.8
51.9
7-
1
1.2
41.
20
.67
1.0
9-0
.6 10
10
1.9
91.2
62
.04
0.8
31.4
61.3
2 12
-1.5 1
1 0 1 1 4 10
10
-0.5 0.5 1
11
111 8 88.5
-0.4
9 3 3-
1 3 1 1 1 1 1 1 1 1 1 1 2 1 3 3 8 3 8 7 8 8 c 8
1 1 1 1 1 3 3 3 1 2 1 6 2 1 2 15 4
11 23
56 1
12 14 3 1
2 234 1
24 5
35 6 1 6 3 4 1 1
32 2
16
16 1 1 6 1 1
14 1
34 2
41 11114 4 17
56 12
81
24
31 20 13 9
16
23 2
29
113 1 2 2 3
5 4 14
67 1 3 3 2 3 6 1 4 3 1 5 4 1 2 5 14 3 3 2 8
8 1 7 1 2 1 1 2 1 1 2 40 22
6 1 4 2 3 5
9 1
10 91
1 2 1 2 2 1 1 1
1 1
12 3 2 1 2 3 1 3 6 5 4
13 17 2 25
1 5 12 6 5 3 3 2 1 15
1
14
15 5 1
16 9 1
1 1 9 9 16
17 2 2 1 1 2 6 8 12 17 7 2 1
18
19
iri
)
20 22
3 7 8
21 4
23
App
endi
x 2.
MA
OD
SP
OC
Fllo
LUito
*12
612
813
013
113
213
313
413
513
813
914
214
314
414
514
514
714
815
215
515
716
316
416
616
816
917
017
117
217
317
417
617
718
218
3..
!»«
18
619
319
419
519
619
819
9200
202
205
206
210
211
21
2216
217
22
022
122
2223
224
225
227
232
233
Lo
calit
y/C
ate
go
ryA
C-7
1-2
7A
W-6
2-1
60
-9H
U6
9-0
50
.82
5A
C-7
1-6
AC
-71-7
Ba
rt. #
70H
U69-0
50
182
6H
U6
9-0
50
.83
4A
W-5
7-3
28
-32
AC
-71
-3H
U6
9-0
50
.83
3P
RZ
O
70-2
2-23
AC
-71-1
0A
W-6
2-1
60
-8S
EA
-5-7
6-1
45
81-A
PB
-13
81-A
PB
-12
81-A
BP
-11
HU
69
-05
0.6
19
AC
-71
-1P
RZ
O
70-2
2-82
81
-AE
R-3
5R
ICH
19
70-2
2A
C-7
1-3
6A
C-7
1-3
881-A
ER
-34
AC
-71
-53
PR
ZO
71-
9481-A
ER
-33
AW
-62
-16
0-7
PR
ZO
70
-22-
90N
orth
wln
d 63
S
TA
5681-A
ER
-31
81
-AE
R-3
2A
C-7
1-3
7P
RZ
O
70-2
2-84
HU
69
-05
0.8
38
PR
ZO
71-
51P
RZ
O 7
1-13
68
1-A
BP
-21
AC
-71
-39
Bar
t. LT
27
Haz
el 8
HU
69-0
50.8
61
PR
ZO
70
-22-
120
81-A
PB
-20
HU
69-0
50.8
31
81-A
PB
-19
81-A
PB
-18
AC
-71
-42
PR
ZO
70
-22-
126
PR
ZO
70
-22-
130
81-A
PB
-17
Bar
nes
18-8
0B
arne
s 19
-80
HU
69
-05
0.8
51
79-A
BP
-14
72-A
BP
-12
HU
69-0
50.8
37
Nor
thw
lnd
63
STA
45
72-A
BP
-11
nim
tem
p 4 8 - 1 1 1 2 -1
-0.5 5
1.5
-1.3
-1.2
5 0 810 2 2 2
-0.5
-0.3 -
1
1.3
2.5 2.2 3
0.3 1.5 - 1
- 1 7
-1.5 1.6 - 1 1 a - 1
1.2
5-1
.5 0-1
.53 4 3
0.3
-1.7
5-0
.35 0 1 1 2
-1.3
-1.3
-0.4
3 10.
5-1
.2-0
.18
-0.4
3-1
.3 0-0
.18
1 6 3 6 7 13 81
4 12 15 5 3 7 14 101 6 8 6 6 1 6 6
42 6 2 5 2
2 3 1 1 1
34
5 48 1
67 4 1 6 1 7 1 8 1 2 4 1
89 1 1
72 3
., ?.
fi 1 8 5 1
31
1 6 4 1 i
10 3 1 2 2 6 1
19 5 28 19
11 1
12 1 2
13 1
14 1 3 _. 1 1 2 1 1 1
15 1 5 5
16 3 1 1 2 1 2 2 1 2 t
17 1 7 1 1 7 6 4
18 1 1 1 5 1 2 3 1
19
20 1 1 1 4
21 8
24
App
endi
x 2.
MA
OO
SP
OC
Rle
UliU
I 234
23
6239
239
240
244
24
62
47
250
253
25
4255
256
25
72
58
259
261
262
265
26
6268
270
273
274
27
5276
277
27
8280
281
286
28
8290
292
294
296
297
298
299
303
30
43
08
310
311
31
2313
31
4316
319
32
03
22
32
4325
327
329
330
331
33
2337
340
loca
lity/C
ate
go
ryJa
mes
16
-80
HU
69-0
50.8
30
AW
-62-1
60-3
Bar
nes
17-8
07
2-A
JT-2
6B
arne
s 22
-80
71
-AB
P-2
37
2-A
BP
-1B
arne
s 34
-80
AC
-71-4
571-A
BP
-1
79
-AB
P-2
272-A
JT-1
20A
79-E
RK
-12
72-A
ER
-151
Bar
nes
21-8
07
9-A
BP
-23
Bar
nes
20-8
07
1-A
BP
-12
72
-AE
R-1
50
72
-AE
R-1
49
72
-AB
P-2
6B
arne
s 23
-80
71-A
BP
-13A
72
-AB
P-2
572-A
ER
147
Bar
nes
26-8
0H
U6
9-0
50
.83
6H
U69-0
50.8
86
72
-AE
R-1
46
71
-AB
P-2
72
-AB
P-1
4P
RZ
O 7
1-72
71-A
JT-4
5A
C-7
1-4
871-A
BP
-11
71-A
BP
-38A
Bar
nes
25-8
072-A
ER
-94
72-A
ER
-99
72
-AE
R-1
62
72
-AE
R-1
03
71
-AB
P-3
72
-AE
R-1
09
71
-AJT
-34
80E
R53
Bar
nes
27-8
07
2-A
ER
-85
72
-AE
R-1
07
AW
-EH
-27
2-A
ER
-10
6H
U69-0
50.8
78
AC
-71
-47
72
-AE
R-1
65
72-A
BP
-97
2-A
ER
-13
880
PB
50A
W-6
2-1
60
-1B
arne
s 47
-80
72
-AE
R-1
27
lum
tem
p 0.3
-1.3 7
1.25
-1.6
70.
5 1-1
.45
-1.4
52.
3-1
.45
-1.6
7 1-1
.07
-0.0
5-0
.5
-0.0
50.
5-1
.32
-0.0
5-0
.05
-0.0
50.
5-1
.38
-1.3
8 - 1
-0.3
-0.3 2 -
1-1
.45
1.4
4-1
.3-1
.39
1.7
-1.4
4-1
.39 -1
1.3
9-1
.39
-1.3
9-1
.39
-1.4
5-1
.39
0.7
-0.1 -
1-0
.83
-0.8
3 63.
91 1.3
1.5
-0.8
30.
36-1
.46
-0.8
3 7 - 1
0.7
1 2 16 2 5 9 1 4 2 3 1 3
125 3 1
11
3 6 2
20 4
22 2 9
59 1
2 2 5 2
34 3
56 1 1 2 1 1 1
7 2 2 3 2 t 1
89 74
96 4 2
28 2 4
22
27 1
30 2 3 4 4
82 1 2 2 2 1
125 3 5 3 1
37g 3
37
8 2
10 3
20 36 1 1
23 2
24 4 1 1 1
117 1
199 1
215 13 25 7
21 68 12 30 g 2 1 2
27
1 1
247 1
12
13 1 2 1 3
14 1 23
1 5
16 1 1 3 1 2 1 3 6 1 2 3 2 >
31
17 2 320
18 1 2 1
19
.1 ,
1
20 1
21 1 4 2
25
App
endi
x 2.
MA
OO
SP
OC
File
llh
M
34
1347
350
351
353
354
355
356
359
36
1362
363
368
369
373
376
377
382
383
384
385
386
389
390
391
392
394
406
407
408
409
41
1412
416
410
420
422
423
424
425
426
433
436
437
438
439
440
441
444
445
450
454
458
462
463
469
470
473
474
477
.oca
llly/C
ale
go
ry
72A
fcF
M21
72-A
EH
-124
PH
ZO
72-4
471-A
BP
-5
71-A
JT
-32
72
-AE
H-7
079-A
BP
-34
72
-AE
R1
26
Barn
es
58-8
0
Bar
ries
28-8
061-A
PB
-24
81-A
BP
-25
71-A
BP
-10
72-A
JT
-41
82
-AE
R-1
2P
RZ
O 7
2-41
71-A
JT
-33
71-A
BP
-69
Barn
es
56-8
072-A
JT
-42
Barn
es
66-8
0B
arn
es
71-8
071-A
BP
-37
AW
-57-3
28-1
771-A
BP
-9
71-A
BP
-34
71-A
BP
-50
71
-AB
P-8
80E
R79
72-A
JT
-31
71-A
BP
-33
AW
-57
-32
6-9
1
80E
R80
PH
ZO
71-1
87
71-A
BP
-39A
80E
H77
71-A
JT
-35
80E
H81
71
-AB
P-4
0B
E. o
f D
rew
Pt.
Barn
es
35-8
080P
B40
Barn
es
38-8
0B
arn
es
44-8
0B
arr
ies
45-8
072-A
BP
61
72-A
BP
-43
Barn
es
57-8
071-A
BP
-41A
Barn
es
30-8
07
1-A
BP
-30
B71-A
BP
-90
71-A
BP
-61A
71-A
BP
-43
71-A
BP
-60
Tapk
aluk
Pas
sE
lultk
lt P
ass
Nor
thw
lnd
63 S
TA 5
071
-AB
P-9
371
-AB
P-8
8A
um
tem
p 0.7
0.7 1.5
0.3
6 1 10.7
0.7 1 0
-0.7
6-0
.76
1.4
3 0-1
.75
1.2 1
-1.7
5-0
.15 0 - 1
- 1
-1.7
5 3-1
.35
1.9
51.9
2-1
.25
-0.3
-0.3
2.4
5 7-0
.3
1.7
6 1
.66
3.5
30
.31
-1.4
31.
1 1-0
.21
1.4
30
.16
0.3
80
.38
0.2
10
.16
-0.2
50
.69
-0.2
90
.56
-0.6
7 2 1
.5-1
.6 1 1-
1-0
.6-1
.4
1 458 2
13 8 4
58 1 3 1 5 6 8 1 9 1 9 1 2 1 2 4 1 4 1 2 7
14 2 rt
23 5
45
6 1 1
7 1 1 1 1 7 1
8 4
9 4 12 6 3
30 8 3 2 2 1 1 4 5 8 5
33 6
44 1 1
16
10 2 8 1 5 6 9 8
39 2 1 10 5
301 1 7 1 3 <
19
1 1
- -
12
13
14 1 1 1 2 1 1 2 1
1 5
1 6 1 1 3 3 1
1 2 1 2 1 1 3 2 2 2 1 2 2
17 20 12 1 2
1 8 3 4 1
19
- . i
20
21 6 1
App
endi
x 2.
MA
OD
SP
OC
File
LLliM 478
48
1482
483
484
485
486
487
488
489
490
492
493
495
496
497
499
500
503
504
505
506
507
508
509
518
524
528
532
Lo
calit
y/C
ate
go
ryN
orth
wln
d 63
S
TA 5
1N
orth
wln
d 63
S
TA 7
7N
orth
wln
d 63
S
TA 7
9N
orth
wln
d 63
STA
71
Nor
thw
lnd
63
STA
13
0N
orth
wln
d 63
STA
83
Nor
thw
ind
63 S
TA 6
3B
art.
LT 3
3 H
azel
7B
art.
LT 5
1 H
azel
6N
orth
win
d 63
STA
95
Nor
thw
ind
63 S
TA 9
7A
W-5
7-3
28-4
6Ba
rt. L
T 35
Haz
el 5
Nor
thw
ind
165
Nor
thw
ind
145
Nor
th w
ind6
5 S
TA
41N
orth
win
d 13
9Ba
rt. L
T 31
H
azel
4A
W-R
-1N
orth
wln
d 63
S
TA14
3B
art.
LT 2
3 H
azel
3Th
ule,
N.
Sta
.Bay
(2)
Bart.
N.O
men
olu
Bart.
LT
26 H
azel
2N
orth
wln
d65
STA
35
Bar
t. LT
52
Haz
el #
1A
W-C
FN
orth
win
d S
TA 1
06N
orth
wln
d S
TA11
2TO
TAL
mm
tom
p - 1
- 1
- 1
- 1
-1.5
-0.5
-0.5 -
1-
1-1
.5-1
.5 5 -1-1
.5-1
.5 0.5
-1.5 -
1 4-1
.5 0 0 0 0 0-1
.5-1
.5 0.5 0
1 14 2
126 2 2 2
10
58
2 4 4
24 2 16
13
14 4
359
3
146
4 8
47 8
494
24 1 2
40
1491
5 67
6 3 9
21
7 2 3 13 2 2 2 1 3
21
5
8 5
62
404
9 126
90
2
10 3
15
20
11 17
13
323
12 1 5
74
13 53
22
4
14 3 1 1 3 3 5 3 1 2
70
1 5 1
20
16 10 1
187
17 1 2 10
24
3
18 3
30
19
i«i i
821 30
20 2
40 1 4
121
230
21 3
48
7
27
Ol Ol
o o
II
3 3£ »
u <cB
Ol
Ol
01 to
u ro
ro 0100 Ol
U Ol
Ol
I
oc
o
ro
o
ro
COm
Ol
o
Olo
00
OE
CD CO
ro ro
oo
ro or-
N
I
00
CD
a r-
ro
1
N
Ol
ro
b>
X
2o CO
ro
ro
O
0
5"0
ro
ro o
_.
Doo ro o ro j*.Ol
L.
Olro
o
roOl
roro'
ro oo
CD
O
S.s.B>
0
CD
p.
r~
roro
re
sj
b: <o
2 u
X
i0CO
o>
u <o
i CO
1z z
I
(C
(t
ro
I
(C
(C
CO
u
I
b:(O
3CO
o
HX 139 033 SIK 7 HX 139014 PUN 3
HX 139 006 NUN 3 HX 139 035 SLI 2 HX 139 030 SIK 5 HX 139 056 VNQ 1
i
a o e 5 I -i Cszl ssg J£ t> j I > B> ;
e c r c oo jj
""i*!01 21 Z b>
u * _._.
o -»
_»
3
CD 00
q i-
B>
»a
Ol
Ol *
00
00 10
u -»
a o ro00
pm 9a a>
_»
ioio > > D > > r- IOO! »<££'> jfy_»j o e i (
91 ' <» G * o;
>* -* c « to < * **
<D
4* b>_» *. 01 -»
<O to
01
ro 01 u oo ro to -*
^ ro ro
-»
00 U
ro
u ' b b b> ro ro rolro ro ro ro-» . 0 0 -» 00 b> <0l<0 -g u 00 C ; b b ^ -« -» OIO < O) bj. 3 , , 01 <o
U3 ' '
O -» O-«OOO_4-»O
-» ro01 00 *
-» ro 3 _» oi b> >j ro
1
ro ro ro -*
_.
_»
> -» ro o» ro -»
-» ro ID -» > a> u> to uoiro -
b> 00
-* jt
ro ro oo ro a>
r-
^ ,, M ^ f
Locality/Category AW-OM1&2
> AW-S745 ) White Bear Hazel 18
1 AW-2399
. J
ro ro
ro u
ro
ro (u
ro o>
ro-j
ro09
ro to
u0
u
u ro
u u
u
u(u
u <n
u
u09
U tf>
3
»
1 0
I
App
endi
x 2.
MA
OD
SP
OC
Rle
lltiM 6
667
68
69
70 71 72
73 74
75
76
77
78 79
80
81 82 83 84
85
86
87
88
89
90
91 92 93 94 95 96 97
98 99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
11
411
511
611
71
18
119
120
121
122
12
312
412
5
Loca
lity/
Cate
gory
Bar
t. LT
20
Haz
el
10C
hest
. In
let
2C
hest
. In
let
14C
hest
. In
let
1C
hest
. In
let
7C
hest
. In
let
6C
hest
. In
let
5C
hest
. In
let
4C
hest
. In
let
9S
5-7
7-B
S-2
9S
EA
-5-7
5-1
69A
Che
st.
Inle
t 15
Che
st.
Inle
t 17
Che
st.
Inle
t 18
Che
st.
Inle
t 16
Che
st.
Inle
t 20
Che
st.
Inle
t 19
SE
A-5
-76-1
37
GV
82027-6
7S
EA
5-1
25
AH
U81-0
45-2
0S
5-7
7-B
S-1
7
Bar
t. C
oral
ha
rbor
S5
-77
-BS
-16
S5
-77
-BS
-18
Bar
t. 98
Bar
t. 97
S5
-77
-BS
-27
SE
A-5
-76-1
74
SE
A-5
-76-
1 31
DA
lpha
-H
#9A
lpha
-H
#4S
EA
-5-7
6-7
2A
Che
st.
Inle
t 8
Pen
ney2
7410
1N
orth
wln
d 5
Bar
t. 19
Nor
thw
lnd
8B
art.
47B
art.
49B
art.
46B
an.
30B
art.
33B
art.
5B
art.
48B
art.
29B
art.
31B
art.
55A
W-3
7-1
81
-51
Bar
t. LT
34
Haz
el #
9N
orth
wln
d 63
S
TA
10
Non
hwln
d 63
S
TA
11
AW
-V6-3
3-7
8-2
1N
orth
wln
d 63
S
TA
13
AW
-NN
AW
-62-1
60-1
1A
W-5
7-3
28-7
0A
W-6
2-1
60-1
0A
W-5
7-3
28
-28
AW
-57-3
28-8
0
um
tem
p 0
1.8
5
1.9
7-
1
1.24 1.
20
.67
1.09
-0.5 10 10
1.99
1.26
2.0
40.8
31.
461.
32 12-1
.5 1 1 0 1 1 4
10 10-0
.5 0.5 11 11 1 1 8 8
8.5
-0.4
9 3 3 1 3 2 1 3 3 8 3 8 7 8 8 5 8
22
23 32 1 4 5 8
20 1 1
38 1 2 7 1
32
2 2 10 12 12 2
24 614 3
10 3 2 8 8 10 7 10 6 1 2 2 1
1 1 3 1 1 1 6 1
25 3
26 1 1 4 2 5 2 2 1 3 1
27
28 24 6 155 3
18 317 16 6 4 2 2 2 3
0 52 2 11 21
1 2 1 1 1
29
30
31
32 3 4 1 1 1 3
33
34
35 2 2 2
36 1 2 85 7 ~t
37 1 2
38 43 10 85 7
51 23
39
62
24 14 10 8 7 14 26 9 84 3 9 1
39 85
79 26
78 6
60
103
511
20 12 9 8 5 1 2 15
2
20 14 6
94 17 36 17 2 16 4 1 1 7 10
1 1 1
40 1 2 1
i i
2 3 2
41 1
28 1
42 38 17 4
36 2 6
18 81
1 1 3 3 1 5 7 11
1
12 2 1 2 1
29
App
endi
x 2.
MA
OD
SP
OC
File
UllU
>«
126
128
13
013
113
213
313
413
513
813
914
214
31
44
145
145
14
714
815
215
515
716
31
64
166
168
16
917
017
117
2 17
317
417
617
718
218
318
618
819
319
419
519
619
819
9200
202
205
206
210
211
212
216
217
220
221
222
223
224
225
227
232
?33
oca
llly/
Ctt
leg
ory
AC
-71-2
7A
W-6
2-1
60-9
HU
69
-05
0.8
25
AC
-71
-6A
C-7
1-7
Ba
rt. #
70
HU
69
-05
0.8
26
HU
59
-05
0,8
34
AW
67-3
28-3
2A
C-7
1-3
H 1
169-
050,
833
PR
ZO
70
-22-
23A
C-7
1-1
0A
W-6
2-1
60
-8S
EA
-5-7
6-1
45
81
-AP
B-1
381-A
PB
-12
81-A
BP
-11
HU
69- 0
50,8
19
AC
-71-1
PR
ZO
70
-22-
828
1-A
ER
-35
RIC
H
1970
-22
AC
-71-3
6A
C-7
1-3
8B
1-A
ER
-34
AC
-71
-53
PR
7O 7
1 94
B1
-AE
R-3
3A
W-6
2-1
60-7
PR
ZO
70
-22-
90N
orth
wln
d 63
S
TA
56
81-A
ER
-31
81-A
ER
-32
AC
-71
-37
PR
ZO
70
-22-
94H
U6
9-0
50
.83
8P
RZ
O 7
1-61
PR
ZO
71-
136
B1-A
BP
-21
AC
-71
-39
Ban
. LT
27
Haz
el 8
HU
69-0
50.8
61
PR
ZO
70
-22-
120
81-A
PB
-20
HU
69
-05
0.8
31
81-A
PB
-19
81-A
PB
-18
AC
-71
-42
PR
ZO
70
-22-
126
PR
ZO
70
-22-
130
81-A
PB
-17
Bar
nes
18-8
0B
arne
s 19
-80
HU
69
-05
0.8
51
79-A
BP
-14
72
-AB
P-1
2H
U6
9-0
50
.83
7N
orth
wln
d 63
S
TA
45
n A
ijp-1
1
urr
tom
p 4 8 - 1 1 1 2 - 1
-0.5 5
1.5
-1.3
-1.2
5 0 8 10 2 2 2-0
.5 0
.3 - 1
1.3
2.5
2.2 3
0.3
1.5 - 1
1 7
-1.5 1.6 - 1 1 2 - 1
-1.2
5-1
.5 0-1
.53 4 3
0.3
-1.7
5-0
.35 0 1 1 2
-1.3
-1.3
-0.4
3 10.
5 1
.2-0
.18
-0.4
3-1
.3 0 0
.18
22 2
___ 2 1 3 3 3 1 9 4 12
5 101 9 2
24 18
1 6 3 4 5 2 12 2 t
23
-
4 2 1 1 1 8 1 2 1 2 6 1
24
-
25
-
26
. 2
27 5
__ 2
J 27
- 5 1
29
- - 1 1
30 1 1 1
31 1 128 5 4 1 1
23 5 1
131
223 2 1 7
43
11
2 325 41 84 18 2 10
4 191
33 4 i 6 3 6
32 1 2
33
34
- 1 1 2 I
35
36 1 1 6 4 1 1 1 2 1 1 1 1 10 i ~i
37
38 2
39 9 6 1 3 5 3 3 15 58 i
40 5
<" i
2 1 1 i t
41
1
42 1
- A 1
30
App
endi
x 2.
MA
OD
SP
OC
Rle
LLfil
o*
23
42
36
23
9239
24
02
44
246
247
25
02
53
254
255
256
257
258
259
261
262
265
266
268
27
02
73
27
4275
276
277
278
280
281
286
28
8290
292
294
296
297
298
299
303
30
4308
310
311
31
23
13
31
4316
31
9320
322
324
325
327
32
9330
331
33
2337
340
oca
llly/
Cate
gory
Bar
nes
16-8
0H
U69-0
50.8
30
AW
-62
-16
0-3
Bar
nes
17-8
07
2-A
JT-2
6B
arne
s 22
-80
71
-AB
P-2
37
2-A
BP
-1B
arne
s 34
-80
AC
-71-4
57
1-A
BP
-179-A
BP
-22
72-A
JT-1
20A
79
-ER
K-1
272-A
ER
-151
Barn
ei
21
807
9-A
BP
-23
Bar
nes
20-8
07
1-A
BP
-12
72
-AE
R-1
50
72
-AE
R-1
49
72-A
BP
-26
Bar
nes
23-8
07
1-A
BP
-13
A72-A
BP
-25
72-A
ER
147
Bar
nes
26-8
0H
U69-0
50.8
36
HU
69
-05
0.8
86
72
-AE
R-1
46
71-A
BP
-272
-A
BP
-14
PR
ZO
71
-72
71
-AJT
-45
AC
-71
-48
71-A
BP
-11
71
-AB
P-3
8A
Barn
ei
25-8
07
2-A
ER
-94
72
-AE
R-0
97
2-A
ER
-16
27
2-A
ER
-10
37
1-A
BP
-37
2-A
ER
-10
971-A
JT-3
480
ER
53B
arne
s 27
-80
72
-AE
R-8
57
2-A
ER
-10
7A
W- E
H- 2
72
-AE
R-1
06
HU
69-0
50.8
78
AC
-71
-47
72
-AE
R-1
65
72
-AB
P-9
72
-AE
R-1
38
80P
B50
AW
-62
-16
0-1
Bar
nes
47-8
07
2-A
ER
-12
7
um
tom
p 0.3
-1.3 7
1.25
-1.6
70.
5 1-1
.45
-1.4
52.
3-1
.45
-1.6
7 1-1
.07
-0.0
5-0
.5
-0.0
50.
5-1
.32
-0.0
5-0
.05
-0.0
50.
5-1
.38
-1.3
8 - 1
-0.3
-0.3 2 -
1-1
.45
-1.4
4-1
.3-1
.39
1.7
-1.4
4-1
.39 - 1
-1.3
9-1
.39
-1.3
9-1
.39
-1.4
5-1
.39
0.7
-0.1 -
1-0
.83
-0.8
3 63.
91 1.3
1.5
-0.8
30
.36
-1.4
6-0
.83 7
- 1
0.7
22 3
10 2 3 1 2 10 6 17 17
2 2 3 1 3 4 3 2 12
533 1
23 2 4 1 7
23 3 1 1 8 2 4 2 1
84
24 1
25
26
27
28 29 15 2
29 5
30 2 1 1 2 1
31 2 11 2 15 18
3 12 18 33 14 21
9 1 4 1
55 25 7
56
32 2
33
34 1 1
35
36 1 1 4 6 1
1 1 3 1 1 3
37
38 2 11
39 9 11 18
1 1
40 1 2 1 1 3 6
.,,
2 10
1 1 1 7 1 1
41 7
42 2 2 1
21
1 13
1 3
31
App
endi
x 2.
MA
OO
SP
OC
File
LL
fik*
341
347
350
351
353
354
35
53
56
35
936
1362
363
368
36
9373
37
6377
382
383
384
38
53
86
38
9
300
391
392
394
406
407
40
84
09
411
412
41
641
94
20
422
42
3424
42
5426
433
436
437
438
43
9440
441
444
44
54
50
454
458
462
463
46
9470
473
474
477
.oca
llty/
Cate
gory
72
-AE
R-1
21
72
-AE
R-1
24
PR
ZO
72-
4471-A
BP
-5
71
-AJT
-32
72
-AE
R-7
079-A
BP
-34
72-A
ER
126
Bar
nes
58-8
0B
arne
s 28
-80
81-A
PB
-24
81-A
BP
-25
71-A
BP
-10
72-A
JT-4
182-A
ER
-12
PR
ZO 7
2-41
71
-AJT
-33
71
-AB
P-6
9Ja
mes
56
-80
72
-AJT
-42
Bar
nes
66-8
0la
rne
s 71
-80
71
-AB
P-3
7
AW
6
/32
8-1
771-A
BP
-971-A
BP
-34
71-A
BP
-50
71-A
BP
-880
ER
7972-A
JT-3
17
1-A
BP
-33
AW
-57-3
26-9
180
ER
80P
RZ
O 7
1-18
771-A
BP
-39A
80E
R77
71
-AJT
-35
80E
R81
71-A
BP
-40B
E. o
f D
rew
Pt.
Bar
nes
35-8
080
PB
40B
arne
s 38
-80
Bar
nes
44-8
0B
arne
s 45
-80
72-A
BP
-61
72-A
BP
-43
Bar
nes
57-8
07
1-A
BP
-41
AB
arne
s 30
-80
71-A
BP
-30B
71-A
BP
-90
71
-AB
P-6
1A
71-A
BP
-43
71-A
BP
-60
Tapk
aluk
Pas
sE
luitk
it P
ass
Nor
th w
ind
63
ST
A
5071-A
BP
-93
71-A
BP
-88A
um
tem
p 0.7
0.7
1.5
0.36
1 10
.70.
7 1 0-0
.76
-0.7
6-1
.43 0
-1.7
51.
2 1-1
.75
-0.1
5 0 -1 -1
-1.7
5 3
-1.3
51.
951.
92-1
.25
-0.3
-0.3
2.45
7-0
.3-1
.76
1.6
63.
630.
31-1
.43
1.1 1
-0.2
1-1
.43
0.1
60
.38
0.38
0.21
0.1
6-0
.25
0.6
9-0
.29
0.5
6-0
.67 2
-1.5
-1.6 1 1-
1-0
.6 1
.4
22 55
25 10
1 3 141 1 4 1 1 2 5 101 6 1
16 8 1 1 1 1 2 1 1 3
23 3 3 2 1 4 2 1 2 1 1 1 1 3 3 1
24
25 25
26
27
28 1
29 1
30 4 1 1 1
31 8
922 1 8 2 8 1
10
2 8 2 3 6 5 1
12
9 16
7 1
71
7 1 3 1
32 17 24 e
33
34 3 1 3 1
35
36 22 1 2 1
43 1 7 1 2 1 1 3 1 1 1
37 1
38 1 1
39 1 1
40 2
. -
4 1
41
42 1 1
32
App
endi
x 2.
MA
OD
SP
OC
Rle
LLliM 478
48
1482
483
484
485
480
487
488
489
490
492
493
495
496
497
499
500
503
504
505
506
507
508
500
518
524
528
532
-oca
llty/
Cate
gory
Nor
thw
ind
63
ST
A 5
1N
orth
win
d 63
ST
A
77N
orth
win
d 63
ST
A 7
9N
orth
win
d 63
S
TA
71
Nor
thw
ind
63
ST
A
130
Nor
thw
ind
63
ST
A
83N
orth
win
d 63
ST
A
63B
art.
LT 3
3 H
azel
7B
art.
LT 5
1 H
azel
6N
orth
win
d 63
S
TA
95
Nor
thw
ind
63
ST
A
97A
W-5
7-3
28-4
6B
art.
LT 3
5 H
azel
5N
orth
win
d 16
5N
orth
win
d 14
5N
orth
win
d65
ST
A
41N
orth
win
d 13
9B
art.
LT 3
1 H
azel
4A
W-R
-1N
orth
win
d 63
S
TA
143
Bar
t. LT
23
Haz
el 3
Thu
le,
N.
Sla
.Bay
(2)
Bar
t. N
Om
enol
u B
art.
LT 2
0 H
azel
2N
orth
wln
d65
ST
A35
Bar
t. LT
52
Haz
el #
1A
W-C
FN
orth
win
d S
TA
106
Nor
thw
ind
ST
A11
2T
OT
AL
um
tem
p -1 -1 -1 -1-1
.5-0
.5-0
.5 - 1
- 1
-1.5
-1.5 5-
1-1
.5-1
.5 0.5
-1.5 -
1 4-1
.5 0 0 0 0 0-1
.5-1
.5 0.5 0
22 1 1
466
23 4 3
42 3 6
137 6
40 13
12
1
87
7
24 1 1
87
3
25 7
146
4
18
5
26 35
66
27 03
28 1 1 1
91 15 4
355
29 0
30 6 10 18
51
31
22
44
32 2
63
33 2 2 2 6
34 1
128
35 24
36 2 3 1 1
26 2
90 5
1046
37 41
38
1201
39 8 1 5 6 6 91
221 28
1514
40 82
41 5 1
79
42 56
146
483
33
Appe
ndix
2.
MA
OD
SPO
C R
le
LUite
# 1 2 3 4 5 6 7 8 910
1 1
12 14 15
17 18
19
20
21 23
24
25
26
27
28
29
30
31 32
33 34
35
36
37
38
39
40
41 42
43
44
45
47
48
49
50
51 52
53
54
55
56
57
58
59
60
61 62
64
65
Localit
y/C
ate
gory
AW
-OM
1&
2A
W-S
74
5W
hite
B
ear
Haze
l 18
AW
-23
99
AW
-28
39
AW
-23
65
AW
-27
89
AW
-29
05
AW
-29
04
AW
-2375
AW
-28
19
AW
-31
43
GV
83033»45
GV
83
03
30
44
LA
-81-N
A-9
AW
-31
01
AL
A-8
1-N
A-5
9
AW
-31
61
AW
-31
54
GV
83
03
3
#3
0A
lask
a
66A
W-I
H2
5D
C1-7
9-E
G-1
DC
2-8
0-E
G-7
3
DC
2-8
0-E
Q-1
86
Bar
t. L
T 2
9 H
aze
l 16
Ba
rt.L
T3
0E
GA
L-7
5-K
C-5
3B
FM
-78
-1
Ikers
sauk
15H
X
13
9 0
04 N
UN
1Ik
ers
sauk
53e
nney
Iker
ss.J
Mke
rssa
uk
2ke
rssa
uk
4H
X
139
03
3 8
IK 7
HX
139
01
4 P
UN
3H
X 1
39 0
06 N
UN
3H
X
139
03
5 S
LI 2
HX
13
9 0
30
SIK
6H
X
139
056
VN
Q 1
HX
139
051
S
MI
6H
X
139
02
9 S
IK 3
HX
13
9 0
27
SIK
2H
X 1
39
00
11
N
UN
7H
X
139
049
SM
I 4
HX
13
9 04
1 S
LI 6
HX
1 3
9 0
47
SM
I 3
Bar
t. L
T 2
2B
art.
Cry
sta
l H
arb
our
QV
82027-4
5C
hest
. In
let
11H
X
139
046
SM
I 2
Bar
t. LT
21
Ha
zel
12B
art.
20
LT 4
2 H
aze
l 1
K1
-78
-BS
-22
SE
A-5
-76
-15
6
HU
85
-02
7-7
6C
he
st.
Inle
t 95a
Chest
. In
let
3
tum
t»m
p
11
.5 12
9.4
10
.5
10
.5
11
.1 11
10
.5
10
.5
10
.81
1.7
10
.5 0-1
.6 91
0.3 9
1 1
9.7 2 9
9.4 12
13
13
- 1
- 1
13
12
4.6 4 4
3.2 6 5 4 4 4 2 4 1 2 4 4 4 2 2 2 2 2
-1.3
2.1
6 2 0 0B
.8B
.8 0 . 1
1.6
6
43 24
26 3 6 2 312 i 2
44 5
43
37
47 3 9 1
45 3
19 5 10
89 8
233 2
149 17 4 3 6 4 4
46 5
999
27
65 5 1 1 ~i
47 59
12
41 2
22 3 9 6 3 14 24 33 fl
12 2 3
18 t
48 1 2
130
22 4 9
31 15 7
1 1
22
212 1 1
10 3
49 32 3 5 3 1
12
13 5 7
119
50 22 5 2
50
25 2 1 4 9 8
108 1 3
15 1 5 1
19 1 6 1
51
52 1 1
1 1 1 1 2 6
53
296
268 3 1 1
14 1 1
54 2 2
55 7 3 1 2 2 1
0 i 2 t 3 6 ~i 1
56 5
116 5 1 1
126 15
57 1 2 1
58 1
59 1 2 10
60 2
28 8
23 46 B 12 2 2 11 10
1 1
12 4 1
917 3
24 7 6 1
21 45
61 1 117
97 3 1
20
42 17
63 9
47 16
"i i
1
12 1 3 1 1
62 119
76
55 12
14
55
33
45 10
63
4 31
34
App
endi
x 2.
MA
OD
SP
OC
File
LL
hM 66
67
68
69
70 71 72
73
74
75
76
77 78
79
80 81 82
83 84
85
86
87
88
89
90 91 0<?
93 94
95
96 97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
Lo
calit
y/C
ate
go
ryB
art.
LT 2
0 H
azel
10
Che
st.
Inle
t 2
Che
st.
Inle
t 14
Che
st.
Inle
t 1
Che
st.
Inle
t 7
Che
st.
Inle
t 6
Che
st.
Inle
t 5
Che
st.
Inle
t 4
Che
st.
Inle
t 9
S5
-77
-BS
-29
SE
A-5
-75-1
69
AC
hest
. In
let
15C
hest
. In
let
17C
hest
. In
let
18C
hest
. In
let
16C
hest
. In
let
20C
hest
. In
let
19S
EA
-5-7
6-1
37
GV
82027-6
7S
EA
5 12
5AH
U8
1-0
45
-20
S5
-77
-BS
-17
Bar
t. C
oral
ha
rbor
S5
-77
-BS
-16
S5
-77
-BS
-18
Bar
t 98
Hur
l. 07
S5
-77
-BS
-27
SE
A-5
-76
-17
4S
EA
-5-7
6-1
31
0A
lpha
- H
#9A
lpha
-H
#4S
EA
-5-7
6-7
2A
Ch«
8t.
Inle
t 6
Pfn
n«
y27
41
01
Nor
thw
lnd
5B
art.
10N
orth
wln
d 6
Bar
t. 47
Bar
t. 49
Bar
t. 46
Bar
t. 30
Bar
t. 33
Bar
t. 5
Bar
t. 48
Bar
t. 29
Bar
t. 31
Bar
t. 55
AW
-37
-16
1-5
1
Bar
t. LT
34
Haz
el #
9N
orth
wln
d 63
S
TA
10
Nor
thw
ind
63
ST
A
11A
W-V
6-3
3-7
8-2
1N
orth
win
d 63
S
TA
13A
W-N
NA
W-6
2-1
60
-11
AW
-57-3
28-7
0A
W-6
2-1
60-1
0A
W-5
7-3
28-2
8A
W-5
7-3
28-8
0
um
tom
p 01.
851.
97 -1
1.24 1.
20
.67
1.09
0.5 10 10
1.99
1.26
2.0
40.
831.
461.
32 12 1
.5 1 1 0 11 4
10 10-0
.5 O.b 1
11
111 8 88.
5 0
.49 3 3
1 3 2 1 3 3 8 3 8 7 8 8 5 8
43 7 5 14 2 3 1
14
1
23 27 11
2 2 1
44 2 10
1
45 7 1
68 1
12 101
23
6 7 21 36
45 13 11 10
1 2 5 6
46 3 3 13 2 3 3 2 3 2 3 1 2 2
34
. 9 4 2 2 1
47 7 2 17 2
1 1
13 25
7 9 13 14 1 4 7 10 42 18 13 2 8
80
101 44 144 9
33
32 5 3
48
49
50 5 7 3 8 2 3
12 3 5 7 4 2 1 1 3 ? 5 14 14 3 2 8 3
51
52 15 33 1 3 8 4 3 2 1 1 4 g £ 1
53
54 3 3 4 1
55 19 7
26 9 8
22 8 5 9 4 5 6 1 2 4 ? 2 2 12
112
4 5 2 1 1
56 99 21
57 23
1 1
58
1
18
04
1813 4
127
78
59 13
60
11
8 101
57 1
14 93
33
111
309 46 45 158 18 49 68 511 2 30 8
26 1 31 2
197
82
11
424
25 1
1 1 151 3
310
711
010
1 12
713
0 7 4 13 2 1
61 1 1 6 1
i
1 9 1 1 3 1 451
1 5 6 8 3 1 3 1 1
17 2 2 2 9 152 2 4
62
63
342 4 11 31
9 8 1 1 5 4
35
App
endi
x 2.
MA
OD
SP
OC
File
LUite
*126
12
8130
131
132
133
134
136
138
139
142
143
144
145
145
147
148
152
155
157
163
164
166
168
169
170
171
17
2173
174
176
177
182
183
180
188
193
194
195
79
6
198
199
200
202
205
206
210
21
1212
216
217
220
221
222
223
224
225
227
232
233
Lo
calit
y/C
ate
go
ryA
C-7
1-2
7A
W-6
2-1
60-9
HU
69-0
50.8
25A
C-7
1-6
AC
-71
-7B
art.
#70
HU
69-0
50.8
26H
U69
-050
1834
AW
-57-3
28-3
2A
C-7
1-3
HU
69-0
50.8
33P
RZO
70
-22-
23A
C-7
1-1
0A
W-6
2-1
60
-8S
EA
-5-7
6-1
45
81-A
PB
-13
81-A
PB
-12
81-A
BP
-11
HU
69-0
50.8
19A
C-7
1-1
PR
ZO
70-2
2-82
81-A
ER
-35
RIC
H
1970
-22
AC
-71
-36
AC
-71
-38
81-A
ER
-34
AC
-71
-53
PH
ZO 7
1-94
81-A
ER
-33
AW
-62
-16
0-7
PR
ZO
70-2
2-90
Nor
thw
lnd
63 S
TA 5
681
-AE
R-3
181
-AE
R-3
2A
C-7
1-3
7P
RZO
70
.22-
94H
U69
-050
.838
PR
ZO 7
1-61
PR
7O 7
1-13
681
-AB
P-2
1A
C-7
1-3
9B
art.
LT 2
7 H
azel
8H
U69
-050
.861
PR
ZO
70-2
2-12
081-A
PB
-20
HU
69-0
50.8
3181
-AP
B-1
981
-AP
B-1
8A
C-7
1-4
2P
RZO
70
-22-
125
PR
ZO
70-2
2-13
081-A
PB
-17
Bar
nes
18-8
0B
arne
s 19
-80
HU
69-0
50.8
5179
-AB
P-1
472
-AB
P-1
2H
U69
-050
.837
Nor
thw
lnd
63 S
TA 4
572
-AB
P-1
1
um
tvm
p 4 8-
1 1 1 2-
1-0
.5 51
.5-1
.3
-1.2
5 0 810 2 2 2
-0.5
-0.3 -1 1.3
2.5
2.2 3
0.3 1.5 -
1-
1 7 1
.5 1.6
- 1 1 2 1
-1.2
5-1
.5 0 1
.53 4 3
0.3
-1.7
5-0
.35 0 1 1 2
-1.3
1.3
-0.4
3 10
.5-1
.2
-0.1
8-0
.43
-1.3 0
-0.1
8
43 7 5 13 3 1
44 1 18 8
45 1 42
46 37
1
47 1 3 3 24 18
48 8
49 1
50 1 15
2
51 3 12 16 2 1 7 1 1 8 4 9 39 23
3
52 8 2 13 4 1 1 2
14
36 4
22
51 26
717 4
87
34
91 80
42 57
50 1
34
38
65 1 6
27 1 1
22 7 5
27 12
26 18
54
45
125
55
42 16 4
12
42 t 15
53
54
55 2 1
1 1 1
56 14 7 1 2 1 1 3 1 3 2 1 2 2 12 c 1
57 1 1 1 2 2 1
58
194
63
102
59 23
5
60 10 19 2 7 2 6 8 3 2 5 1
18 592 2 33 31
f
61 2 2 2 2 1 1 1 1 1 3 1 1 1 1 7 1 1 6 1
wi
1
3 1
62
63 36 9
20 12
33
46
41 1 1
26 11
855
257
31 41 37
102 12
42
227
493
33
32
165
90
414
36
61 05
134
60
157
203 9
25
32
95 4 7 14
92 43 6 56 32 26 4
49 13 i
36
App
endi
x 2.
MAO
O S
PO
C F
ile
LLliM 234
236
239
239
240
244
246
247
250
253
254
255
256
257
258
259
26
1262
265
266
268
270
273
274
275
276
277
278
280
28
1286
288
290
292
294
296
297
298
299
303
304
308
310
31
1312
313
314
316
319
320
322
324
325
327
329
330
331
332
337
340
.ocallt
y/C
ate
gory
Barn
es
16-8
0H
U69-0
50.8
30
AW
-62
-16
0-3
Barn
es
17-8
072-A
JT
-26
Barn
es
22-8
071-A
BP
-23
72
-AB
P-1
Barn
es
34-8
0A
C-7
1-4
571-A
BP
-1
79-A
BP
-22
72-A
JT
-120A
79
-ER
K-1
272-A
ER
-151
Barn
es
21-8
079-A
BP
-23
Barn
es
20-8
071-A
BP
-12
72-A
ER
-150
72-A
ER
-149
72-A
BP
-26
Barn
es
23-8
071-A
BP
-13A
72-A
BP
-25
72
-AE
R1
47
Barn
es
26-8
0H
U69-0
50.8
36
HU
69
-05
0,8
86
72-A
ER
-146
71-A
BP
-2
72
-AB
P-1
4P
RZ
O71-7
271-A
JT
-46
AC
-71-4
871-A
BP
-11
71-A
BP
-38A
Barn
es
25-8
07
2-A
ER
-94
72
-AE
R-9
972-A
ER
-162
72
-AE
R-1
03
71-A
BP
-3
72-A
ER
-109
71-A
JT
-34
80E
R53
Barn
es
27-8
07
2-A
ER
-85
72-A
ER
-107
AW
-EH
-2
72-A
ER
-106
HU
69
-05
0.8
78
AC
-71-4
7
72
-AE
R-1
65
72
-AB
P-9
72
-AE
R-1
38
80P
B50
AW
-62
-16
0-1
Barn
es
47-8
072-A
ER
-127
um
tem
p 0.3
-1.3 7
1.2
5-1
.67
0.5 1
-1.4
5-1
.45
2.3
-1.4
5-1
.67 1
-1.0
7-0
.05
-0.5
-0.0
50.5
-1.3
2-0
.05
-0.0
5-0
.05
0.5
-1.3
8-1
.38 - 1
0.3
-0.3 2-
1
-1.4
5 1
.44
1.3
1.3
91
.7 1
.44
1.3
9 - 1
1.3
9-1
.39
-1.3
9-1
.39
1.4
5-1
.39
0.7
-0.1 -
1
-0.8
3 0
.83 6
3.9
11.
31
.5-0
.83
0.3
6 1
.46
-0.8
3 7 - 1
0.7
43 1 1 7 4 11
1
44 1 1 1
45 1 9 2 1 1
46
47 1 1 2 12
1 2 22
48
49
50 2 1
51 2 3 10 16
1 1 1 !
52 41 10
32
83
30
120
25
79
21 10
46
35
146 16
82 13
34
46
37
56 10 8
22
74
16
222 8
36 5 9
13 4
124
23
26
19
60 8
19
16 2
54 10
355
326 6 1
10 2 1
119
287 2 t
52
53
54 2
55 2 1 2 1 6
_ 6
56 10 6 1 6 1 4 7 2 16 5 7 2
57 11 5 1 5 2 1 5
1 1 2 2 1 1
16
58 11 145 15
59
4 25 4
60 1 1 2 4 14 4 1 2 7 82 5 2 2 7 1 2 7
59 17 191
39
61
»i i
1 2 6 2 3 1 1 1 51
2 2 28 5 1 7 1 1 1 1 19 32 10 2
24
62
63 23 44
82 26 43 3 65 1 1
26
22 8 4
109 3
172 57 17
30 10 3 40 65 2
187 5
23 13 3
347 9 10 52 8
13 7
20 9 96 6 13
24 17 70
193 3
96
37
App
endi
x 2.
MA
OD
SP
OC
File
LLliM 34
1347
350
351
353
354
355
356
35
936
1362
363
366
369
3/3
3/6
377
362
36
33
84
385
366
38
9390
391
30
?3
94
406
407
40
64
09
411
412
416
41
9420
422
423
424
42
6426
433
436
437
438
439
440
441
444
445
450
454
458
462
463
469
470
473
474
477
.oca
iily/
Cate
gory
72
-AE
R-1
21
72-A
ER
-124
PR
ZO
72-
4471-A
BP
-5
71-A
JT-3
272-A
ER
-70
79
-AB
P-3
472-A
ER
126
Bar
ries
58-8
0B
arrie
s 28
-80
81-A
PB
-24
81-A
BP
-25
71-A
BP
-10
72
-AJT
-41
U?
AIM
12
P
RZ
O 7
2-41
71
-AJT
-33
71-A
BP
-69
tarn
es
56-8
07
2-A
JT-4
2ta
rnes
66-8
0B
arne
s 71
-60
71
-AB
P-3
7A
W-5
7-3
28
-17
71-A
BP
-971
A
RP
34
71
-AB
P-6
07
1-A
BP
-680
ER
7972-A
JT-3
171-A
BP
-33
AW
-57-3
26-9
180
ER
80P
RZ
O 7
1-18
77
1-A
BP
-39
A80
ER
777
1-A
JT-3
580
ER
8171-A
BP
-40B
E. o
l D
rew
PI.
Bar
nes
35-8
080
PB
40B
arne
s 38
-80
Bar
nes
44-8
0B
arne
s 45
-80
72
-AB
P-6
17
2-A
BP
-43
Bar
nes
57-8
07
1-A
BP
-41
AB
arne
s 30
-80
71
-AB
P-3
0B
71
-AB
P-9
07
1-A
BP
-61
A7
1-A
BP
-43
71
-AB
P-6
0T
apka
luk
Pas
sE
iuitk
it P
ass
Nor
thw
ind
63 S
TA
50
71
-AB
P-9
37
1-A
BP
-88
A
um
t»m
p 0.7
0.7 1.5
0.3
6 1 10.
70
.7 1 0-0
.76
-0.7
6-1
.43 0
-1./6
1.2 1
-1.7
5-0
.15 0 - 1
- 1
-1.7
5 3-1
.35
1.05
1.92
-1.2
5-0
.3-0
.32
.45 7
-0.3
-1.7
5 1
.66
3.5
30.
31-1
.43
1.1 1
-0.2
1-1
.43
0.1
60
.38
0.3
80.
210
.16
-0.2
50
.69
-0.2
90
.56
-0.6
7 2-1
.5-1
.6 1 1-
1-0
.6-1
.4
43 1 6
44 1 1 1
45 2
46
47
48 11
49
SO 2
51 3 1 3 1 8 1 2 10
4 1 1 5
52 24
72 3
12
5 3 6 14 27
76
39 3 1
13!
) 2
6 19 5580 20 191
18 22
2 151
10 12 30 7 3 12 25 11 8 12 13 4 13 19 16 14 17 8 2 8 1 4 1 2 £ £
53 1
54
55 1
56 6 3 1 1 15 1 3 4 1 1
34 5 1 1 2
57 1 1 1 1 1 1 1
58
59
60 3 3
416 2 3 1 3 1 2 1 2
13 32 4 j
10
; 3 i
34
61 10 60 1 1 1 9 1 3 1
17 6 1 2 3 1 2 2 4 4 1 1 1 1 4 3 4 1 3
62 1
63 56
194
113 11 34 5 6
22 77 6
50 3
20
23 4
174
19 72 25 3 636 70 43 30
116 1
41 138
21 34 2
11 12 20 610 25 16 29 29
5 1 116
38
App
endi
x 2.
MA
OD
SP
OC
File
LLfiM 478
481
482
483
484
486
486
487
488
489
490
492
493
495
49
6497
49
9500
503
504
505
506
507
508
50
9518
524
528
53
2
Loca
lity/
Cate
gory
Nor
thw
lnd
63
ST
A
51N
o U
nwin
d 63
S
TA
77
Nor
thw
lnd
63
ST
A
79N
orth
wln
d 63
S
TA
71
Nor
thw
lnd
63
ST
A
130
Nor
thw
lnd
63
ST
A
83N
orth
wln
d 63
S
TA
63
Bar
t. LT
33
Haz
el 7
Bar
t. LT
51
Haz
el 6
Nor
thw
lnd
63
ST
A
95N
orth
wln
d 63
S
TA
97
AW
-57-3
28-4
6B
art.
LT 3
5 H
azel
5N
orth
wln
d 16
5N
orth
wln
d 14
5N
orth
wln
d65
ST
A
41N
orth
win
d 13
9B
art.
LT 3
1 H
azel
4A
W-R
-1N
orth
wln
d 63
S
TA
143
Bar
t. LT
23
Haz
el 3
Thu
le,
N.
Sta
.Bay
(2)
Bar
t. N
.Om
enol
uB
art.
LT 2
6 H
azel
2N
orth
wln
d65
ST
A35
Bar
t. LT
52
Haz
el #
1A
W-C
FN
orth
wln
d S
TA
106
Nor
thw
lnd
ST
A11
2T
OT
AL
um
t»m
p - 1
- 1
- 1
1
-1.6
-0.6
0.6 -
1-
1
-1.5
-1,5 5 -
1-1
.5-1
.5 0.6
-1.5 -1 4
-1.5 0 0 0 0 0
-1.5
-1.5 0.5 0
43 45 39 4
360
44 42 1 4
238
45 1 8 12 6
52 41
5 11
10
37
46 2
12
34
47 6 1 4 3
46
0 3 1 716
38
14
75
48 7
507
49 1
20
2
50 23 1
51 18
1 1 4
528
51 4 13 13
23
4
52 1 2 5 18 22 1
37 30 2
25 2
5923
53
58
6
54 17
55 2 12 9
289
56 13
1 3 4 2
614
57 1
10
8
58
4358
59 87
60 2 2 3
13
8 3 2
3951
61 1
38 1
91
5
62
32
1
63 1 2 3
20 6
13
813 39 12
79
22
39
Appe
ndix
2.
MA
OD
SPO
C F
ile
LLfil
o* 1 2 3 4 5 6 7 8 910
1 1
12
14
15
17
18
19
20
21
23
24
26
26
27
28
29
30
31 32
33
34
35
36
37
38
39
40
41
42
43
44
45
47
48
49
50
51 52
53
54
55
56
57
58
59
60
61 62
64
65
Localit
y/C
ate
gory
AW
-OM
1&
2A
W-S
74
5W
hite
B
ea
r H
aze
l 18
AW
-23
99
AW
-2839
AW
-23
65
AW
-27
89
AW
-29
05
AW
-29
04
AW
-23
75
AW
-28
19
AW
-31
43
GV
83033*4
5G
V83033*4
4LA
-81-N
A-9
AW
-31
01
AL
A-8
1-N
A-6
9
AW
-31
61
AW
-31
54
GV
83033
#3
0A
lask
a
66
AW
-IH
25
DC
1-7
9-E
G-1
DC
2-8
0-E
G-7
3
002-8
0
EG
- 18
6B
an.
LT 2
9 H
aze
l 16
Bart
.LT
SO
EG
AL
-75
-KC
-53
BF
M-7
8-1
IKe
rssa
uk
16H
X 1
39 0
04 N
UN
1Ik
ers
sau
k 5
Penney
Ikers
s.H
Ike
rssa
uk
2Ik
erss
auk
4H
X
139
03
3 S
IK 7
HX
139014 P
UN
3H
X 1
39 0
06 N
UN
3
1 IX
1 3
0 0
38
8)
1 2
HX
13
9 0
30
SIK
5H
X 1
39056 V
NQ
1H
X 139051 S
MI6
HX
13
9 0
29
SIK
3H
X
139
02
7 S
IK 2
HX
1390011
NU
N 7
HX
13
9 0
49
SM
I 4
HX
13
9 04
1 S
LI 6
HX
13
9 04
7 S
MI
3B
art
. L
T 2
2B
art.
Cry
stal
H
arbo
urG
V8
20
27
-45
Che
st.
Inle
t 11
HX
139
046
SM
I 2
Bar
t. LT
21
Haz
el
12B
art.
20 L
T 42
Haz
el 1
K1
-78
-BS
-22
SE
A-5
-76-1
56
HU
85-0
27-7
6C
hest
. In
let
95a
Che
st.
Inle
t 3
aum
tem
p11.5 12
9.4
10.5
10.5
11.1 11
10.5
10.5
10.8
11.7
10.5 0
-1.6 9
10.3 9 1
19.7 2 9
9.4 12
13
13
- 1
- 1
13
12
4.6 4 4
3.2 5 5 4 4 4 2 4 1 2 4 4 4 2 2 2 2 2
-1.3
2.1
6 2 0 08.8
8.8 0 -
1
1.6
6
64
65 2 1 8 5 6
11 82
20 2 2
66 3 6 1 5 1
67
145
32
39 3 8 1 1
43 1
23 9
28 9
68 96 13
69 36 1
12 3 1 1 3 1 1
70 3 1 1 6 4 3 6 1 4
71
1
72 1 7
29 5 1 3 1 1 2
73
74 64 7
26
39
46
57
54
75 1
76
:
77 9 18 39 7
611
169 1
26 16 3 1
28 1 3 44 2 3
48 1 5
78 1 1
79 22
254
20
1 1
77
41
166 3
50 6 12 6 1 6 5 3
27 1
31 10 4
43
43
80 15 16 3 4 1
10 5 1
81 56 1 2 3 1
25
120
1 1 2 9 2 7
28
35
82 8
-
83 413
60
42
51
3 11
3 8 2 352 16 4
94 1 1 1 1
-----
1 2
92 5
84 28 11 2 5 1 5 1 1 9 1 1
40
App
endi
x 2.
MA
OO
SP
OC
File
LLIit
e* 66
67
68
69
70
71 72
73
74
75
76
77
78 79 80 81 82
83
84
85
86
87
88
89
90
91 92
93 94 95
96 97
98
99
10
010
110
210
310
410
510
610
710
810
911
011
111
211
311
411
511
611
711
811
91
20
121
122
123
124
125
Lo
calit
y/C
ate
go
ryB
art.
LT 2
0 H
azel
10
Che
st.
Inle
t 2
Che
st.
Inle
t 14
Che
st.
Inle
t 1
Che
st.
Inle
t 7
Cho
st.
Inle
t 6
Che
st.
Inlo
t 5
Che
st.
Inle
t 4
Che
st.
Inle
t 9
S5-7
7-B
S-2
9S
EA
-5-7
5-1
69
AC
hest
. In
lot
15C
hest
. In
let
17C
hest
. In
let
18C
host
. In
lot
16C
hest
. In
let
20C
hest
. In
let
19S
EA
-5-7
8-1
37
GV
82027-8
7S
EA
5-12
SA
HU
81 -
04
5-2
0S
5-7
7-B
S-1
7
tart
. C
oral
ha
rbor
S5
-77
-BS
-16
S5-7
7-B
S-1
8B
art.
98B
art.
97S
5-7
7-B
S-2
7S
EA
-5-7
6-1
74
SE
A-5
-76-
1 310
Alp
ha-H
#9
Alp
ha-H
#4
SE
A-5
-76-7
2A
Che
st.
Inle
t 8
Pen
ney2
7410
1N
orth
win
d 5
Bar
t. 19
Nor
thw
ind
6B
art.
47B
art.
49B
art.
46B
art.
30B
art.
33B
art.
5B
art.
48B
art.
29B
art.
31B
art.
55A
W-3
7-1
61
-51
Bar
t. LT
34
Haz
el #
9N
orth
win
d 63
S
TA
10
Nor
thw
ind
63
ST
A
11A
W-V
6-3
3-7
8-2
1
Nor
thw
ind
63
STA
13
AW
-NN
AW
-62
-16
0-1
1A
W-5
7-3
28-7
0A
W-6
2-1
60-1
0A
W-5
7-3
28-2
8A
W-5
7-3
28-8
0
um
tvm
p 01.
851.
97 - 1
1.24 1.
20.6
71.
09-0
.5 10 101.
991.
262.0
40.
831.
461.
32 12-1
.5 11 0 11 4 10 10 0
.5 0.5 11 1 1
1 1 8 8
8.5
-0.4
9 3 3-
1 3 2 1 3 3 8 3 8 7 8 8 g 8
64
1
65 1 1 2 1 3 1 1
20 1 1
66 3 1 2 1 6 7 2 3 1 2 5 3 1 8 2 5 2 2
67 28
28 3
98 2 6
53 6
76 9 15 14 2 3 4 14 16 69 1 3 3 3 6 3 13
68
69 5 2 1
70
71
72 2 1
171 8 1 3 3 1 2 9 1 4 3 1 1
73
74 92 44 2 2
75 13
76 14 1 7 3 1 1 1 7 27
77 2 1 7 17
1 5 1 1 18
212 4 7
21
2 14
348
52 56
10
8 121 67 32
78 1 2 2 2 2
79 89 19
150 5
30
75
41 109 20 33 14 14 6 103
29
165 2
11 14 414 1 6 18 3
12
13 14
153
76 9 8 4 2 12 24 1 1
180 1
166 1
80 22 7 2 1
15 11 19 3 6 1 5 11 2 13
4
28 16 11 10 10 3
81 53 17 82
24
79 19
101 18 30
26 6 4
38
80
32 99
34 1
60
29 2 9 5 1 3
82 5
26
83 4
34 18 6
47 5 1 6 7 8 1 2 1 8 42 3 3 5 8 10 5 2 2 1
84 4 1 1 1 3 1 4 3 1 3 7 2 1 1
41
App
endi
x 2.
MA
OD
SP
OC
Rle
LL
fiM 126
128
130
131
132
133
134
136
138
139
142
143
144
145
145
147
148
152
155
157
163
164
166
168
169
170
171
172
173
174
176
177
182
183
186
188
193
194
195
196
196
199
200
20
2205
206
210
211
212
216
217
220
221
22
2223
224
225
227
232
233
Loca
lity/
Cate
gory
AC
-71
-27
AW
-62
-16
0-9
HU
69
-05
0,8
25
AC
-71
-8A
C-7
1-7
Ba
rt. #
70H
U6
9-0
50
.82
6H
U6
9-0
50
.83
4A
W-5
7-3
28-3
2A
C-7
1-3
HU
69
-05
0.8
33
PR
2O
70-2
2-23
AC
-71
-10
AW
-62-1
60-8
SE
A-5
-76-1
45
81-A
PB
-13
81-A
PB
-12
81-A
BP
-11
HU
69-0
50.8
19
AC
-71
-1P
R2O
70
-22-
828
1-A
ER
-35
RIC
H
1970
-22
AC
-71
-36
AC
-71
-38
81
-AE
R-3
4A
C-7
1-5
3P
R2O
71-
9481-A
ER
-33
AW
-62
-16
0-7
3RZ
O
70-2
2-90
Nor
lhw
lnd
63
ST
A 5
681-A
ER
-31
81-A
ER
-32
AC
-71-3
7P
RZ
O
70-2
2-94
HU
69-0
50,8
38
PR
ZO
71
-61
PR
ZO
71-
136
81-A
BP
-21
AC
-71-3
9B
art.
LT 2
7 H
azel
8H
U69-0
50.8
61
PR
ZO
70
22-
120
81-A
PB
-20
HU
69
-05
0.8
31
81-A
PB
-19
81-A
PB
-1B
AC
-71
-42
PR
ZO
70
-22-
126
PR
ZO
70
-22-
130
81-A
PB
-17
Bar
nes
18-8
0B
arne
s 19
-80
HU
69
-05
0.8
51
79-A
BP
-14
72-A
BP
-12
HU
69-0
50.8
37
Nor
lhw
lnd
63
ST
A 4
572-A
BP
-11
um
tem
p 4 8 - 1 1 1 2 - 1
-0.5 5
1.5
-1.3
-1.2
5 0 8 10 2 2 2-0
.5-0
.3 - 1
1.3
2.5
2.2 3
0.3
1.5 - 1
- 1 7
-1.5 1.6
-11 2
- 1
-1.2
5 1
.5 0-1
.53 4 3
0.3
-1.7
5-0
.35 0 1 1 2
1.3
-1.3
-0.4
3 10
.5-1
.2-0
.18
-0.4
3-1
.3 0-0
.18
64 3
65
66 1 1 9
67 2
68
69 12
1 1 2 1 1 5 9
25 2 2 4 7 14
70
71 2 1 2
72 1
73
209 3 1 1 6
28 55 14 2 3 1 1 1
18 3 112
1 5 8 2 7 5 1 1 1 6 £
74 16 2 9
75 5 6 4 2 2 1 2 1 4 6 8 1 3 1 3 2 433 1 4
76 22
20 7 3 6 45 35 12 15
77 10 12
419 7
20
193 1 9 2 3 3
23 32
164 3 6
35
312 50 20 ; 5
77 2 7 48 27 5 1 4 6 3 13
3 11 12
1 t
78 3 2 2 2 1 1 1 1 1 1 3 3 4
79 9 15 8 2 1
33
196 17 30 2
44 13
7 2 4 2 16 1 1
10 9 6 5 437
29 17 5 1
36
30 49 10 79 27 1f 19 13 24 t
80 1 3 1 5 4 10 8 2 1
81 1 1 9 10 94 12
2 4 8 41 25 15
1 1
82 4
83 3 3 1 1
84 1
1 2 1
10 1 2 12 12
4 12 5 2 41
1 1 8 6 14
1 9 1 i t 1
42
App
endi
x 2.
MA
OD
SP
OC
Rle
LLfit
e*234
236
239
239
240
244
246
247
250
253
254
255
256
257
258
259
261
262
265
266
?68
270
273
274
275
276
277
278
280
281
286
288
290
292
294
296
297
298
299
303
304
308
310
311
312
313
314
316
319
320
322
324
325
327
329
330
33
1332
337
340
Lo
calit
y/C
ate
go
ryB
arne
s 16
-80
HU
69-0
50,8
30A
W-6
2-1
60
-3ia
rnes
17
-80
72
-AJT
-26
Bar
nes
22-8
071
-AB
P-2
372
-AB
P-1
Bar
nes
34-8
0A
C-7
1-4
571
-AB
P-1
79-A
BP
-22
72
-AJT
-12
0A
79-E
RK
-12
72-A
ER
-151
Bar
nes
21-8
079
-AB
P-2
3B
arne
s 20
-80
71-A
BP
-12
72-A
ER
-150
72-A
FR
-149
/2-A
UP
28
Bar
nes
23-8
071
-AB
P-1
3A72
-AB
P-2
572
-AE
R14
7B
arne
s 26
-80
HU
69 0
50,8
36H
U6
9-0
50
.88
67
2-A
ER
-14
67
1-A
BP
-2
72
-A
BP
-14
PR
ZO
71-7
271-A
JT
-45
AC
-71-4
8
71-A
BP
-11
71-A
BP
-38A
Bar
nes
25-8
072
-AE
R-9
472
-AE
R-9
972
-AE
R-1
6272
-AE
R-1
0371
-AB
P-3
72-A
ER
-109
71-A
JT-3
480
ER
53B
arne
s 27
-80
72-A
ER
-85
72-A
ER
-107
AW
- EH
- 272
-AE
R-1
06H
U69
-050
.878
AC
-71
-47
72-A
ER
-165
72-A
BP
-972
-AE
R-1
3880
PB
50A
W-6
2-1
60
-1B
arne
s 47
-80
72-A
ER
-127
um
tem
p 0.3
-1.3 7
1.2
5-1
.67
0.5 1
-1.4
5-1
.45
2.3
-1.4
5-1
.67 1
-1.0
7 0
.05
-0.5
-0.0
50.5
1.3
2-0
.05
-0.0
5
"~~
0!0
6
0.5
-1.3
8-1
.38 - 1
-0.3
-0.3 2 -1
-1.4
5-1
.44
-1.3
-1.3
91
.7 1
.44
-1.3
9 - 1
-1.3
9-1
.39
-1.3
9-1
.39
-1.4
5-1
.39
0.7
-0.1 -
1
-0.8
3-0
.83 6
3.9
11.
31
.5-0
.83
0.3
6-1
.46
-0.8
3 7-
1
0.7
64
65 1
66 1
67 1 1 1
68
-
69
- -
-
70
71 3 4 7 1 8 1 1 1 1 1
72 20
73 7 1
34 3
32 1
......
....
.? 5 2 1
47 2 1 6 4 1 2
45 t
74 13
1
75 6
" y 2 2 9 7 3
212
76 57
226
112 241 10
104 6
19 2 3 13 5 433
17
"Ts 28 26
139 1 23
... ,
? ! 4
125 22 26 30 50 256 4 1 3
23 131 30 73
77 3 5 8 1 1 5 5 6 2 5 2 g 1 15 15 1
78 2 2 3 1 1 2 2 1 14 1 1 2 3 15
79 7 1 2
48
157 23 6 7 21 50 10 18
21
2 73 4 67 341 49 2 7 7 4
307 3
19 9
19
437 6 9 7 7 7 1 2 7
385 2 2 9 1 1 2 19 2
153 1 11 39
80 10 2 1 7 7 4
81 10
3 6 6 6 3 2 4 7 8 8 1 9 2
12 1
82 1 1 1
83 2 1 2
84 1 2 2 4 5 2 2 1 16 3 8 5 4 2 4
46 9
43
App
endi
x 2.
MA
OO
SP
OC
File
LLIit
e*3
41
347
350
38
1363
354
355
356
359
36
1362
363
368
369
373
376
377
382
383
384
385
386
389
390
391
392
394
406
407
408
409
411
412
416
419
420
422
423
424
425
426
433
436
437
438
439
440
441
444
445
450
454
458
462
463
469
470
473
474
477
Localit
y/C
ate
gory
72
-AE
R-1
21
72
-AE
R-1
24
PR
7O
72-4
4
71-A
BP
-8
71-A
JT
-32
72
-AE
R-7
079-A
BP
-34
72
-AE
R1
26
Barn
es
58-8
0B
arn
es
28-8
0B
1-A
PB
-24
B1
-AB
P-2
571-A
BP
-10
72-A
JT
-41
82
-AE
R-1
2P
RZ
O 7
2-41
71-A
JT
-33
71-A
BP
-69
Barn
es
56-8
072-A
JT
-42
Barn
es
60-8
0B
arn
es
71-8
071-A
BP
-37
AW
-57-3
28-1
77
1-A
BP
-9
71-A
BP
-34
71-A
BP
-50
71
-AB
P-8
80E
R79
72-A
JT
-31
71-A
BP
-33
AW
-57-3
26-9
1
80E
R80
PR
ZO
71-1
87
71-A
BP
-38A
80E
R77
71-A
JT
-35
80E
R81
71
-AB
P-4
0B
E.
of
Dre
w
PI.
Barn
es
35-8
080P
B40
Barn
es
38-8
0B
arn
es
44-8
0B
arn
es
45-8
07
2-A
BP
-61
72-A
BP
-43
Barn
es
57-8
071-A
BP
-41A
Barn
es
30-8
07
1-A
BP
-30
B71-A
BP
-90
71-A
BP
-61A
71-A
BP
-43
71-A
BP
-60
Tapka
luk
Pass
Elu
ltklt
Pa
ssN
ort
hw
lnd
63
S
TA
50
71-A
BP
-93
71-A
BP
-88A
tum
tom
p 0.7
0.7 1.6
0.3
8 1 10
.70.7 1 0
-0.7
6-0
.76
-1.4
3 0-1
.75
1.2 1
-1.7
5-0
.15 0 - 1
- 1
-1.7
5 3-1
.35
1.9
51.9
2-1
.25
0.3
-0.3
2.4
5 7-0
.3
-1.7
5 1
.66
3.5
30.3
1-1
.43
1.1 1
-0.2
1-1
.43
0.1
60.3
B0
.38
0.21
0.1
6-0
.25
0.6
9-0
.29
0.5
6-0
.67 2
-1.5
-1.6 1 1.
1-0
.6-1
.4
64
_..
-
65
66 - 1
67
68
69 1
70 12
71 2 1
72
73 2
22 1
40 6 1 3 2 2 1 2 3 5 5 4 4 1 3 4 1 1
74 3
75 2
20 1 9 1 4 2
23 3
76 54 10 6 2 1 3 11 4 1 6 2
150 2
374 1 16 36 1 2 g
24 43B
31 11 126 1 1 3
1 1
13
77 1
1 4 6 1 6 1 1 2 5 1 2 3 9 1 i 1 2 1 1 1
78 6
1 2 1 3 1 1 1 1 2 1 1 2
79 24
48
12 3 5
81 21 10
14 9 8 2
16 99 15 10 1 4 3 9 4 2 17 1
46 8 7 8 11 1 1
44 12 15 2 IB 1 3 3 1 5 2 3 5
80 1 4 4 1
6 2 1 1 6 2 t 6 i
81
"2
1 3 1 1 1 9 2 1 2 1 1 2 2
82
----- 1
Wl
1
1
83 1 1 2
84 2 10 1 4 2
34 1 5 3 2 1 2 1 1 5
1 1 1 1 1 1 1
App
endi
x 2.
MA
OD
SP
OC
File
LU
ik*
478
48
1482
483
484
485
486
487
488
489
490
492
493
495
496
497
499
500
503
504
505
506
507
508
509
518
524
528
532
Localit
y/C
ate
gory
Nort
hw
lnd
63
S
TA
51
Nort
hw
lnd
63
S
TA
7
7N
ort
hw
lnd
63
S
TA
79
No
rth
wln
d
63
ST
A
71N
ort
hw
lnd
6
3
ST
A
130
No
rth
wln
d
63
S
TA
83
No
rth
wln
d
63
S
TA
6
3B
art.
LT
33
Ha
zel
7B
art.
LT 5
1 H
aze
l 6
Nort
hw
lnd
63
S
TA
95
No
rth
wln
d
63
S
TA
07
AW
-57-3
28-4
6
Bar
t. LT
35
Ha
zel
5N
ort
hw
lnd
165
Nort
hw
lnd
145
Nort
hw
ind65
ST
A
41N
ort
h w
ind
139
Bar
t. LT
31
Ha
zel
4A
W-R
-1
No
rth
wln
d
63
ST
A143
Bar
t. LT
23
Ha
zel
3T
hule
, N
. S
ta B
ay (
2)B
art.
N.O
menolu
Bar
t. LT
26
Haz
el 2
Nort
hw
ind65
ST
A35
Bar
t. LT
52
Haz
el #
1A
W-C
FN
ort
h w
ind
ST
A106
Nonhw
ind
ST
A1
12
TO
TA
L
um
tem
p 1
-1 -1 1
-1.6
-0.5
-0.5
1-1
-1.5
-1.5 5-
1-1
.5-1
.5 0.5
-1.5 -1
4-1
.5 0 0 0 0 0-1
.5-1
.5 0.5 0
64 4
65 1
19
192
66 2 10
33
45 1
23 7
206
67
82
5
68
10
0
69
163
70 41
71 1
38
72 2 5 5 3 4
73
22
24
3
73
700
74
477
75 4 3 5 1
23
0
76 5 7 4
30
30
77 12 8 1 1 1
35
25
42
31 14
1660
78 8 1 1 1 1 1 2 1
125
79 1 1
13 5 4
26 6
26 9
16
45 18
29 1
61
77
80 37 1
1 1
241 28
20
70
2
81 7 3
84 6
41
1 1
10 7
20
30
82 47
83 30
31
1 3 4 15 1
82
8
84 3 1
54 3 4 1
545
45
App
endi
x 2.
MA
OD
SP
OC
File
LLfit
e* 1 2 3 4 5 6 7 8 910 11 12 14 15 17 18 19 20 21 23
24
25
26
27
28
29
30 31 32
33
34
35 36
37 38
39
40
41 42
43
44
45
47
48 49 SO 51 52 S3
54
SS 56 67
58 59
60 61 62 64
65
.oca
llty/
Cate
gory
AW
-OM
1 &
2A
W-S
745
Whi
te
Bea
r H
azel
18
AW
2399
AW
-2839
AW
-2365
AW
-2789
AW
-2905
AW
-2904
AW
-2375
AW
-2819
AW
-3143
GV
83
03
3*4
5G
V8
30
33
*44
LA-8
1 -N
A-9
AW
-3101A
LA-8
1 -N
A-5
9A
W-3
161
AW
-31
54
GV
8303
3 #3
0A
lask
a 66
AW
-IH
25
DC
1-79
-EG
-1D
C2-8
0-E
G-7
3D
C2-8
0-E
G-1
86
Bar
t. LT
29
Haz
el
16H
art.l
TS
OE
GA
L-7
5-K
C-6
3B
FM
-78-
1ke
rssa
uk
ISH
X 1
39 0
04 N
UN
1ke
rssa
uk
5P
enne
y Ik
erss
.JH
Iker
ssau
k 2
Iker
ssau
k 4
HX
139
033
SIK
7H
X 1
39 0
14 P
UN
3H
X 1
39 0
06 N
UN
3H
X 1
39 0
3S S
LI 2
HX
13
9 03
0 S
IK S
HX
13
90
56
VN
G 1
HX
139
051
SM
I 6
HX
13
9 02
9 S
IK 3
HX
139
027
SIK
2H
X 1
3900
11
NU
N 7
HX
139
049
SM
I 4
HX
139
041
S
LI 6
HX
139
047
SM
I 3
Bar
t. LT
22
Bar
t. C
ryst
al
Har
bour
GV
82027-4
5C
hest
. In
let
11H
X 1
39 0
46 S
MI
2B
art.
LT
21
H
azel
12
Bar
t. 20
LT
42
Haz
el
1K
1-7
8-B
S-2
2S
EA
-6-7
6-1
56
HU
85-0
27-7
6C
hest
. In
let
95a
Che
st.
Inle
t 3
tum
tam
p11
.5 12 9.4
10.6
10.5
11.1 1
110
.510
.510
.811
.710
.5 0-1
.6 910
.3 9 11 9.7 2 9
9.4 12 13 13 - 1
1
13 12 4.6 4 4
3.2 5 5 4 4 4 2 4 1 2 4 4 4 2 £ 2 2 2
-1.3
2.1
6 2 0 08.
88.
8 0 .1
.66
85 40 13 1 1 1 2 2
86 4 7 5 9 2 3 1 5 2 110
13
6 S 1 3 i
87 6 1 3 1 1
88 60 1 1 1 1
89
166 1 9 2 2
84 2 4
90 9 31
5 8 1 4 2
91 2 1 2 5 1
111
19
92 3 3
21 12 12118 8 161 1
13
4
93 31
3 610
2 1
20 1 1 1 2 1 12 ;
94 19 4 19 12 411 7 3
46 2
268 16 21 84 5 1 1 1 1 / ;
95 2
96
97
16
3 5 5 3 11
07
26 20
988 40
236
18
9 7 12
2
24 9
39 2 2 1
25
98
202 10 48
405
384
300
210
444
153
242
176
391 1
10
1344
241
200
38
220
429 61 12 44 1 1
742 3 1 6 3 3 1 6 2
17 6
99 7 5
12
27 1 3 2 1 1 1
TO
TA
L 75
6341
570
488
567
387
407
2728
518
424
34
4831
477
481 35
46
45
42
429
791 7
30
61346
56
71
87
156
62
22
3165
97
140
68
19
00
29
91
28
17
726 6
1 7
16 1 1
10 5
26
20
36
26 3
31
520
812
10
912
18
283
30
45
39
498
280
46
App
endi
x 2.
MA
OD
SP
OC
Rle
ILfik
X 66 67
68
69 70 71 72
73
74
75
76 77
78 79 80
81 82 83
84
86
86
87
88
89
90
91 92 93 94
95
96 87
96
99
100
101
102
103
104
105
106
10
710
810
911
011
111
211
311
41
15
116
117
118
119
120
121
122
123
12
412
5
oca
lity/
Ca
teg
ory
Ban
. LT
20
Haz
el
10C
hest
. In
let
2C
hest
. In
let
14C
hest
. In
let
1C
hest
. In
let
7C
hest
. In
let
6C
hest
. In
let
5C
hest
. In
let
4C
hest
. In
let
9S
5-7
7-B
S-2
95
EA
-5-7
5-1
69
AC
hest
. In
let
15C
hest
. In
let
17C
hest
. In
let
18C
hest
. In
let
16C
hest
. In
let
20C
hest
. In
let
19S
EA
-5-7
6-1
37
GV
82027-6
7S
CA
5 I2
5A
HU
81
-04
5-2
0S
5-7
7-B
S-1
7B
art.
Cor
al
harb
orS
5-7
7-B
S-1
6S
5-7
7-B
S-1
8B
art.
98B
art.
97S
5-7
7-B
S-2
7S
EA
-5-7
6-1
74
SE
A-5
-76-1
31D
Alp
ha- H
#9
Alp
hn-H
*4
8E
A-S
-76-7
2A
Che
st.
Inle
t 8
Penney2
74!0
1N
orth
wln
d 5
Bar
t. 19
Nor
thw
lnd
6B
art.
47B
art.
49B
art.
46B
art.
30B
art.
33B
art.
5B
art.
48B
art.
29B
art.
31B
art.
55A
W-3
7-1
61
-51
Bar
t. LT
34
Haz
el #
9N
orth
wln
d 63
S
TA
10
Nor
thw
ind
63
ST
A
11A
W-V
6-3
3-7
8-2
1N
orth
win
d 63
S
TA
13
AW
-NN
AW
-62-1
60-1
1A
W-5
7-3
28-7
0A
W-6
2-1
60-1
0A
W-5
7-3
28
-28
AW
-57-3
28-8
0
um
tom
p 01.
851.
97 - 1
1.24 1.
20
.67
1.09
-0.5 10 10
1.99
1.26
2.0
40.
831.
461.
32 12 1
.5 1 1 0 1 1 4 10 10
-0.5 0.5 11 11 1 1 8 6
6.5
0.4
9 3 3 1 3 1 1 1 2 1 ft 3 8 f. 8 7 8 8 5 8
85 6 13 2
17 1 2 6 1 4 12 7 1 1 1 5
22 1 4 7 3 2 4 2 5 8
86 2 4 7 4 3 3 5 5 3 5
22 1 2 2 8 2 1
13 32
8
87 10
1 2
88 4
1 1 2 2 3 1 2 1 4 1
47 3 1 1 2 1
89
90 22 6 181 4
24 6 6 3 5 2 2 2 1 1 18 29 4
212 1 9
9192 2 3 1 1 3
93 2 6 10 6 5 7
94 15 10
1 2 1 1 3 1 3 3 1 2 1 1 7 1 1 1
12 27 1 8 1
95 2 2
96 1
22
121
97 6 1
1 1 1 2 3 1
15 21
2 5 2 1
113 1
21 44
27 15 34 161 A
98 5 5 18 7 3 7 8 2 27 1
115 5 1 2 7 1 2
28 1 1 14
4 1
99 1 7 1 1
TO
TA
L 336
710
157
11
54
104
32
3768
292
84
3831 71
281
250
19
792
47
13
05
1326
266 2
547
325
66
29
292 3
27
11
350
323
13
52
61186
201
394
120 9
65
453
397
34
9315
343
71
212
347
350 2
29 4 5
2050 1
2055
35
40
13
2 2241
47
App
endi
x 2.
MA
OD
SP
OC
Rle
LUite
*
126
126
130
131
132
133
134
136
138
139
142
143
144
145
145
147
148
152
155
157
163
164
166
168
169
170
171
172
173
174
176
177
182
183
186
188
193
194
195
196
198
199
200
202
205
206
210
211
212
216
217
220
22
1222
223
224
225
227
232
233
Lo
calit
y/C
ate
go
ryA
C-7
1-2
7A
W-6
2-1
60
-91I
J69
050,
825
AC
-71-
6A
C-7
1-7
Bar
t. #7
0H
U6
9-0
50
.82
6H
U6
9-0
50
.83
4A
W-5
7-3
28-3
2A
C-7
1-3
HU
69
-05
0.8
33
PR
ZO
7
0-2
2-2
3A
C-7
1-1
0A
W-6
2-1
60
-8S
EA
-5-7
6-1
45
1-A
PB
-13
Bt-
AP
B-1
281-A
BP
-11
HU
69-0
50.8
19
AC
-71
-1
PR
ZO
70-2
2-8
28
1-A
ER
-35
RIC
H
19
70
-22
AC
-71-3
6A
C-7
1-3
8
81
-AE
R-3
4A
C-7
1-5
3
PR
ZO
71-9
48
1-A
ER
-33
AW
-62
-16
0-7
PR
ZO
7
0-2
2-9
0N
ort
hw
lnd
63
ST
A
568
1-A
ER
-31
81
-AE
R-3
2A
C-7
1-3
7
PR
ZO
70-2
2-0
4H
U6
0-0
50
.83
8P
RZ
O 7
1-61
PR
ZO
71-1
36
81-A
BP
-21
AC
-71-3
9
Bar
t. LT
27
Ha
zel
8H
U6
9-0
50
.86
1P
RZ
O
70
-22
-12
081-A
PB
-20
HU
69-0
50.8
31
81-A
PB
-19
81-A
PB
-18
AC
-71
-42
PR
ZO
70-2
2-1
26
PR
ZO
70-2
2-1
30
81-A
PB
-17
Ba
rrie
s 18-8
0B
arn
es
19-8
0H
U6
9-0
50
.85
178-A
BP
-14
72-A
BP
-12
HU
69
-05
0.8
37
Nort
hw
lnd
63
ST
A
4572-A
BP
-11
tum
tem
p 4 8-
1 1 1 2-
1-0
.5 51.
5-1
.3
-1.2
5 0 810 2 2 2
-0.5
-0.3 -
1
1.3
2.5
2.2 3
0.3 1.5
- 1
- 1 7
-1.5 1.6
1 1 2 . 1
-1.2
5-1
.5 0-1
.53 4 3
0.3
-1.7
5-0
.35 0 1 1 2
1.3
-1.3
-0.4
3 10.
5-1
.2-0
.18
-0.4
3-1
.3 0-0
.18
85
_.
_ 32
2
86 3 2 1 1 1 3 10
2 4 1
87
88 3 1
89 1
90 2 1 2 2 1
91
92 4 1 1 2
93 1 1
94 1 3 1
95 2 1 1
96
170
59 52
97 4 42
98 21
2 3 12
1 1 11
99
TOTA
L 21
033
60
7
6t
61 124 37 39 3
33
70
146
120
130
68
1013
62
7163
338
124
137
212
303
733
607
129
77
464
213
34
038 4
133
189
207
20
2110
308
261
86
01
130
61
265
237
66
36
124
363
228
364
139
281
133
90
40
114
77 3
60
48
App
endi
x 2.
MAO
D S
PO
C F
ile
LUito
*
234
235
239
239
240
244
246
247
250
253
254
255
256
257
258
259
26
1262
265
266
268
270
273
274
275
276
277
278
280
28
1286
288
290
292
294
296
297
298
299
303
304
308
310
311
312
313
314
316
319
320
322
324
325
327
329
330
331
332
337
340
Lo
calit
y/C
ate
go
ryB
arne
s 16
-80
HU
69-0
50.8
30
AW
-62-1
60-3
Bar
nes
17-8
07
2-A
JT-2
6B
arne
s 22
-80
71-A
BP
-23
2-A
BP
-1B
arne
s 34
-80
AC
-71-4
571
-AB
P-1
79-A
BP
-22
72-A
JT-1
20A
79-E
RK
-12
72-A
ER
-151
Bar
nes
21-8
079
-AB
P-2
3B
arne
s 20
-80
71-A
BP
-12
/2-A
EF
M6
072
-AE
R-1
4972
-AB
P-2
6B
arne
s 23
-80
71-A
BP
-13A
72-A
BP
-25
72-A
ER
147
Bar
nes
26-8
0H
U69
-050
.836
H 0
69-0
50,8
8672
-AE
R-1
4671
-AB
P-2
72
-AB
P-1
4P
RZO
71-
727
1-A
JT-4
5A
C-7
1-4
871
-AB
P-1
171
-AB
P-3
8AB
arne
s 25
-80
72-A
ER
-94
72-A
ER
-99
72-A
ER
-162
72-A
ER
-103
71-A
BP
-372
-AE
R-1
0971-A
JT-3
480
ER
53B
arne
s 27
-80
72-A
ER
-85
72-A
ER
-107
AW
-EH
-272
-AE
R-1
08H
U69
-050
.878
AC
-71-4
772
-AE
R-1
6572
-AB
P-9
72-A
ER
-138
80P
B50
AW
-62-1
60-1
Bar
nes
47-8
072
-AE
R-1
27
tum
tom
p 0.3
-1.3 7
1.2
5-1
.67
0.5 1
-1.4
5-1
.45
2.3
-1.4
5-1
.67 1
-1.0
7-0
.05
-0.5
-0.0
50.5
1.3
2 O
.Ob
0.0
5-0
.05
0.5
-1.3
8-1
.38 - 1
-0.3
-0.3 2-
1
-1.4
5 1
.44
-1.3
1.3
91
.7-1
.44
1.3
9-
1
-1.3
9-1
.39
-1.3
9-1
.39
-1.4
5-1
.39
0.7
-0.1 -1
-0.8
3-0
.83 6
3.9
11
.31
.5-0
.83
0.3
6 1
.46
-0.8
3 7-
1
0.7
85 1
86 2 1 3 1 2 6 2 2 2
87 2
88
89
90 1 2 16
91
92 1 1 2 1 1 12
93 1
94 1 1 8
95 1 3
96 3
201 5
97 9
98 25 1 2 2 1 6
24
99 2
TO
TA
L 421
57
28
468
601
112
23
744
215
24
459
154
124
23
047
325
30
405
144
132
167
58
51
117
242
56
13
25
81
71
91 33
49
118
32
1149
53
85
58
475
56
60
70 6
133
33
68
1038
44
733
488
49
130
17
249
95
164
13
46
33
60
26
4
49
App
endi
x 2.
MA
OO
SP
OC
File
Lift
to*
341
347
35
035
1353
35
43
55
35
6359
361
362
363
368
369
373
376
377
382
383
384
385
386
389
39
039
1392
39
4406
407
408
409
411
412
416
419
42
0422
423
424
425
426
433
436
437
438
439
440
441
444
445
45
04
54
458
462
463
469
470
473
474
477
oca
lity/
Ca
teg
ory
2-A
ER
-12
12-A
ER
-124
PR
ZO 7
2-44
1-A
BP
-51
-AJT
-32
2-A
ER
-70
9-A
BP
-34
2-A
ER
126
Bar
nes
58-8
0B
arne
s 28
-80
1-A
PB
-24
1-A
BP
-25
1-A
BP
-10
2-A
JT-4
1
82-A
ER
-12
PR
ZO
72-
417
1-A
JT-3
371-A
BP
-69
Bar
nes
56-8
07
2-A
JT-4
2B
arne
s 66
-80
Bar
nes
71-8
071-A
BP
-37
AW
-57-3
28-1
77
1-A
BP
-971-A
BP
-34
71-A
BP
-50
71-A
BP
-880
ER
7972-A
JT-3
171-A
BP
-33
AW
-57-3
26-9
1
80E
R80
PR
ZO
71
-187
71-A
BP
-39A
80E
R77
71-A
JT-3
580
ER
8171-A
BP
-40B
E. o
l D
rew
PI.
Bar
nes
35-8
080
PB
40B
arne
s 38
-80
Bar
nes
44-8
0B
arne
s 45
-80
72-A
BP
-61
72-A
BP
-43
Bar
nes
57-8
07
1-A
BP
-41
AB
arne
s 30
-80
71-A
BP
-30B
71-A
BP
-90
71
-AB
P-6
1A
71-A
BP
-43
71
-AB
P-6
0T
apka
luk
Pas
sE
lultk
lt P
ass
Nor
thw
lnd
63 S
TA
50
71
-AB
P-9
371-A
BP
-88A
um
tom
p 0.7
0.7
1.5
0.3
6 1 10.
70.
7 1 0-0
.76
-0.7
6-1
.43 0
-1.7
51.
2 1-1
.75
-0.1
5 0 - 1
- 1
-1.7
5 3-1
.35
1.95
1.92
-1.2
5-0
.3-0
.32.
457
-0.3
-1.7
5 1
.66
3.6
30.
31-1
.43
1.1 1
-0.2
1-1
.43
0.1
60.3
80
.38
0.21
0.1
6-0
.25
0.6
9-0
.29
0.5
6-0
.67 <
-1.5
-1.6 1 1.
1-0
.6-1
.4
85 2 1
86 3 1 2 1 1 2 2 1 1 ; 4
87
88
89
90 2 1 1
91
_.
92 1 1 1 1 1 1
93
94 1
95 2
96
97 1
98 1 3 1 2 25 2
99 1 1 12
1TO
TA
L166
40
41291 5
73
168
32
29
27
3200
13
18
3 13
105
72
335
82
46
1271 72
14
57
041
1 67
9119 3
110
97
109
38
16
31
30
20
79
275
61 18
97
44
11
6146
88
351
131 64
183 3
46
16
57 7
53
19
33
119 J
1 9
10
50
App
endi
x 2.
MAO
O S
PO
C R
le
LLfil
e*
478
48
1482
483
484
485
486
487
488
489
490
492
493
495
496
497
499
500
503
504
505
506
507
508
509
518
524
528
532
Lo
calit
y/C
ate
go
ryN
orth
wln
d 63
S
TA 5
1N
orth
wln
d 63
STA
77
Nor
thw
lnd
63 S
TA 7
9N
orth
wln
d 63
STA
71
Nor
thw
lnd
63
STA
13
0N
orth
wln
d 63
STA
83
Nor
thw
lnd
63 S
TA 6
3B
art.
LT 3
3 H
azel
7B
art.
LT 5
1 H
azel
6N
orth
wln
d 63
STA
95
Nor
thw
ind
63 S
TA 9
7A
W-5
7-3
28-4
6B
art.
LT 3
5 H
azel
5N
orth
wln
d 16
5N
orth
wln
d 14
5N
orth
win
d65
STA
41
Nor
thw
lnd
139
Bar
t. LT
31
Haz
el 4
AW
-R-1
Nor
thw
lnd
63
STA
143
Bar
t. LT
23
Haz
el 3
Thul
e, N
. S
ta.B
ay (
2)Ba
rt. N
.Om
enol
uB
art.
LT 2
6 H
azel
2N
ort
hw
lnd65
ST
A35
Bar
t. LT
52
Haze
l #1
AW
-CF
Nort
hw
lnd
ST
A1
06
Nort
hw
lnd
ST
A1
12
TO
TA
L
um
tom
p - 1
- 1
- 1
- 1
-1.5
-0.5
-0.5 -
1-
1-1
.5 1
.5 5 - 1
-1.5
-1.5 0.5
1.5 -1
4 1
.5 0 0 0 0 0-1
.5-1
.5 0.5 0
85 2 3 4 1 8 7 9 2 1
27
2
86 1 1 2
39
7
345
87 6 1 2 83
11
9
88 1
155
89
271
90 2
28
0
91 6 1
49
92 1
372
93 1
143
10 1 1 1
290
94 3 1 3 9 1 2 11
709
95 1 6
23
96
634
97 2 2 76 2 10 5 7
2312
98 1
1 3 20 24 9 2 1 1 2 1
41 78 155
70
35
99 2 1 1 1 1 1
94
TO
TA
L
3 1 2 1 234
38
97
127 4
14
29
9264
28
56
54
39
25
33
18
59
356
82
240
197
18 2
32
3291
416
82152
51