Subj : Using Hubble, researchers measure the mass of a single white dwarf for
To   : All
From : NasaSpaceFlight
Date : Mon Feb 06 2023 17:15:03

Using Hubble, researchers measure the mass of a single white dwarf for the 
first time

Date:
Mon, 06 Feb 2023 17:09:44 +0000

Description:
Of the trillions of stars scattered throughout the universe, one of the most 
common are The post Using Hubble, researchers measure the mass of a single 
white dwarf for the first time appeared first on NASASpaceFlight.com .

FULL STORY
======================================================================

Of the trillions of stars scattered throughout the universe, one of the most 
common are the white dwarfs, which are the dormant, burned out, and leftover 
cores of low/medium mass stars. For decades, scientists have only measured 
the masses of white dwarfs within binary star systems. While these 
measurements provide insight into the true masses of white dwarfs, the 
measurements typically feature high amounts of uncertainty. 

With help from the joint NASA/European Space Agency (ESA) Hubble Space 
Telescope, a team of researchers directly measured the mass of an isolated 
white dwarf outside of a binary star system. Found to be approximately 56% of 
the Suns mass, the teams results agree with previous white dwarf mass 
predictions and provide insight into the evolutionary processes of dead 
stars. 

 

To measure the mass of the white dwarf, named LAWD 37, the team utilized 
gravitational microlensing  a natural phenomenon in which the gravity from a 
cosmic object in front of another warps the light from the background object. 
In the case of LAWD 37s observations, light from a star behind the white 
dwarf was slightly warped as the white dwarf passed in front of the star, 
seemingly moving the background star to a different location in the sky. 

Precisely measuring the amount of light deflected by LAWD 37s gravity allowed 
the team to determine the mass of the white dwarf. Interestingly, using 
gravitational microlensing to measure the mass of a white dwarf is not new, 
and was first used in 2017 by Kailash Sahu of the Space Telescope Science 
Institute in Maryland to measure the mass of Stein 2051 b. However, much like 
the observations before Sahus, the white dwarf was a member of a binary star 
system. Artists illustration showing how the gravity of a white dwarf can 
warp the light of a star behind it. (Credit: NASA, ESA, Ann Feild (STScI)) 

Our latest observation provides a new benchmark because LAWD 37 is all by 
itself, said Sahu, who served as the principal Hubble investigator during the 
LAWD 37 observations. 

But what about LAWD 37 made it the perfect candidate for the team to study? 

First, LAWD 37 is a single, isolated white dwarf that is not part of a binary 
star system. This means that the gravity measurements the team collected 
would not be warped by the gravity of a second star within a binary, giving 
them clear and precise measurements for LAWD 37s mass. 

 See Also Hubble Updates Space Science Section NSF Store Click here to Join 
L2 

Second, LAWD 37 is very close to Earth  only 15 light-years away from our 
solar system in the constellation Musca. Using multiple observations from 
ESAs Gaia space observatory, the team was able to predict when LAWD 37 would 
pass in front of a background star. Gaia takes extraordinarily precise 
measurements of the positions of nearly two billion stars in the universe, 
and the motion of a specific star can be determined over multiple 
observations by Gaia. 

Because this white dwarf is relatively close to us, weve got lots of data on 
it  weve got information about its spectrum of light, but the missing piece 
of the puzzle has been a measurement of its mass, said lead author Peter 
McGill of the University of California, Santa Cruz. 

The Gaia data showed McGill et al. that LAWD 37 would pass in front of the 
background star in November 2019. With this information, the team then 
enlisted the help of Hubble, which was used to precisely measure the 
(apparent) positional change of the background star over several years. 

These events are rare, and the effects are tiny. For instance, the size of 
our measured offset is like measuring the length of a car on the Moon as seen 
from Earth, McGill said. 

Whats more, extracting the light from the faint background star proved 
challenging for the team, as the glare from LAWD 37 is approximately 400 
times brighter than the observed light of the background star. Hubble is the 
only space telescope that can perform high-contrast observations in visible 
light, making it the perfect tool for the team. Graphic showing Hubbles 
observations of the movement of LAWD 37. (Credit: NASA/ESA/Peter McGill (UC 
Santa Cruz, IoA)/Kailash Sahu (STScI)/Joseph DePasquale (STScI)) 

After Hubble had collected all the needed data, McGill et al. were able to 
precisely calculate the mass of LAWD 37, which came to be around 56% of the 
mass of our Sun. The mass measurements will allow the team to test the 
mass-radius relationship for white dwarfs, which will then allow them to test 
the theory of degenerate matter  which states that within stars and other 
extreme cosmic objects, gas is so compressed under the objects gravity that 
it begins to behave like solid matter. 

The precision of LAWD 37s mass measurement allows us to test the mass-radius 
relationship for white dwarfs. This means testing the theory of degenerate 
matter under the extreme conditions inside this dead star, said McGill. 

McGill et al.s mass calculation method is expected to open the door for 
predicting future white dwarf occultation events using Gaia. Furthermore, 
NASAs James Webb Space Telescope is capable of observing these occultation 
events like Hubble. With Webbs extreme sensitivity to infrared light, the 
white dwarf in Webbs observations will appear dimmer than the background star 
 perfect for measuring the change in the apparent position of the background 
star. With Hubble, astronomers measured the mass of a single, isolated white 
dwarf  which is the surviving core of a burned-out star. 

The white dwarf, called LAWD 37, is 56% the mass of our Sun: 
https://t.co/wIg48n2jPY 

More pic.twitter.com/Y3roR5csiv 

 Hubble (@NASAHubble) February 2, 2023 

 

Gaia has really changed the game  its exciting to be able to use Gaia data to 
predict when events will happen, and then observe them happening. We want to 
continue measuring the gravitational microlensing effect and obtain mass 
measurements for many more types of stars, McGill said. 

Webb is already being used to observe a white dwarf occultation event. With 
help from Gaia, Kailash Sahu is currently using Webb to observe LAWD 66, 
which is currently in the process of occulting the background star Sahu will 
use to measure the white dwarfs mass. The first observation of LAWD 66 was 
performed in 2022, and Webb is expected to continue observing the white dwarf 
through 2024. 

 (Lead image: White dwarf LAWD 37, as imaged by Hubble. Credit: 
NASA/ESA/Peter McGill (UC Santa Cruz, IoA)/Kailash Sahu (STScI)/Joseph 
DePasquale (STScI)) 

The post Using Hubble, researchers measure the mass of a single white dwarf 
for the first time appeared first on NASASpaceFlight.com .



======================================================================
Link to news story:
https://www.nasaspaceflight.com/2023/02/white-dwarf-mass-measurement/


--- Mystic BBS v1.12 A47 (Linux/64)
 * Origin: tqwNet Science News (1337:1/100)

.