21 research outputs found
Around the world with professor Vening Meinesz onboard the submarine K-XVIII
In November 1934, Den Helder, The Netherlands, the start of a remarkable voyage commenced. The Hr. Ms.K-XVIII, a Dutch submarine, was about to set sail to Soerabaya, Indonesia. Onboard was a Dutch professor, Felix Andries Vening Meinesz. He was able to measure the Earth’s gravity field with similar precision as on land for the first time in history using his innovative pendulum apparatus. His ground breaking data and systematic way of working changed the way of performing scientific expeditions.Astrodynamics & Space MissionsMathematical Geodesy and PositioningPhysical and Space GeodesyLibrary Education Service
Acute Appendicitis, Somatosensory Disturbances (“Head Zones”), and the Differential Diagnosis of Anterior Cutaneous Nerve Entrapment Syndrome (ACNES)
National Gravity Compilation 2019 DGIR tilt grid
Maintenance and Update Frequency: notPlannedStatement: This National Gravity Compilation 2019 DGIR tilt grid is produced from the 2019 Australian National Gravity Grids A series. These gravity data were acquired under the project No. 202008. The grid has a cell size of 0.00417 degrees (approximately 435m). The %%MV_DATASETS/SURVEY_NAME% were derived from ground observations stored in the Australian National Gravity Database (ANGD) as at September 2019, supplemented by offshore data sourced from v28.1 of the Global Gravity grid developed at Scripps Institution of Oceanography, University of California at San Diego using data from the United States SIO, NOAA and NGA (Sandwell et al., 2014). Out of the approximately 1.8 million gravity observations, nearly 1.4 million gravity stations in the ANGD together with marine data were used to generate this grid. The ground gravity data used in the national grid have been acquired by the Commonwealth, State and Territory Governments, the mining and exploration industry, universities and research organisations from the 1940's to the present day. Station spacing varies from approximately 11 km down to less than 1 km, with major parts of the continent having station spacing between 2.5 and 7 km. The grid shows a tilt of the de-trended global isostatic residual anomalies (A series) over Australia and its continental margins. The DGIR grid was obtained by subtracting 3 quantities (i.e., the near-field isostatic correction, the far-field isostatic correction, and a first order trend correction) from Complete Bouguer Anomaly data (CBA) of the 2019 Australian National Gravity Grids A series. The CBA values were obtained using the methodology given in Hinze et al. (2005). The horizontal and vertical datum was GDA94 (GRS80 ellipsoid) and the gravity datum was AAGD07 (Tracey et al., 2007). The near-field isostatic response is the gravity response of a density contrast across an isostatic root surface for a flat Earth out to a radius of 166.7 km. The isostatic root surface was derived from the topographic and bathymetric dataset compiled by Whiteway (2009), supplemented by ETOPO1 data (Amante and Eakins, 2009). The calculations were performed with software based on the AIRYROOT program (Simpson et al., 1983; Simpson et al., 1986) which uses a one-dimensional Airy-Heiskanen model of isostatic balance (Airy, 1855; Heiskanen and Vening Meinesz, 1958). The density values for the topography and sea water were 2670 kg.m-3 and 1030 kg.m-3, respectively. A value of 37 km was used for the depth to the root surface at sea level whilst a value of 400 kg.m-3 was used for the density contrast across the root. These values are the same as those used in previous isostatic residual gravity products from Geoscience Australia (Nakamura et al., 2010). The far-field isostatic response was the combined topographic adjustment-isostatic gravity response for a spherical Earth for a distance of 166.7 km from the observation point to 180 degrees as published by Karki et al. (1961). To assist with isolation of the anomalies due to sources in the mid- to upper crust, a strong southwest to northeast gradient was removed by fitting and applying a first order trend correction. More information about the 2019 national gravity grids and the processing steps can be found in Lane et al. (2020a,b). A tilt filter was calculated by applying a fast Fourier transform (FFT) process to the DGIR grid of the 2019 Australian National Gravity Grids A series to produce this grid. This tilt filter was calculated using an algorithm from the INTREPID Geophysics software package. A tilt filter is a ratio of the vertical derivative to the total horizontal derivative and is used for detection of edges of geological units. Details of the specifications of individual surveys held in the Australian National Gravity Database (ANGD) can be found in the Second Edition of the Index of Gravity Surveys (Wynne and Bacchin, 2009).
References:
Airy, G. B., 1855, On the computation of the effect of the attraction of mountain-masses, as disturbing the apparent astronomical latitude of stations in geodetic surveys: Phil. Trans. R. Soc., 145, 101-104, http://doi.org/10.1098/rstl.1855.0003;
Amante, C., and B. W. Eakins, 2009. ETOPO1 1 Arc-Minute Global Relief Model: Procedures, Data Sources and Analysis: NOAA Technical Memorandum NESDIS NGDC-24, National Geophysical Data Center, NOAA, doi:10.7289/V5C8276M;
Heiskanen, W. A., and F. A. Vening Meinesz, 1958, The Earth and its gravity field: McGraw Hill Book Co., Ltd., New York, 470 pp.;
Intrepid Geophysics, http://www.intrepid-geophysics.com;
Karki, P., L. Kivioja, and W. A. Heiskanen, 1961, Topographic-Isostatic reduction maps for the world to the Hayford zones 18-1, Airy-Heiskanen system, T = 30 km: Isostatic Institute of the International Association of Geodesy, 35;
Lane, R. J. L., Wynne, P. E., Poudjom Djomani, Y. H., Stratford, W. R., Barretto, J. A., and Caratori Tontini, F., 2020a, 2019 Australian National Gravity Grids: Geoscience Australia, eCat Reference Number 133023, https://pid.geoscience.gov.au/dataset/ga/133023;
Lane, R. J. L., Wynne, P. E., Poudjom Djomani, Y. H., Stratford, W. R., Barretto, J. A. and Caratori Tontini, F., 2020b, 2019 Australian national gravity grids explanatory notes: Record 2020/22, Geoscience Australia, Canberra, http://dx.doi.org/10.11636/Record.2020.022;
Nakamura, A., Bacchin, M., and Tracey, R., 2010, Isostatic residual gravity anomaly grid of onshore Australia: Extended Abstracts, ASEG 21st Geophysical Conference, 2010, 1-4;
Sandwell, D. T., R. D. Muller, W. H. F. Smith, E. Garcia, and R. Francis, 2014, New global marine gravity model from CryoSat-2 and Jason-1 reveals buried tectonic structure: Science, 346 (6205), 65-67, doi: 10.1126/science.1258213;
Simpson, R. W., R. C. Jachens, and R. J. Blakely, 1983, Airyroot: A Fortran Program for Calculating the Gravitational Attraction of an Airy Isostatic Root Out to 166.7 KM: U.S.G.S. Open-File Report 83-883, 66 p. ;
Simpson, R. W., R. C. Jachens, R. J. Blakely, and R. W. Saltus, 1986, A new isostatic residual gravity map of the conterminous United States with a discussion on the significance of isostatic residual anomalies: J. Geophys. Res., 91(B8), 8348, 8372, doi:10.1029/JB091iB08p08348. ;
Tracey, R., M. Bacchin, and P. Wynne, 2007, AAGD07: A new absolute gravity datum for Australian gravity and new standards for the Australian National Gravity Database: Expanded Abstract, 19th ASEG/PESA International Geophysical Conference & Exhibition, Perth, Western Australia, 1-3, https://www.tandfonline.com/doi/abs/10.1071/ASEG2007ab149;
Whiteway, T., 2009, Australian Bathymetry and Topography Grid, June 2009: Record 2009/021, Geoscience Australia, Canberra, https://pid.geoscience.gov.au/dataset/ga/67703;
Wynne, P. and Bacchin, M., 2009. Index of Gravity Surveys (Second Edition). Geoscience Australia, Record 2009/07.Gravity data measure small changes in gravity due to changes in the density of rocks beneath the Earth's surface. The data collected are processed via standard methods to ensure the response recorded is that due only to the rocks in the ground. The results produce datasets that can be interpreted to reveal the geological structure of the sub-surface. The processed data is checked for quality by GA geophysicists to ensure that the final data released by GA are fit-for-purpose. This National Gravity Compilation 2019 DGIR tilt grid is produced from the 2019 Australian National Gravity Grids A series. These gravity data were acquired under the project No. 202008. The grid has a cell size of 0.00417 degrees (approximately 435m). The data are derived from ground observations stored in the Australian National Gravity Database (ANGD) as at September 2019, supplemented by offshore data sourced from v28.1 of the Global Gravity grid developed using data from the Scripps Institution of Oceanography, the National Oceanic and Atmospheric Administration (NOAA), and National Geospatial-Intelligence Agency (NGA) at Scripps Institution of Oceanography, University of California San Diego. Out of the approximately 1.8 million gravity observations, nearly 1.4 million gravity stations in the ANGD together with marine data were used to generate this grid. The ground gravity data used in the national grid has been acquired by the Commonwealth, State and Territory Governments, the mining and exploration industry, universities and research organisations from the 1940's to the present day. Station spacing for ground observations varies from approximately 11 km down to less than 1 km, with major parts of the continent having station spacing between 2.5 and 7 km. The DGIR was obtained by subtracting 3 quantities (i.e., the near-field isostatic correction, the far-field isostatic correction, and a first order trend correction) from Complete Bouguer Anomaly data (CBA) of the 2019 Australian National Gravity Grids A series. The grid shows a tilt of the de-trended global isostatic residual (DGIR) anomalies (A series) over Australia and its continental margins. A tilt filter was calculated by applying a fast Fourier transform (FFT) process to the DGIR grid of the 2019 Australian National Gravity Grids A series. A tilt filter is a ratio of the vertical derivative to the total horizontal derivative and is used for detection of edges of geological units
National Gravity Compilation 2019 DGIR 0.5VD grid
Maintenance and Update Frequency: notPlannedStatement: This National Gravity Compilation 2019 DGIR 0.5VD grid is produced from the 2019 Australian National Gravity Grids A series. These gravity data were acquired under the project No. 202008. The grid has a cell size of 0.00417 degrees (approximately 435m). The data were derived from ground observations stored in the Australian National Gravity Database (ANGD) as at September 2019, supplemented by offshore data sourced from v28.1 of the Global Gravity grid developed at Scripps Institution of Oceanography, University of California at San Diego using data from the United States SIO, NOAA and NGA (Sandwell et al., 2014). Out of the approximately 1.8 million gravity observations, nearly 1.4 million gravity stations in the ANGD together with marine data were used to generate this grid. The ground gravity data used in this grid have been acquired by the Commonwealth, State and Territory Governments, the mining and exploration industry, universities and research organisations from the 1940's to the present day. Station spacing varies from approximately 11 km down to less than 1 km, with major parts of the continent having station spacing between 2.5 and 7 km. The grid shows a half vertical derivative of the de-trended global isostatic residual anomalies (A series) over Australia and its continental margins. The original DGIR grid was obtained by subtracting 3 quantities (i.e., the near-field isostatic correction, the far-field isostatic correction, and a first order trend correction) from Complete Bouguer Anomaly data (CBA) of the 2019 Australian National Gravity Grids A series. The CBA values were obtained using the methodology given in Hinze et al. (2005). The horizontal and vertical datum was GDA94 (GRS80 ellipsoid) and the gravity datum was AAGD07 (Tracey et al., 2007). The near-field isostatic response is the gravity response of a density contrast across an isostatic root surface for a flat Earth out to a radius of 166.7 km. The isostatic root surface was derived from the topographic and bathymetric dataset compiled by Whiteway (2009), supplemented by ETOPO1 data (Amante and Eakins, 2009). The calculations were performed with software based on the AIRYROOT program (Simpson et al., 1983; Simpson et al., 1986) which uses a one-dimensional Airy-Heiskanen model of isostatic balance (Airy, 1855; Heiskanen and Vening Meinesz, 1958). The density values for the topography and sea water were 2670 kg.m-3 and 1030 kg.m-3, respectively. A value of 37 km was used for the depth to the root surface at sea level whilst a value of 400 kg.m-3 was used for the density contrast across the root. These values are the same as those used in previous isostatic residual gravity products from Geoscience Australia (Nakamura et al., 2010). The far-field isostatic response was the combined topographic adjustment-isostatic gravity response for a spherical Earth for a distance of 166.7 km from the observation point to 180 degrees as published by Karki et al. (1961). To assist with isolation of the anomalies due to sources in the mid- to upper crust, a strong southwest to northeast gradient was removed by fitting and applying a first order trend correction. More information about the 2019 national gravity grids and the processing steps can be found in Lane et al. (2020a,b). Details of the specifications of individual surveys held in the Australian National Gravity Database (ANGD) can be found in the Second Edition of the Index of Gravity Surveys (Wynne and Bacchin, 2009). A half vertical derivative was calculated by applying a fast Fourier transform (FFT) process to the DGIR grid of the 2019 Australian National Gravity Grids to produce this grid. This vertical derivative was calculated using an algorithm from the INTREPID Geophysics software package.
References:
Airy, G. B., 1855, On the computation of the effect of the attraction of mountain-masses, as disturbing the apparent astronomical latitude of stations in geodetic surveys: Phil. Trans. R. Soc., 145, 101-104, http://doi.org/10.1098/rstl.1855.0003;
Amante, C., and B. W. Eakins, 2009. ETOPO1 1 Arc-Minute Global Relief Model: Procedures, Data Sources and Analysis: NOAA Technical Memorandum NESDIS NGDC-24, National Geophysical Data Center, NOAA, doi:10.7289/V5C8276M;
Heiskanen, W. A., and F. A. Vening Meinesz, 1958, The Earth and its gravity field: McGraw Hill Book Co., Ltd., New York, 470 pp.;
Intrepid Geophysics, http://www.intrepid-geophysics.com;
Karki, P., L. Kivioja, and W. A. Heiskanen, 1961, Topographic-Isostatic reduction maps for the world to the Hayford zones 18-1, Airy-Heiskanen system, T = 30 km: Isostatic Institute of the International Association of Geodesy, 35;
Lane, R. J. L., Wynne, P. E., Poudjom Djomani, Y. H., Stratford, W. R., Barretto, J. A., and Caratori Tontini, F., 2020a, 2019 Australian National Gravity Grids: Geoscience Australia, eCat Reference Number 133023, https://pid.geoscience.gov.au/dataset/ga/133023;
Lane, R. J. L., Wynne, P. E., Poudjom Djomani, Y. H., Stratford, W. R., Barretto, J. A. and Caratori Tontini, F., 2020b, 2019 Australian national gravity grids explanatory notes: Record 2020/22, Geoscience Australia, Canberra, http://dx.doi.org/10.11636/Record.2020.022;
Nakamura, A., Bacchin, M., and Tracey, R., 2010, Isostatic residual gravity anomaly grid of onshore Australia: Extended Abstracts, ASEG 21st Geophysical Conference, 2010, 1-4;
Sandwell, D. T., R. D. Muller, W. H. F. Smith, E. Garcia, and R. Francis, 2014, New global marine gravity model from CryoSat-2 and Jason-1 reveals buried tectonic structure: Science, 346 (6205), 65-67, doi: 10.1126/science.1258213;
Simpson, R. W., R. C. Jachens, and R. J. Blakely, 1983, Airyroot: A Fortran Program for Calculating the Gravitational Attraction of an Airy Isostatic Root Out to 166.7 KM: U.S.G.S. Open-File Report 83-883, 66 p. ;
Simpson, R. W., R. C. Jachens, R. J. Blakely, and R. W. Saltus, 1986, A new isostatic residual gravity map of the conterminous United States with a discussion on the significance of isostatic residual anomalies: J. Geophys. Res., 91(B8), 8348, 8372, doi:10.1029/JB091iB08p08348. ;
Tracey, R., M. Bacchin, and P. Wynne, 2007, AAGD07: A new absolute gravity datum for Australian gravity and new standards for the Australian National Gravity Database: Expanded Abstract, 19th ASEG/PESA International Geophysical Conference & Exhibition, Perth, Western Australia, 1-3, https://www.tandfonline.com/doi/abs/10.1071/ASEG2007ab149;
Whiteway, T., 2009, Australian Bathymetry and Topography Grid, June 2009: Record 2009/021, Geoscience Australia, Canberra, https://pid.geoscience.gov.au/dataset/ga/67703;
Wynne, P. and Bacchin, M., 2009. Index of Gravity Surveys (Second Edition). Geoscience Australia, Record 2009/07.Gravity data measure small changes in gravity due to changes in the density of rocks beneath the Earth's surface. The data collected are processed via standard methods to ensure the response recorded is that due only to the rocks in the ground. The results produce datasets that can be interpreted to reveal the geological structure of the sub-surface. The processed data is checked for quality by GA geophysicists to ensure that the final data released by GA are fit-for-purpose. This National Gravity Compilation 2019 DGIR 0.5VD grid is produced from the 2019 Australian National Gravity Grids A series. These gravity data were acquired under the project No. 202008. The grid has a cell size of 0.00417 degrees (approximately 435m). The data are derived from ground observations stored in the Australian National Gravity Database (ANGD) as at September 2019, supplemented by offshore data sourced from v28.1 of the Global Gravity grid developed using data from the Scripps Institution of Oceanography, the National Oceanic and Atmospheric Administration (NOAA), and National Geospatial-Intelligence Agency (NGA) at Scripps Institution of Oceanography, University of California San Diego. Out of the approximately 1.8 million gravity observations, nearly 1.4 million gravity stations in the ANGD together with marine data were used to generate this grid. The ground gravity data used in this grid has been acquired by the Commonwealth, State and Territory Governments, the mining and exploration industry, universities and research organisations from the 1940's to the present day. Station spacing for ground observations varies from approximately 11 km down to less than 1 km, with major parts of the continent having station spacing between 2.5 and 7 km. The grid shows the half vertical derivative of the de-trended global isostatic residual anomalies (A series) over Australia and its continental margins. The original DGIR was obtained by subtracting 3 quantities (i.e., the near-field isostatic correction, the far-field isostatic correction, and a first order trend correction) from Complete Bouguer Anomaly data (CBA) of the 2019 Australian National Gravity Grids A series. A half vertical derivative was calculated by applying a fast Fourier transform (FFT) process to the DGIR grid of the 2019 Australian National Gravity Grids to produce this grid
The new theory of the gravimetric geodesy (II)
Prepared for Air Force Cambridge Research Center, U.S. Air Research and Development Command, Laurence G. Hanscom Field, Bedford, Massachusetts: Contract No. AF 19(604)-1963 (OSURF Project 716)According to Helmert, the function of geodesy is to measure and represent the physical surface of the earth, "Ausmessung und Abbildung der Erdoberfläche." This problem is practically solved in three steps. 1. Establishment of a reference surface which must be as regular as possible, but at the same time, sufficiently close to the actual surface, 2. Establishment of an intermediate surface and determination of the deviations of the latter from the reference surface, 3. Determination of the deviations of the actual surface from the intermediate surface. For the purposes of pure geodesy, the first step is definitely completed by the international ellipsoid. There is no need to replace the constants given on pp. 18-26, Part I, by values which would represent the actual earth more closely. As for step 2, the classical theory introduced the geoid as the intermediate surface. This is a smoothly undulating surface which runs close to the ellipsoid; the deviations, which are of order of 50 meters, can be determined with the aid of the famous formulas of Stokes. The distances involved in step 3 are long, often several kilometers. They are called orthometric heights. The increasing accuracy of the practical measurements has shown that the classical theory fails to satisfy the modern requirements of the precision. According to the old theory, the following reductions should be applied to the measurements: a. The results of spirit levellings should be converted to orthometric heights, b. The direction of the actual gravity as obtained with the aid of the astronomical fixations at the physical surface of the earth should be reduced to the geoid, c. Similarly, the values of gravity observed at the earth's surface should be reduced to the geoid. These reductions require such information about the circumstances within the earth's crust--as the gravity or the density of the matter-- which practically never can be obtained. Very good approximations can be computed with the aid of plausible hypotheses but, anyway, the computations often are very cumbersome. On the other hand, many investigators have shown that these hypotheses are quite unnecessary. No one, however, has clearly pointed out that the new methods of reduction signify the abandonment of the geoid as the intermediate surface, nor has anyone exactly defined the new intermediate surface. In this paper a comprehensive new theory will be developed on the basis of the ideas that have been presented by Stokes, Pizzetti, Somigliana, Vening Meinesz, Jeffreys, Molodensky, de Graff Hunter and many others. There will be only a few references in the text because the ideas mostly are generally known; the omission of the bibliographical sources, in most cases, is due to the fact that the author has not been sure of the origin of each idea. [Full text of abstract available in document.
Better stoma care using the Stoma App:does it help? A first randomized double-blind clinical trial on the effect of mobile healthcare on quality of life in stoma patients
Background: Receiving a stoma significantly impacts patients’ quality of life. Coping with this new situation can be difficult, which may result in a variety of physical and psychosocial problems. It is essential to provide adequate guidance to help patients cope with their stoma, as this positively influences self-efficacy in return. Higher self-efficacy reduces psychosocial problems increasing patient’s quality of life. This study investigates whether a new mobile application, the Stoma App, improves quality of life. And if personalized guidance, timed support, and peer contact offered as an in-app surplus makes a difference. Methods: A double-blind, randomized controlled trial was conducted between March 2021 and April 2023. Patients aged > 18 years undergoing ileostomy or colostomy surgery, in possession of a compatible smartphone were included. The intervention group received the full version of the app containing personalized and time guidance, peer support, and generic (non-personalized) stoma-related information. The control group received a restricted version with only generic information. Primary outcome was stoma quality of life. Secondary outcomes included psychological adaption, complications, re-admittance, reoperations, and length of hospital stay. Results: The intervention version of the app was used by 96 patients and the control version by 112 patients. After correction for confounding, the intervention group reported a significant 3.1-point improvement in stoma-related quality of life one month postoperatively (p = 0.038). On secondary outcomes, no significant improvements could be retrieved of the intervention group. Conclusion: The Stoma App improves the quality of life of stoma patients. Peer support and personalized guidance are of significant importance in building self-efficacy. It is to be recommended to implement Stoma app—freely available software qualifying as a medical device—in standard stoma care pathways for the benefits of both patients and healthcare providers.</p
Impact of White Adipose Tissue on Brain Structure, Perfusion, and Cognitive Function in Patients With Severe Obesity: The BARICO Study
Background and Objective While underlying pathophysiology linking obesity to brain health is not completely understood, white adipose tissue (WAT) is considered a key player. In obesity, WAT becomes dysregulated, showing hyperplasia, hypertrophy, and eventually inflammation. This disbalance leads to dysregulated secretion of adipokines influencing both (cardio)vascular and brain health. Within this study, we investigated the association between omental WAT (oWAT) and subcutaneous WAT (scWAT) with brain structure and perfusion and cognition in adults with severe obesity. Methods Within the cross-sectional BARICO study, brain structure and perfusion and cognitive function were measured before bariatric surgery (BS) using MRI and cognitive assessments. During BS, oWAT and scWAT depots were collected and analyzed by histopathology. The number and diameter of adipocytes were quantified together with the amount of crown-like structures (CLS) as an indication of inflammation. Blood samples were collected to analyze adipokines and inflammatory markers. Neuroimaging outcomes included brain volumes, cortical thickness, white matter (WM) integrity, WM hyperintensities, cerebral blood flow using arterial spin labeling (ASL), and the ASL spatial coefficient of variation (sCoV), reflecting cerebrovascular health. Results Seventy-one patients were included (mean age 45.1 ± 5.8 years; 83.1% women; mean body mass index 40.8 ± 3.8 kg/m 2). scWAT showed more CLS (z = −2.72, p < 0.01, r = −0.24) and hypertrophy compared with oWAT (F(1,64) = 3.99, p < 0.05, η 2 = 0.06). Adiponectin levels were inversely associated with the average diameter of scWAT (β = −0.31, 95% CI −0.54 to −0.08) and oWAT (β = −0.33, 95% CI −0.55 to −0.09). Furthermore, the adipocyte diameter in oWAT was positively associated with the sCoV in the parietal cortex (β = 0.33, 95% CI 0.10–0.60), and the number of adipocytes (per mm 2) was positively associated with sCoV in the nucleus accumbens (NAcc) (β = 0.34, 95% CI 0.09–0.61). Cognitive function did not correlate with any WAT parameter or plasma marker. These associations were highly influenced by age and sex. sCoV in the NAcc was positively associated with fasting plasma glucose (β = 0.35, 95% CI 0.10–0.56)
0004
THE DAILY PALO ALTO TIMES
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M ♦ •♦♦♦4>4»s»-.>-4>.».s>-.
HOT ICE CREAM SODAS
are not the Kind yon get at oar
fountain. All drinks served ore
Ice Cold and Propertr Mixed. Try
a rich egg drinK or a delicious banana Cream Sundae.
MELLOR'S
Fraternity Hall Building.
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MAIL SCI! RBI'I.E.
An*1»al snd departure of malls at
th* postomce at Palo Alto, Cal,—In
affect July I, 1907:
Dispatch aorth — V:ll, 1:81.
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LOCAL
***** ********
Whose your grocer? Compton.
It-tf.
Islston creamery butter at Comp-
rms. ll-tf
Dr. Kirk spent the week end In
Ban Pranctsco.
St. Helena Sanitarium Health
Poods st Compton's. 18-tf
Mark Mount has purchased a
ranch nesr Turlock.
Coffee that pleasss—Dsl Monte
Btsel Cut Compton's. 18-tf
Professor C. B. Wing spent a part
of last week In Baa Joss.
Fresh, shelled Spanish peanut*;
fine for candy. Comptons. 18-tf
Miss Lucretls Young bss gone to
Los Aagsles to spend the winter.
Miss Christine Rose. Stanford '01,
ta studying piano forts In Psrts.
A daugbtsr wss born yesterdsy to
Mr. and Mrs. Oeorge R. Bramhsll.
Mr. aad Mra. A. Jensen spent San-
day TUItlag relstlvs* In Ssn Francisco
Misses Angellne snd Julia Board-
msn bsve issued Invitations for s
Halloween psrty.
Guy lieeney. of San Francisco.
wss ths week-end guest of W. C.
Horn snd family.
Joha Pryor spent a part of last
wsek with hu parents. Mr. snd Mrs.
J. T. Pryor of HollUter
The Junior snd senior clssses of
Caalilleja school wlll entertain st s
dsnce on Friday avenlng.
All kinds of sowing machines
packed and crated for shipment at
108 Circle. Pbone Msin 22».
Miss Ilerths Martin, of San Mateo", waa the week-end guest of
Misses Marie aad Carrie Jensen.
Mr, aad Mra. H. A. Hicks bare returned to Ssn Frsoclsco, after a
six-months' residence In Palo Alto.
Fred Nelson doss all kinds of
sroodwork sad furnlturs repairing st
Palo Alto Cabinet Worts. Slf High.
The studentbody ot the high
school will give s dsnce in the Playhouse on Frtdsy svenlng. November
1st.
Miss Edna Logan has returned to
her home In Sent** Clara, after a
visit st ths borne of her sister. Mrs.
A. at Mills.
Misses Helen aad Carrie Lewis
were losers in tbe recent Sr* st
Sunnyvale, their business building
being destroyed.
Miss Hsrtter bas issued Invitations
to sa "st home" to be given at her
handsome new achool building on
Friday *vening. October 15th.
Ray Uenn has corns from Colfax.
Wash., to Palo Alto to spend the
winter. Mr. Benn has aooepted s
position with Robert Compton.
O. H. MscMeekln. th* Pslo Alto
tuner, with Kotier A Chas*. expert
plsno luring snd repairing. All
work guaranteed. 6«« Hawthorne
avenue. Phone Jamas 40T.
Arnold J. Mount, of Oakland, i
in town yesterdsy.
P. W. Fox snd fsmily bsvs re-
tu.rn.--d from s rlalt to Council Bluffs.
Omahs snd other eastern points.
Speclsl todsy: Hot chicken ta-
males, 10c sptecs. Stanford Dsllca-
teasen A Catering Co. (With Palo
Alto Tea Co.)
Mrs. A. Lr.' Munger was a passenger oo tbs San Frsnclsco atreet car
Ssturdsy when the fatal shooting
affray occurred and barely eecaped
being hit by s bullet.
S. A. Velno waa brought home
yesterday from a hospital in Salinas
where be has beea since hts unfortunate scddent. Mr. Vetno's condition is very much Improved.
Mr. and Mrs. A. Jensen entertained very delightfully Friday evening at their home on Homer avenue.
the occasion being tbe birthday anniversary of tbelr daughter Marie.
Mr. and Mrs, Homer T. Blckel, of
Ssn Frsnclsco, came dowa In tbelr
machine yesterdsy from tbelr country home st Pair Oaks for a short
visit st ths bom* of Mrs. Elda Cut-
Isr.
H. O. Hathaway and family *•"
speed the winter In Southern California. Mr. Hathaway has ranted
his house to the Ellis fsmily, who
recently came to Pslo Alto from
Helena. Moot.
The Alpine Wood Compaay. corner Forest snd Alms streets, will
sell for esih for l limited time only,
live osk stove wood. 11 per cord.
Phone Msin aoa.
Dr. R. H. Donsldson snd Mra.
Donaldson wlll leave sbout tb* flrst
of tbe montb for Lskeport. Dr. Donsldson will be absent for two or
three weeks, bnt hla wife will remain there for aome time.
Tfae Girls' Glee Club of the high
achool recently elected the following new members: First soprano*,
j Mlsa Minnie Nellsen. Mis* Louise
Bille; second soprano, Miss Mlnnls
Wlmurs; alto, Miss B. Deal.
W. H. Adams, box 00, Redwood
City, CaL, lsnd agent snd real sstats
broker. Commissions eiecuted In
sll parts of the stste. Rsnch lands
bought sad sold. If you wsat to
buy or sail, address aa above.
Stop at Slade's
i
for "la Ounlts." None but ths
choicest of Havana tobsoeo onters
Into ths composition of this mlld-
amoklng clgsr.
3. A Lakln Is seriously 111 with
I congestion of ths blood vesssls
around ths brain
William wim,,-. of Alameds, sod
Mlas Theresa Commerford. of Ssn
Fraaelsco, war* guests of F. J. Com-
merford over Sundsy.
John Darling Is convalescing sftsr
s serious Illness of several weeks'
duration, due to an abacess undsr
ons of the bones of the face.
John Rose, of Pslo Atto. wbo wsa
committed to Stockton asylum lsst
September, escaped s few days ago
and local police offlcers havs been
notified to keep s watch for htm
8. SV. Lockwood is at home for a
tew days. A M. Thomson remained
lr. Fresno, where the Co-operative
Land * Trust Compsny sre exploiting their Palo Alto and Suanyslde
property. Incidentally the Co-operative is doing s service tn the way
ol promoting Palo Alto and the
peninsula tbat Is attracting much
favorable notice among (be leading
cltisens of Freano. Direct missionary work of this kind u beosflclal
to Pslo Alto In genersl, besides selling Sunnyslde and Alba Park tots.
Mrs. A. M. Thomson snd ths babies
will Join Mr. Thomson st Fresno ths
lsst of this week.
President J. E. Stubos. of the
University of Nevsda. snd Mrs. J
Stubos will be the guests of Dr. and |
Mra. David Starr Jordsn this week,
having com* down from Nevada Frt-
day to see Ihe N**eds-CslIfornia i
snd Nevada-Stanford gsmes.
Mr. and Mrs. Msnchester, parents!
of Professor P. A. Msnchester. of
the Stanford English depsrtmenV j
hsve recently arrived ln Palo Atto,
from tbelr home In Wisconsin snd [
bsvs taken the Gregg bouse on
Florence street until Christmas.
Mrs. n. S. Stanton, of 11J Everett
svenue, underwent s serious operation at Dr. Mover's ssnltorium Saturday evening. Mrs. Stanton's con-
't it Ion Is most eneoursglag- Dr.
Morton, of Ssn Frsnclsco. and Dr.
Moyer performed the operation.
George Parker snd sister, Mlas
Llnna aPrker, of Santa Cm*. Miss
Height of Ssn Prsnclsro and Miss
Reveal1 of Berkeley were tbe guosu
of Miss Lyds Oosaett yeaterdsy, The
party left In tbe Parker touring car
laat -»vening for Sao Jose on their
way to Saota Crus.
Rev. Leon L. l^oofbourow, formerly of tbla city, but at present pss-;
tor of the Eighth svenue Methodist
rbur-h of Oakland, has sehleved
considerable prominence fay denouncing the snnusl derby dsy a* the
Emeryville rate trsck fj* the bene-
fit of Fsblols hospital.
Eager For Mew Pirtioa.
Amsricsn book publisher! sad ths
wbolssals dealers in lletlon betveen
rovers unite In declsrlng thst-the demand for new Dorels ts strong. People wbo tske s somewhat supertk-tal
view of this rtu.iji-i-t are often moved
to wonder ss to wbo buys and reads
tbs mass of new bcoks turned out
•very month. Llbrsrlsna report thst
the demand over their counters Is
brrtsk tor wbst they are pbesed, to call
************ or trashy stories, while tbe
patro— of libraries are alow to sppre-
clsts really good literature. Wltb so
msny stsndsrds In taste It Is really
dlxhcult to decide what maimer ot
book deserves to be rstsd ss "good,"
■"■t**-d Iff area*,'' "commonplace" snd the
Ilka. On* standard assy safely bs ap-
pUed to ail novels wblcb to sny extant command the price of i.&o they
must bs rasdsbls. As things at* now
man? people srs ssUsfled to look for
oo value beyond tbat. Tbe hope of being ratertstned is siifflclent to opon
tbe p(*ckstbook.
It may bs thst ths desire for entertainment and faith ta the story teller's
art hss really mors to do with th*
eagerness for fletloa thsn merit wblch
is foand ln any particular clsss of
books or tbe work of sny particular
aothot*--* Ow frequently bears of read-
en wbo go te tbe same source the second time for s treat snd turn swsy
dlssppulnted. But disspimlntmeiit does
not dull the ctrursge. A new author
is called upon to feed tbe appetite
which the flrst crested only to leers tt
buagry tn the end. It would be a
pleasure to be able to atate that Just
the books whlcb ths reading public Is
tpoklng for are created and tbat author, put.