City of Columbia Street Index – 2020 Street Name – Grid Cells

Total Page:16

File Type:pdf, Size:1020Kb

City of Columbia Street Index – 2020 Street Name – Grid Cells City of Columbia Street Index – 2020 Street Name – Grid Cells A Alley - M11 Aaron Dr - O7 Abbey Ln - T15 Abbeywood Dr - O6 Anthony St - M11, M12 Abbington Ct - F5 Appalachian Dr - M5, M6 Abbington Ter - F4, F5 Apple Tree Ct - G9 Abbotsbury Ln - D6 Apple Tree Ln - G9 Abercorn Dr - F5 Apple Valley Ct - O6, P6 Acorn Ct - K5 Apricot Falls - G5 Addison Dr - K5 Arapahoe Cir - P16 Adens Woods Ct - N16 Arapahoe Pl - P16 Affirmed Dr - Q12 Arbor Ct - M15 Again St - N8, N9 Arbor Dr - M15, N15 Agate Way - P17 Arbor Pointe Pkwy - T14, T15, U15 Agronomy Research Dr - J9, K9, K10 Arcaro Ct - Q11 Alan Ln - O16 Arctic Ct - P12 Alaska Ct - P12 Arctic Fox Dr - Q10, R10 Albany Ct - M14 Arctic Wolf Ct - R10 Albany Dr - M14 Argyle Rd - P11 Albatross Ave - Q9 Arlene Dr - K4 Alcott Dr - S12 Arlington St - M6 Aldeah Ave - M9 Armadillo Dr - Q10 Alexander Ave - M9, N9 Armitage Dr - R9 Alfred St - N12 Armstrong Dr - O19 Allen Ln - O11 Arrowwood Dr - Q17 Allen St - N10 Arthur Dr - G12 Allen Walkway - M10, N10 Ascot Way - T14 Alligator Ln - Q10 Ashford Ct - K5 Alpine Dr - P14, Q14 Ashland Rd - K12, L11, L12 Alpine Ridge Dr - S10 Ashley St - O11, O12 Alps Ct - M6 Ashwood Dr - H6 Alsup Dr - K6 Aspen Dr - N8, N9, O8 Altai Dr - M5, M6 Aspen Heights Pkwy - H13, I13 Alton Ave - N11 Aspen Ridge Dr - S10 Amaryllis Ct - N5 Aster Ct - P6 Amazon Dr - Q10, Q11 Astoria Ct - F5 Amberwood Ct - D6 Astoria Way - F5 Amelia St - N12 Athens Ct - O15 American Pkwy - Q11 Atkins Dr - M8, N8 Americus Dr - R12, R13 Atwood Ct - T15 Ames Dr - J11 Auburn Ln - N8 Amethyst Dr - Q17 Audubon Dr - K13, L13 Ammonette St - N12, N13 August Briggs Dr - J17, K17 Amron Ct - P15 Augusta Dr - I8 Anaconda Ct - Q9 Aurora Dr - H10 Anderson Ave - M9, N9 Austin Ave - N10 Andretti Cir - K16, K17 Autumn Ridge Ct - F4 Andrew Geoffrey Ct - K16 Avatar Ct - R12 Andy Dr - P13 Avondale Pl - H9 Angelo Ct - O16 Axis Ct - R17 Angels Rest Way - M3 Azeal St - G12, H12 Anita Ct - M12, T12 Azoros Dr - E8 Annandale Ct - H4 Aztec Blvd - P16, P17 Antelope Dr - Q10 Badger Ct - Q10 Page 1 of 32 City of Columbia Street Index – 2020 Street Name – Grid Cells Bailey Dr - H9 Bedford Dr - K5 Balboa Ln - I10 Beech Cove Ct - I5, I6 Baldwin Pl - P9 Beechwood Dr - Q17, R17 Balkan Ct - M6 Belfair Ct - E7 Ballard Mill Dr - G6 Belinda Alley - I9 Ballenger Ln - O16, P16, Q16 Belinda Ct - I9 Ballenger Pl - N16, O16 Bell Flower Ct - G4 Ballentine Ln - K16 Belle Meade Dr - I8 Ballyneal Ct - L16 Bellerive Ln - K16 Balmoral Ct - I13 Belleview Ct - K8, L8 Balow Wynd - M7 Bellingham Dr - E6 Bamboo Dr - Q10 Belmont St - N12 Bandon Dunes Ct - L16, L17 Benedict Rd - Q16 Banks Ave - N9 Bennett Springs Ct - J10 Banyan Dr - D4, D5 Bennett Springs Dr - J10 Barberry Ave - P5, P6 Bent Grass Way - L18 Barcus Ct - D5, D6 Bent Oak Dr - J5 Barkley Ave - K6 Bentley Ct - P9 Barksdale Mill Dr - G5 Benton St - N10, N9 Barnett Dr - P13 Bentpath Dr - E8, F8 Barnwood Dr - O6 Bergen Dr - M18 Barrington Dr - H9, I9 Berkshire Ct - M5, M6 Barrys Bluff Ct - K3 Bernadette Dr - N7, O6, O7 Baseline Pl - S10 Bernadette Pl - O6, O7 Basin Dr - N6 Berry View Ct - K7 Bass Ave - M11, M12 Berrywood Dr - N14, N15 Bass Pro Dr - O14, P14 Berwick Ct - H8 Basswood Ct - J5 Bethel St - G9, H9, I9 Basswood Dr - J5, K5 Bettina Dr - O9 Bates Creek Ct - K16 Betty Jean Way - G10 Bates Creek Dr - J16, K16, K17 Beulah Dr - P16 Battle Ave - O19, O20, P20 Beverly Dr - O7 Baurichter Dr - H9 Bicknell St - M9 Baxley Dr - G13 Big Bear Blvd - P10, P11 Bay Brook Dr - H12, H13 Big Bear Ct - P10 Bay Hills Dr - M17 Big Sur Blvd - J5 Bay Pointe Ln - M18, N18 Billingsly Dr - G14 Bayfield Dr - O19 Bingham Rd - L10 Bayonne Ct - L6 Birch Bank Ct - I5 Baywood Dr - J5 Birch Rd - L10 Beach Pointe Dr - I5, J5 Birchwood Dr - P16, Q16 Beachview Dr - L7 Birdsong Ln - Q17 Beacon Falls Dr - G4 Birmingham Ct - G7, G8 Bear Bluff Dr - P9 Biscayne Ct - L6 Bear Creek Dr - O10, P10 Bismark Dr - P17 Bear Creek Trl - P10, P11, P12, P13, P8, P9, Q11, Bittersweet Ct - M8 Q12, Q13, Q8, Q9 Bitterwood Dr - I7 Bear Valley Ct - P9 Black Cherry Ct - J13 Bearfield Rd - H13, I13 Black Hills Dr - Q17 Bearing Rd - V16 Black Oak Dr - I6, I7 Beckys Bluff Ct - K3 Black Tail Dr - R17 Page 2 of 32 City of Columbia Street Index – 2020 Street Name – Grid Cells Black Wolf Loop - L17 Brady Pl - K6 Blackberry Ln - I12 Braemore Rd - M6, M7 Blackfoot Rd - P7, Q7 Brandeis Ct - K7 Blackford Ct - G8, H8 Brandon Woods St - G9 Blair Ct - M11 Bray Ave - L5, L6 Blossom Ct - I10 Bray Ct - L5 Blue Cedar Ln - I7 Breakers Ct - H4 Blue Grouse Dr - Q10 Bremerton Ct - D6 Blue Hollow Ct - H5 Brenda Ln - M13 Blue Hollow Dr - H5 Brengman Dr - O19 Blue Ridge Rd - Q10, Q11, Q12, Q13, Q14 Brentwood Dr - J5 Blue Sky Ct - M6 Brett Pl - I9 Blue Spruce Ct - G9 Brewer Dr - M5 Bluegrass Ct - I11 Briarcrest Ct - J10, J9 Bluff Blvd - L13 Briarmont Ave - G14, G15 Bluff Creek Blvd - J13, K13 Brickton Rd - M13, M14 Bluff Creek Dr - I13, I14, J13, J14 Bridgewater Dr - P9 Bluff Dale Dr - L12, L13 Bridle Bend Dr - K18 Bluff Pointe Dr - J13, K13 Bridle Bit Ln - K18 Bob O Link Dr - K13, L13 Bridlewood Ct - F3 Bodie Dr - S11, S12 Bright Star Dr - M4, N4 Bogie Hills Dr - M17 Brighton St - N12 Bold Ruler Ct - S12 Bristol Lake Dr - G13, G14 Bold Ruler Dr - R12, S12 Bristol Lake Pkwy - F14, G14 Bold Venture Dr - R12 Broadfield Dr - M6 Bollard Rd - U16 Broadhead St - N9 Bolstad Ct - U16 Broadway Bluffs Dr - M13 Bolten Ct - R12 Broadway Business Park Ct - M6 Bonny Linn Dr - S14, S15 Broadway Village Dr - M13 Boone Dr - N10 Brockwood Dr - V15 Boone Prairie Dr - Q14 Brogan Cellars Ln - I9 Boone's Crossing Dr - D5 Bromley Cir - L3 Boot Spur Ct - K18 Brook Trout Ct - L4 Bouchelle Ave - L11, L12 Brookedale Ct - G8 Boulder Dr - J11 Brookfield Manor - G7, G8 Boulder Falls Ln - N4, N5 Brookside Ct - M13 Boulder Springs Ct - J10 Brookthorn Ct - G3, G4 Boulder Springs Dr - J10 Brown Station Rd - P13, P14, Q14, R14, S14, S15, Bourbon St - N6 T15, U15, U16 Bourn Ave - L7, M7 Brunswick Dr - R13 Bower Ln - K17 Bryant St - M10, N10 Bowling St - N12, O12 Bryant Walkway - M10 Bowman Ct - D7 Buckeye Dr - G9 Boxwood Ct - Q17 Buckhaven Ct - K5 Boyd Ln - O16 Buckner St - N7 Brackenhill Ct - D6 Bucks Run - L13 Bradbury Dr - M15 Buffington Dr - M5 Braden Dr - J5 Bull Run Dr - N17, N18 Bradford Dr - L8 Bullhead Ln - Q16, Q17 Bradington Dr - F14, G13, G14 Bunker Loop - K17 Bradshaw Ave - K6, L6 Burbank Loop - Q16 Page 3 of 32 City of Columbia Street Index – 2020 Street Name – Grid Cells Burlington St - O12, P12 Carpathian Dr - M6 Burnam Ave - L10 Carpenter Dr - P13 Burning Bush Rd - S10, S11 Carrera Dr - J5 Burnside Dr - N18 Carrick Ct - F8 Burrwood Dr - J9 Carrie Francke Dr - K10, L10, L9 Bushnell Dr - L13 Carrieridge Dr - G9 Butte Creek Dr - G6 Carter Dr - H14 Butterfield Ct - J9 Carter Ln - I10, J10 Butternut Ct - I13, J13 Carthage Ct - P9 Button Buck Cir - R17 Cartman Rd - U16, V16 Buttonwood Access - H10 Cartwright Ln - H14 Buttonwood Dr - H10, H11, I10, I11 Casa Cir - J4 Buxton Ln - S12 Cascades Dr - D6, D7, E6, E7 Caesar Rd - R14, S14 Cash's Crossing - K18, K19 Calder Ct - H13 Cass Dr - P17 Caleb Ct - K4 Castle Bay Pl - G8 Caledon Ct - K3 Castle Rock Ct - K7 Calico Ln - P13 Castlewood Ct - M4 Caliente Ct - I13 Catalpa Ct - J13 Callaway Dr - O16, P16 Cattle Dr - L12 Callie Dr - L5 Caymus Ct - L18 Calumet Dr - I13 Cecil St - H12 Calvert Dr - O13 Cedar Cliff Dr - Q7 Calvin Dr - M13 Cedar Coals Ct - K4 Cambridge Dr - L6, M6 Cedar Crest Ln - J5 Camden Cir - M18, N17, N18 Cedar Falls Ct - N4, N5 Camel Ct - Q10 Cedar Falls Ln - N4 Cameron Ct - K5 Cedar Lake Ct - G9 Campusview Dr - J10, J11 Cedar Ln - M15, N15 Canaveral Dr - N17, N18 Cedar Ridge Dr - G9 Candlewood Dr - Q17, Q18 Cedar Rock Ct - K4 Caniff Cir - K12 Celebrant Ct - R10 Cannery Row Ct - Q6 Centennial Ct - J9 Cannon Ct - Q13 Center Brook Ct - F4 Canter Ct - G4 Centerstate Dr - O14, P14 Canterbury Dr - I8, I9 Chadwick Ct - H8 Canton Dr - K5, L5 Chadwick Dr - H8 Canyata Ct - H4 Chairman Dr - F10 Canyon Dr - K12 Chalmers Rd - M7 Canyon Ridge Dr - Q16 Chamberlain Ln - D6 Cape Cod Ct - H9 Chambray Ct - K5 Capen Park Dr - K11 Chambray Rd - J5, K5 Capri Dr - M12 Chameleon Ct - Q9, R9 Cardinal Dr - K13, K14 Chamois Dr - G4 Caribou Dr - P10, Q10 Champions Dr - K10, K11 Carlisle Ct - G13, G14 Champlain Ct - H9 Carlson Strollway - H14 Chancellor Cir - R10 Carmello Rock Dr - Q6 Chantilly Ct - K8 Carnation Dr - P7 Chapel Hill Rd - K3, K4, K5, K6, K7, K8 Carol Dr - O16, P16 Chapel Hollow Ct - K6 Carolina Dr - S12 Chapel Plaza Ct - J8, K8 Page 4 of 32 City of Columbia Street Index – 2020 Street Name – Grid Cells Chapel Ridge Rd - K6 Club Ct - N12, N13 Chapel Wood Rd - K6 Club Meadows Dr - I8 Chapel Wood Ter - K6 Club Village Dr - H8, H9 Chapel Wood View - K6 Clybourne Ct - G3 Chariton Dr - O17, P16, P17 Clydesdale Dr - Q9, R9 Charles St - N12 Coats St - N11, O11 Chateau Rd - T15, T16, U16 Cobble Creek Dr - J18, K18 Chatham Dr - H9, I9 Cobblestone Ct - K5 Chatsworth Dr - M15 Cochero Ct - G4 Cheetah Dr - Q10, Q11 Cocoa Ct - O15 Chelan Cir - E7 Cody Ct - F4 Chelan Dr - E6, E7 Coho Ct - L4 Cheltenham Dr - J13, J14 Colby Dr - L8 Cherokee Ln - P17 Colgate - L7, M7 Cherry Blossom Ln - N17 Coliseum Blvd - S13 Cherry Hill Dr - K5 College Park Dr - K7, L7 Cherry Ridge Ct - K7 Colonial Ct - O13 Cherry Ridge Ln - K7 Colony Dr - J8, K8 Cherry St - M10, M11 Colorado Ave - O10 Cheryl Ct - K4 COLT Railroad - M11, N11, N12, O12, O13, P13, Cheryl Way - T12 P14, Q14, R14, R15, S15, T15, T16, U15, U16, Chesapeake Ln - S12 V16, W16, X16 Cheshire Ct - K5 Columbia Dr - L13, M13 Chesterfield Dr - G7 Columbia Gorge Pkwy - J16, J17 Chestnut Dr - T15 Columbine Ct - J9 Chickasaw Dr -
Recommended publications
  • Monadnock Vol. 45 | June 1971
    THE MONADNOCK I - L. .RK UNIVERSITY Vol. XLV )GRAPHICAL SOCIETY June, 1971 THE MQNADNOCK Volume XIN Editor, Edwin T. Wei5e, Jr. Aaooite Editor5 James FOnSeOa Kirsten Haring David Seairøn Photoqzapher, Ernie Wight ypists Ronnie Mason Phyllis sczynski 323812 ii ‘7f THE MONADNOCK CONTENTs . 2 DIRECT0I MESSAGE THE JESUITS IN NORTH AMERICA: A STUDY . IN ENVIRONMENTAL COCEUALIZATI Eenry Aay 4 STRUCTURE IN TRANSACTION SYSTEMS. .Christopher Clayton 9 CULTURE AND AGRICULTURE ON THE ANEPJCAN NTIER Brad Baltensperger 22 THE PROBABILISTIC APPROACH TO SPATIAL THEORY Kang-tsung Chang 30 AROHITECTURE AND GEOGRAPHICAL STUDIES: A REVIEW Stephen Hobart 36 AN ESSAY ON GROWTH POLE THEORY B. David Miller 40 MIND, MEANING, AND MILIEU: PSYCHOLOGICAL NEED AND DESIGRED ENVIRONMENTS Ernest A. Wight Jr 43 SPATIAL DYNAMICS IN CLASSICAL LOCATION THEORY Alfred Hecht 52 THE GRADUATE SCHOOL OF GEOGRAPHY 56 ALUMNI NEWS 65 A N(YTE ON THE QUESTIONNAIRE 80 :1 DIRECTOR’S MESSAGE This academic year is very special for Geography at Clark, marking the fiftieth year of the founding of the Graduate School of Geography by Wallace W. Atwood. Dedication of the new Geography facilities — with special recognition to the memory of John K. Wright, Historical Geographer and Geosophist, an adopted son of Clark — is one appropriate mode of celebration. Another mark of the occasion is the honor accorded to two major figures in American Geography: Clark could not have chosen two more distinguished geographers than Richard Hartshorne and Samuel Van Valkenburg on whom were bestowed .1 . - Honorary Doctorates of Law at the anniversary ceremonies of April .17th. Very different in their contributions and their characters, Richard Hartshorne provided American geography with its philosophic and method ological rationale and Dr.
    [Show full text]
  • Glossary Glossary
    Glossary Glossary Albedo A measure of an object’s reflectivity. A pure white reflecting surface has an albedo of 1.0 (100%). A pitch-black, nonreflecting surface has an albedo of 0.0. The Moon is a fairly dark object with a combined albedo of 0.07 (reflecting 7% of the sunlight that falls upon it). The albedo range of the lunar maria is between 0.05 and 0.08. The brighter highlands have an albedo range from 0.09 to 0.15. Anorthosite Rocks rich in the mineral feldspar, making up much of the Moon’s bright highland regions. Aperture The diameter of a telescope’s objective lens or primary mirror. Apogee The point in the Moon’s orbit where it is furthest from the Earth. At apogee, the Moon can reach a maximum distance of 406,700 km from the Earth. Apollo The manned lunar program of the United States. Between July 1969 and December 1972, six Apollo missions landed on the Moon, allowing a total of 12 astronauts to explore its surface. Asteroid A minor planet. A large solid body of rock in orbit around the Sun. Banded crater A crater that displays dusky linear tracts on its inner walls and/or floor. 250 Basalt A dark, fine-grained volcanic rock, low in silicon, with a low viscosity. Basaltic material fills many of the Moon’s major basins, especially on the near side. Glossary Basin A very large circular impact structure (usually comprising multiple concentric rings) that usually displays some degree of flooding with lava. The largest and most conspicuous lava- flooded basins on the Moon are found on the near side, and most are filled to their outer edges with mare basalts.
    [Show full text]
  • March 21–25, 2016
    FORTY-SEVENTH LUNAR AND PLANETARY SCIENCE CONFERENCE PROGRAM OF TECHNICAL SESSIONS MARCH 21–25, 2016 The Woodlands Waterway Marriott Hotel and Convention Center The Woodlands, Texas INSTITUTIONAL SUPPORT Universities Space Research Association Lunar and Planetary Institute National Aeronautics and Space Administration CONFERENCE CO-CHAIRS Stephen Mackwell, Lunar and Planetary Institute Eileen Stansbery, NASA Johnson Space Center PROGRAM COMMITTEE CHAIRS David Draper, NASA Johnson Space Center Walter Kiefer, Lunar and Planetary Institute PROGRAM COMMITTEE P. Doug Archer, NASA Johnson Space Center Nicolas LeCorvec, Lunar and Planetary Institute Katherine Bermingham, University of Maryland Yo Matsubara, Smithsonian Institute Janice Bishop, SETI and NASA Ames Research Center Francis McCubbin, NASA Johnson Space Center Jeremy Boyce, University of California, Los Angeles Andrew Needham, Carnegie Institution of Washington Lisa Danielson, NASA Johnson Space Center Lan-Anh Nguyen, NASA Johnson Space Center Deepak Dhingra, University of Idaho Paul Niles, NASA Johnson Space Center Stephen Elardo, Carnegie Institution of Washington Dorothy Oehler, NASA Johnson Space Center Marc Fries, NASA Johnson Space Center D. Alex Patthoff, Jet Propulsion Laboratory Cyrena Goodrich, Lunar and Planetary Institute Elizabeth Rampe, Aerodyne Industries, Jacobs JETS at John Gruener, NASA Johnson Space Center NASA Johnson Space Center Justin Hagerty, U.S. Geological Survey Carol Raymond, Jet Propulsion Laboratory Lindsay Hays, Jet Propulsion Laboratory Paul Schenk,
    [Show full text]
  • A Study About the Temporal Constraints on the Martian Yardangs’ Development in Medusae Fossae Formation
    remote sensing Article A Study about the Temporal Constraints on the Martian Yardangs’ Development in Medusae Fossae Formation Jia Liu 1,2 , Zongyu Yue 1,3,*, Kaichang Di 1,3 , Sheng Gou 1,4 and Shengli Niu 4 1 State Key Laboratory of Remote Sensing Science, Aerospace Information Research Institute, Chinese Academy of Sciences, Beijing 100101, China; [email protected] (J.L.); [email protected] (K.D.); [email protected] (S.G.) 2 University of Chinese Academy of Sciences, Beijing 100049, China 3 CAS Center for Excellence in Comparative Planetology, Hefei 230026, China 4 State Key Laboratory of Lunar and Planetary Sciences, Macau University of Science and Technology, Macau 999078, China; [email protected] * Correspondence: [email protected]; Tel.: +86-10-64889553 Abstract: The age of Mars yardangs is significant in studying their development and the evolution of paleoclimate conditions. For planetary surface or landforms, a common method for dating is based on the frequency and size distribution of all the superposed craters after they are formed. However, there is usually a long duration for the yardangs’ formation, and they will alter the superposed craters, making it impossible to give a reliable dating result with the method. An indirect method by analyzing the ages of the superposed layered ejecta was devised in the research. First, the layered ejecta that are superposed on and not altered by the yardangs are identified and mapped. Then, the ages of the layered ejecta are derived according to the crater frequency and size distribution on them. These ages indicate that the yardangs ceased development by these times, and the ages are valuable for studying the evolution of the yardangs.
    [Show full text]
  • Proceedings of the United States National Museum
    Proceedings of the United States National Museum SMITHSONIAN INSTITUTION • WASHINGTON, D.C. Volume 123 1967 Number 3604 Revision of the Beetles Of Genus Glyptoscelis (Coleoptera: Chrysomelidae) By Doris H. Blake Honorary Research Associate, Department of Entomology In a paper on the Coleoptera of Fort Tejon, Calif. (Proc. Acad. Nat. Sci. Philadelphia, vol. 9, p. 81, 1859), LeConte briefly de- scribed the genus Glyptoscelis as follows: "The genus Glyptoscelis (Chevrolat) [Dejean Catalogue, 3rd ed., p. 438, nomen nudum, 1837] is distinguished from the other genera allied to Eumolpus by the mouth not being covered beneath by the presternum, by the claws being toothed, and by the tibiae being longitudinally sulcate. The head is not sculptured as in Heteraspis [Graphops]." The first species, pubescens, was described as early as 1777 by Fabri- cius under Eumolpus. Linneaus in 1788 gave this species another name, and he was followed by Olivier in 1808 with still another specific name, and our own early American entomologist, Thomas Say, in 1827 gave a fourth name to this species, which is widespread over the eastern half of the United States. Say also described two other species from the eastern and middle states under Eumolpus. In LeConte's paper of 1859 he described Glyptoscelis albida, the first species from the West Coast. In 1878, nearly 20 years later, he de- scribed G. longior, a second western species. In the meantime, in l 2 PROCEEDINGS OF THE NATIONAL MUSEUM vol. 123 1873, Crotch, adopting LeConte's generic name Glyptoscelis, de- scribed from California three more species of this predominately West Coast genus.
    [Show full text]
  • Adams Adkinson Aeschlimann Aisslinger Akkermann
    BUSCAPRONTA www.buscapronta.com ARQUIVO 27 DE PESQUISAS GENEALÓGICAS 189 PÁGINAS – MÉDIA DE 60.800 SOBRENOMES/OCORRÊNCIA Para pesquisar, utilize a ferramenta EDITAR/LOCALIZAR do WORD. A cada vez que você clicar ENTER e aparecer o sobrenome pesquisado GRIFADO (FUNDO PRETO) corresponderá um endereço Internet correspondente que foi pesquisado por nossa equipe. Ao solicitar seus endereços de acesso Internet, informe o SOBRENOME PESQUISADO, o número do ARQUIVO BUSCAPRONTA DIV ou BUSCAPRONTA GEN correspondente e o número de vezes em que encontrou o SOBRENOME PESQUISADO. Número eventualmente existente à direita do sobrenome (e na mesma linha) indica número de pessoas com aquele sobrenome cujas informações genealógicas são apresentadas. O valor de cada endereço Internet solicitado está em nosso site www.buscapronta.com . Para dados especificamente de registros gerais pesquise nos arquivos BUSCAPRONTA DIV. ATENÇÃO: Quando pesquisar em nossos arquivos, ao digitar o sobrenome procurado, faça- o, sempre que julgar necessário, COM E SEM os acentos agudo, grave, circunflexo, crase, til e trema. Sobrenomes com (ç) cedilha, digite também somente com (c) ou com dois esses (ss). Sobrenomes com dois esses (ss), digite com somente um esse (s) e com (ç). (ZZ) digite, também (Z) e vice-versa. (LL) digite, também (L) e vice-versa. Van Wolfgang – pesquise Wolfgang (faça o mesmo com outros complementos: Van der, De la etc) Sobrenomes compostos ( Mendes Caldeira) pesquise separadamente: MENDES e depois CALDEIRA. Tendo dificuldade com caracter Ø HAMMERSHØY – pesquise HAMMERSH HØJBJERG – pesquise JBJERG BUSCAPRONTA não reproduz dados genealógicos das pessoas, sendo necessário acessar os documentos Internet correspondentes para obter tais dados e informações. DESEJAMOS PLENO SUCESSO EM SUA PESQUISA.
    [Show full text]
  • The W.A.S.P the Warren Astronomical Society Paper
    Vol. 49, no. 11 November, 2018 The W.A.S.P The Warren Astronomical Society Paper President Jeff MacLeod [email protected] The Warren Astronomical Society First Vice President Jonathan Kade [email protected] Second Vice President Joe Tocco [email protected] Founded: 1961 Treasurer Ruth Huellmantel [email protected] P.O. Box 1505 Secretary Jerry Voorheis [email protected] Outreach Diane Hall [email protected] Warren, Michigan 48090-1505 Publications Brian Thieme [email protected] www.warrenastro.org Entire board [email protected] Photo credit: Joe Tocco 1 Society Meeting Times Astronomy presentations and lectures twice each month at 7:30 PM: First Monday at Cranbrook Institute of November Discussion Science. Group Meeting Third Thursday at Macomb Community College - South Campus Building E (Library) Come on over, and talk astronomy, space Note: for the rest of 2018, we are meeting in news, and whatnot! room E308, in building E. The Discussion Group meeting for November will be at Jon Blum’s home on Tuesday, November 20, at 7:00 PM. Jon has been Snack Volunteer hosting this every November for several years, Schedule so come and be part of the annual photo. Jon will provide lots of snacks, so please don’t Nov 5 Cranbrook Jim Shedlowsky bring any food or drinks. Jon’s home is in Nov 15 Macomb Riyad Matti Farmington Hills. Dec 3 Cranbrook Joe Tocco If you do not receive the address and directions If you are unable to bring the snacks on your in your email a week before this event, please scheduled day, or if you need to reschedule, email [email protected] for this information.
    [Show full text]
  • Complete Dissertation
    VU Research Portal The lunar crust Martinot, Melissa 2019 document version Publisher's PDF, also known as Version of record Link to publication in VU Research Portal citation for published version (APA) Martinot, M. (2019). The lunar crust: A study of the lunar crust composition and organisation with spectroscopic data from the Moon Mineralogy Mapper. General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. • Users may download and print one copy of any publication from the public portal for the purpose of private study or research. • You may not further distribute the material or use it for any profit-making activity or commercial gain • You may freely distribute the URL identifying the publication in the public portal ? Take down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. E-mail address: [email protected] Download date: 10. Oct. 2021 VRIJE UNIVERSITEIT THE LUNAR CRUST A study of the lunar crust composition and organisation with spectroscopic data from the Moon Mineralogy Mapper ACADEMISCH PROEFSCHRIFT ter verkrijging van de graad Doctor of Philosophy aan de Vrije Universiteit Amsterdam, op gezag van de rector magnificus prof.dr. V. Subramaniam, in het openbaar te verdedigen ten overstaan van de promotiecommissie van de Faculteit der Bètawetenschappen op maandag 7 oktober 2019 om 13.45 uur in de aula van de universiteit, De Boelelaan 1105 door Mélissa Martinot geboren te Die, Frankrijk promotoren: prof.dr.
    [Show full text]
  • Historical Research in the National Park Service
    CULTURAL RESOURCE MANAGEMENT VOLUME 22 NO. I 1999 CRM SUPPLEMENT Historical Research in the National Park Service This is a list of recent and current historical research projects sponsored or sup­ ported by or related to the National Park Service. It encompasses work in progress during 1997-1998 and work completed during this period that was not listed in last year's supplement. PUBLISHED BY THE ALASKA REGION NATIONAL PARK SERVICE General ISSN 1068-4999 Catton, Theodore, Inhabited Wilderness: Indians, Eskimos, and National To promote and maintain high standards Parks in Alaska. Albuquerque: University of New Mexico Press, 1998. for preserving and managing cultural resources Cook, Linda, Denise Chaffee, and Brad Wolf, Alaska Goldrush NHLs: The Stampede North (brochure), 1998. DIRECTOR Cook, Linda, et al., ElmendorfAir Force Base World War II Context and Robert Stanton National Register Eligibility Study, 2 vols., 1998. ASSOCIATE DIRECTOR Hovis, Logan, history of explosives, in progress. Katherine H. Stevenson Norris, Frank, "Gold Rush-Era Mining Sites in Alaska's National Parks," EDITOR CRM 21, no. 7(1998). Ronald M. Greenberg Norris, Frank, "Tourism in Alaska's National Parks," paper at Alaska Environmental History Conference, 1998. Norris, Frank, "Tourism, Mining, and the Evolving Gold Rush Landscape," International Symposium on Mining, Proceedings Publication, 1997. Norris, Frank, "The Yukon in Celluloid," Alaska Geographic 25, no. 2 (1998). Norris, Frank, ed., Communities in Transition, Alaska Historical Society 1997 Annual Conference Proceedings, 1998. Aniakchak National Monument/National Preserve Norris, Frank, "Aniakchak Bay, A Cultural Landscape Based on Fishing," SHA Newsletter 31 (Spring 1998). Bering Land Bridge National Monument Hovis, Logan, Utica Mining District National Historic Landmark nomination, in progress.
    [Show full text]
  • Dissertation Calibration of the Pierre Auger Observatory Fluorescence
    Dissertation Calibration of the Pierre Auger Observatory Fluorescence Detectors and the Effect on Measurements Submitted by Ben Gookin Department of Physics In partial fulfillment of the requirements For the Degree of Doctor of Philosophy Colorado State University Fort Collins, Colorado Summer 2015 Doctoral Committee: Advisor: John Harton Walter Toki Kristen Buchanan Carmen Menoni Copyright by Ben Gookin 2015 All Rights Reserved Abstract Calibration of the Pierre Auger Observatory Fluorescence Detectors and the Effect on Measurements The Pierre Auger Observatory is a high-energy cosmic ray observatory located in Malarg¨ue, Mendoza, Argentina. It is used to probe the highest energy particles in the Universe, with energies greater than 1018 eV, which strike the Earth constantly. The observatory uses two techniques to observe the air shower initiated by a cosmic ray: a surface detector composed of an array of more than 1600 water Cherenkov tanks covering 3000 km2, and 27 nitrogen fluorescence telescopes overlooking this array. The Cherenkov detectors run all the time and therefore have high statistics on the air showers. The fluorescence detectors run only on clear moonless nights, but observe the longitudinal development of the air shower and make a calorimetric measure of its energy. The energy measurement from the the fluorescence detectors is used to cross calibrate the surface detectors, and makes the measurements made by the Auger Observatory surface detector highly model-independent. The calibration of the fluorescence detectors is then of the utmost importance to the measurements of the Ob- servatory. Described here are the methods of the absolute and multi-wavelength calibration of the fluorescence detectors, and improvements in each leading to a reduction in calibration uncertainties to 4% and 3.5%, respectively.
    [Show full text]
  • Ingrid J. Daubar - C.V
    Ingrid J. Daubar - C.V. Ingrid J. Daubar CURRICULUM VITAE Contact Information Brown University Office: 401-863-1437 Campus Box 1846 Cell: 520-245-8608 Lincoln Field 108 [email protected] Providence, RI 02912-1846 http://www.lpl.arizona.edu/~ingrid/ Education Doctor of Philosophy, Planetary Sciences University of Arizona, August 2014 Dissertation: New Dated Craters on Mars and the Moon: Studies of the Freshest Craters in the Solar System Master's of Science, Planetary Sciences University of Arizona, August 2002 Thesis: Northwest Africa 482: A Lunar Meteorite from the Highlands Bachelor of Arts, Astronomy Cornell University, May 1999 Selected Honors and Awards JPL Group Achievement Award, Juno Mission Re-Design, 2018 JPL Voyager Award, 2017 JPL Team Award, Juno Radiation Monitoring Investigation Team, 2017 JPL Team Award, Europa Clipper Investigation Scientists, 2017 Editors' Citation for Excellence in Refereeing, Journal of Geophysical Research-Planets, 2016 NASA Postdoctoral Program Fellowship, 2014-2015 Wiley-Blackwell Award, 2014 Nininger Meteorite Award, 2014 Emily Krauz Staff Endowment Fund Scholarship, 2014 Shandel Education Plus Fund award, 2012 University of Arizona College of Science Galileo Circle Scholar, 2011 Group Achievement Award, MRO HiRISE Science Team, 2011 University of Arizona College of Science Graduate Student Award for Outstanding Service/Outreach, 2011 Lunar & Planetary Laboratory Career Staff Excellence Award, 2008 Graduate Teaching Excellence Award, Spring 2000 Mission Experience 2014-current: InSight mission Co-Lead for the Impacts Science Theme Working Group Deputy Lead, Instrument Site Selection Working Group Landing site certification and safety assessment Impact detection and localization Science planning 2016-current: Europa mission Investigation Scientist for the Europa Imaging System (EIS) 1 of 11 Ingrid J.
    [Show full text]
  • Cometary and Meteorite Swarm Impact on Planetary Surfaces
    JOURNAL OF GEOPHYSICAL RESEARCH, VOL. 87, NO. B8, PAGES 6668-6680, AUGUST 10, 1982 Cometary and Meteorite Swarm Impact on Planetary Surfaces JOHN D. O'KEEFE AND THOMAS J. AHRENS SeismologicalLaboratory, Division of Geologicaland Planetary Sciences California Institute of Technology,Pasadena, California 9! ! 25 The velocity flow fields, energy partitioning, and ejecta distributions resulting from impact of porous (fragmented)icy cometarynuclei with silicateplanetary surfaces at speedsfrom 5 to 45 km/s are different thanthose resulting from the impactof solidice or silicatemeteorites. The impactof ! g/cm3 icespheres onto an atmospherelessanorthosite planetary surface inducescratering flows that appear similar to those induced by normal density anorthositemeteorite impact. Both of these impactors lead to deep transient cratercavities for final craterdiameters less than ---! to ---10 km and for escapevelocities •<!0 -s cm/s. Moreover the fraction of internal energy partitioned into the planetary surface at the cratering site is 0.6 for both ice and anorthositeimpactors at 15 km/s. As the assumeddensity of the hypotheticalcometary nucleusor fragmentcloud from a nucleusdecreases to 0.01 g/cm3, the fractionof the impactenergy parti- tioned into planetary surface internal energy decreasesto lessthan 0.01, and the flow field displaysa toroidal behavior in which the apparent sourceof the flow appearsto emanate from a disc or ringlike region rather than from a single point, as in the explosivecratering case. The edges of the crater region are in several casesdepressed and flow downward,whereas the center of the crater region is uplifted. Moreover,the resul- tant postimpactparticle velocity flow in some cases indicates the formation of concentricridges, a central peak, and a distinct absenceof a deep transientcavity.
    [Show full text]