2013/08/06

8112.- Matias Freio... un amigo de esta casa...



No hay que ser agricultor para saber que una buena cosecha requiere de buena semilla, buen abono y riego.
También es obvio que quien cultiva la tierra no se detiene impaciente frente a la semilla sembrada, y grita con todas sus fuerzas: ¡Crece, maldita seas!
Hay algo muy curioso que sucede con el bambú y que lo transforma en no apto para impacientes:
Siembras la semilla, la abonas, y te ocupas de regarla constantemente.
Durante los primeros meses no sucede nada apreciable. En realidad no pasa nada con la semilla durante los primeros siete años, a tal punto que un cultivador inexperto estaría convencido de haber comprado semillas infértiles.
Sin embargo, durante el séptimo año, en un período de sólo seis semanas la planta de bambú crece ¡más de 30 metros!

 

¿Tardó sólo seis semanas crecer?
No, la verdad es que se tomó siete años y seis semanas en desarrollarse.
Durante los primeros siete años de aparente inactividad, este bambú estaba generando un complejo sistema de raíces que le permitirían sostener el crecimiento que iba a tener después de siete años.
Sin embargo, en la vida cotidiana, muchas personas tratan de encontrar soluciones rápidas, triunfos apresurados, sin entender que el éxito es simplemente resultado del crecimiento interno y que éste requiere tiempo.
Quizás por la misma impaciencia, muchos de aquellos que aspiran a resultados en corto plazo, abandonan súbitamente justo cuando ya estaban a punto de conquistar la meta.
Es tarea difícil convencer al impaciente que sólo llegan al éxito aquellos que luchan en forma perseverante y saben esperar el momento adecuado.
De igual manera es necesario entender que en muchas ocasiones estaremos frente a situaciones en las que creemos que nada está sucediendo. Y esto puede ser extremadamente frustrante.
En esos momentos (que todos tenemos), recordar el ciclo de maduración del bambú japonés, y aceptar que en tanto no bajemos los brazos -, ni abandonemos por no "ver" el resultado que esperamos-, si está sucediendo algo dentro nuestro: estamos creciendo, madurando.
Quienes no se dan por vencidos, van gradual e imperceptiblemente creando los hábitos y el temple que les permitirá sostener el éxito cuando éste al fin se materialice.
El triunfo no es más que un proceso que lleva tiempo y dedicación.
Un proceso que exige aprender nuevos hábitos y nos obliga a descartar otros.
Un proceso que exige cambios, acción y formidables dotes de paciencia.
Tiempo... Cómo nos cuestan las esperas, qué poco ejercitamos la paciencia en este mundo agitado en el que vivimos...
Apuramos a nuestros hijos en su crecimiento, apuramos al chofer del taxi... nosotros mismos hacemos las cosas apurados, no se sabe bien por qué...
Perdemos la fe cuando los resultados no se dan en el plazo que esperábamos, abandonamos nuestros sueños, nos generamos patologías que provienen de la ansiedad, del estrés...
¿Para qué?
Te propongo tratar de recuperar la perseverancia, la espera, la aceptación.
Si no consigues lo que anhelas, no desesperes...
quizá solo estés echando raíces....


Matias estuvo en nuestra casa en tiempo no muy lejano, la Veru lo trajo de la mano y nos regalo una excelente conferencia... lo leemos en cuanto notamos su presencia, es de los buenos amigos que están siempre presentes, no importa la ausencia...
Gracias por el Bambú...

8111.- Marte, ese viejo desconocido...

MAVEN: Mars Atmosphere and Volatile EvolutioN

Answers About Mars Climate History

The Mars Atmosphere and Volatile EvolutioN (MAVEN) mission, scheduled for launch in late 2013, will be the first mission devoted to understanding the Martian upper atmosphere.

The goal of MAVEN is to determine the role that loss of atmospheric gas to space played in changing the Martian climate through time. Where did the atmosphere – and the water – go?

MAVEN will determine how much of the Martian atmosphere has been lost over time by measuring the current rate of escape to space and gathering enough information about the relevant processes to allow extrapolation backward in time.

MAVEN is the first Mars mission managed by the Goddard Space Flight Center.

Download the MAVEN Mission Fact Sheet (pdf).

Partners:
The University of Colorado will coordinate the science team and science operations and lead the education and public outreach activities.

NASA Goddard will also provide mission systems engineering, mission design, and safety and mission assurance.

Instruments on the spacecraft will be provided by the University of California, Berkeley, the University of Colorado, Boulder, and NASA Goddard, with the Centre d’Etude Spatiale des Rayonnements, Toulouse, France, providing the sensor for one instrument.

Lockheed Martin Corp., based in Bethesda, Md., will develop the spacecraft, conduct assembly, test and launch operations, and provide mission operations at their Littleton, Colorado facility.

NASA's Jet Propulsion Laboratory, Pasadena, Calif., will provide navigation support, the Deep Space Network, and Electra telecommunications relay package.

The Mars Atmosphere and Volatile Evolution, or MAVEN, mission will orbit Mars to explore how the sun may have stripped Mars of most of its atmosphere, turning a planet once possibly habitable to microbial life into a cold and barren desert world. MAVEN will be the first spacecraft mission dedicated to exploring the upper atmosphere of Mars.

Previous missions to Mars have shown us that the atmosphere and climate have changed over time and found evidence of abundant liquid water on the surface in ancient times, though not today. Scientists want to know what happened to the water and where the planet’s thick atmosphere went. The MAVEN mission will study the nature of the red planet’s upper atmosphere, how solar activity contributes to atmospheric loss, and the role that escape of gas from the atmosphere to space has played through time.

MISSION OVERVIEW

MAVEN will launch from Cape Canaveral,Fla., during a 20-day period that begins on November 18, 2013. The trip to Mars takes 10 months, and MAVEN will go into orbit around Mars in September 2014. It will take 5 weeks for the spacecraft to get into its final science-mapping orbit, test the instruments, and test science mapping sequences. After this commissioning phase, MAVEN has a 1-Earth-year primary mission during which it will make its key measurements.

The MAVEN orbit will be elliptical. At its closest point to the planet, it will be 93 miles (150 kilometers) above the surface. At this altitude, the spacecraft will pass through the upper atmosphere on each orbit and can sample the gas and ion composition directly. At its highest point, it will be more than 3728 miles (6000 km) above the surface and can carry out ultraviolet imaging of the entire planet. This combination of detailed point measurements and global imaging is a powerful way to understand the properties of the upper atmosphere. The altitude in the MAVEN orbit will be lowered for five “deep-dip” campaigns during the mission. In each deep dip, the spacecraft will take measurements down to an altitude of about 77 miles (125 kilometers). These measurements will provide information down to the top of the well-mixed lower
atmosphere, giving scientists a full profile of the top of the atmosphere.

The MAVEN spacecraft will make measurements in all regions of “near-Mars” space. These measurements will allow scientists to characterize the current state of the upper atmosphere and ionosphere, determine the rates of loss of gas to space today, and extrapolate backward in time in order to determine the total loss to space through time.

SCIENCE PAYLOAD

MAVEN will carry three instrument suites. The Particles and Fields Package (PFP), provided by the University of California at Berkeley Space Sciences Laboratory, contains six instruments that characterize the solar wind and the ionosphere of the planet. Four of the instruments were built by the Space Sciences Laboratory, one was built jointly with the University of Colorado at Boulder Laboratory for Atmospheric and Space Physics, and one was built by NASA’s Goddard Space Flight Center in Greenbelt, Md.
The PFP includes:
• Solar Energetic Particle (SEP)
• Solar Wind Ion Analyzer (SWIA)
• Solar Wind Electron Analyzer (SWEA)
• SupraThermal and Thermal Ion Composition (STATIC)
• Langmuir Probe and Waves (LPW)
• Magnetometer (MAG)


The Remote Sensing Package, built by the University of Colorado at Boulder Laboratory for Atmospheric and Space Physics, will determine global characteristics of the upper atmosphere and ionosphere. The Neutral Gas and Ion Mass Spectrometer (NGIMS), built by NASA Goddard, will measure the composition and isotopes of neutrals and ions.

SPACECRAFT

The MAVEN spacecraft was built by Lockheed Martin in Littleton, Colo., and builds on heritage from
previous Mars orbiters. It is solar-powered, with a high-gain antenna that can be pointed to Earth for
twice-weekly communications sessions.

Spacecraft specifications:

• Length: 37.5 feet (11.4 meters)
• Spacecraft Dry Mass: 1991 pounds max (903 kilograms)
• Wet (Fueled) Mass at Launch: 5622 pounds max (2550 kilograms)
• Power: 1135 watts (when Mars is furthest from the Sun)

MAVEN PARTNERS
MAVEN is led by its Principal Investigator, Dr. Bruce Jakosky, from the University of Colorado. The 
university is building two science instruments, will conduct science operations, and leads education/
public outreach. 
NASA’s Goddard Space Flight Center in Greenbelt, Md., manages the project and is building two of the science instruments. 
The University of California at Berkeley Space Sciences Laboratory is building four science instruments for the mission. 
Lockheed Martin of Littleton, Colo., is building the spacecraft and will perform mission operations. 
NASA’s Jet Propulsion Laboratory, Pasadena, Calif., provides program management via the Mars Program Office, as well as data-relay telecommunications hardware and operations, navigation support, and Deep Space Network operations.

For more information, please visit web sites:
http://www.nasa.gov/MAVEN and http://lasp.colorado.edu/MAVEN or follow them on Facebook and Twitter at MAVEN2Mars